Claims
- 1. A green ceramic oxide pre-form comprising green ceramic oxide material and substantially continuous alpha alumina fibers having lengths of at least 5 cm, the green ceramic oxide material securing the substantially continuous alpha alumina fibers in place, wherein the green ceramic oxide material extends along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 2. The green ceramic oxide pre-form according to claim 1 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 3. The green ceramic oxide pre-form according to claim 1 further comprising discontinuous fibers, wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 4. The green ceramic oxide pre-form according to claim 1 wherein said green ceramic oxide material, when sufficiently heated, provides porous, alpha alumina.
- 5. The green ceramic oxide pre-form according to claim 1 wherein the substantially continuous alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 6. The green ceramic oxide pre-form according to claim 1 further comprising fugitive binder material bonding at least a portion of the substantially continuous alpha alumina fibers together.
- 7. The green ceramic oxide pre-form according to claim 6 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 8. The green ceramic oxide pre-form according to claim 1 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 9. The green ceramic oxide pre-form according to claim 1 wherein said green ceramic oxide material, when sufficiently heated, provides porous, alpha alumina, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 10. A method for making a green ceramic oxide pre-form, the method comprising:
positioning at least one elongated fiber insert in a cavity, the fiber insert comprising substantially continuous alpha alumina fibers having lengths of at least 5 cm, wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned; introducing a slurry into the cavity such that a pre-determined portion of the elongated fiber insert is coated with the slurry, the slurry comprising liquid medium and discontinuous ceramic oxide fibers dispersed therein; removing a sufficient amount of the liquid medium to cause the discontinuous fibers to consolidate and secure the fiber insert to provide an article comprising the elongated fiber insert and the discontinuous fibers, wherein the consolidation of the discontinuous fibers extends along at least a portion of the length of the fiber insert; and drying the consolidated article to provide a green ceramic oxide pre-form comprising the elongated fiber insert and the discontinuous fibers, wherein at least one consolidation of the discontinuous fibers secures the fiber insert in place, wherein the consolidation of discontinuous fibers extends along at least a portion of the length of the fiber insert, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 11. The method according to claim 10 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 12. The method according to claim 10 wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 13. The method according to claim 10 wherein the green ceramic oxide material, when sufficiently heated, provides porous, alpha alumina.
- 14. The method according to claim 10 wherein the substantially continuous alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 15. The method according to claim 10 wherein the fiber insert further comprises fugitive binder material bonding at least a portion of the substantially continuous alpha alumina fibers together.
- 16. The method according to claim 10 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 17. The method according to claim 10 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 18. The method according to claim 10 wherein the green ceramic oxide material, when sufficiently heated, provides porous, alpha alumina, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 19. A method for making a green ceramic oxide pre-form, the method comprising:
positioning at least one elongated fiber insert in a cavity, the fiber insert comprising substantially continuous alpha alumina fibers having lengths of at least 5 cm, wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned; introducing a slurry into the cavity such that a pre-determined portion of the elongated fiber insert is coated with the slurry, the slurry comprising liquid medium and discontinuous ceramic oxide fibers dispersed therein; and removing a sufficient amount of the liquid medium from the slurry to cause the discontinuous fibers to consolidate and secure the fiber insert to provide an article comprising the elongated fiber insert and the discontinuous fibers, wherein the consolidation of the discontinuous fibers extends along at least a portion of the length of the fiber insert, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 20. The method according to claim 19 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 21. The method according to claim 19 wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 22. The method according to claim 19 wherein the substantially continuous alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 23. The method according to claim 19 wherein the fiber insert further comprises fugitive binder material bonding at least a portion of the substantially continuous, longitudinally aligned, alpha alumina fibers together.
- 24. The method according to claim 23 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 25. The method according to claim 19 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 26. A porous ceramic oxide pre-form comprising porous ceramic oxide material and substantially continuous alpha alumina fibers having lengths of at least 5 cm, the porous ceramic oxide material securing the substantially continuous alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 27. The ceramic oxide pre-form according to claim 26 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 28. The ceramic oxide pre-form according to claim 26 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 29. The ceramic oxide pre-form according to claim 26 wherein the substantially continuous alpha alumina fibers have a first Young's modulus and the ceramic oxide material has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus.
- 30. The ceramic oxide pre-form according to claim 26 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers.
- 31. The ceramic oxide pre-form according to claim 26 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section.
- 32. The ceramic oxide pre-form according to claim 26 wherein the ceramic oxide pre-form is elongated and has a rectangular cross-section perpendicular to the length of the substantially continuous alpha alumina fibers.
- 33. The ceramic oxide pre-form according to claim 26 wherein the ceramic oxide pre-form is elongated and has substantially constant cross-sectional area.
- 34. The ceramic oxide pre-form according to claim 26 wherein the substantially continuous alpha alumina fibers are encapsulated within the porous ceramic oxide material.
- 35. The ceramic oxide pre-form according to claim 26 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 36. The ceramic oxide pre-form according to claim 35, wherein the porous ceramic oxide material is comprised of alpha alumina.
- 37. The ceramic oxide pre-form according to claim 35, wherein the substantially continuous alpha alumina fibers have a first Young's modulus and the ceramic oxide material has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus.
- 38. The ceramic oxide pre-form according to claim 35 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers.
- 39. The ceramic oxide pre-form according to claim 35 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section.
- 40. The ceramic oxide pre-form according to claim 35, wherein the substantially continuous alpha alumina fibers are encapsulated within the porous ceramic oxide material.
- 41. A porous ceramic oxide pre-form comprising porous ceramic oxide material and substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm, the porous ceramic oxide material having an open porosity of at least 85% by volume and securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers.
- 42. The ceramic oxide pre-form according to claim 41 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 43. The ceramic oxide pre-form according to claim 41 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 44. The ceramic oxide pre-form according to claim 41 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus.
- 45. The ceramic oxide pre-form according to claim 41 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers.
- 46. The ceramic oxide pre-form according to claim 41 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section.
- 47. The ceramic oxide pre-form according to claim 41 wherein the ceramic oxide pre-form is elongated and has a rectangular cross-section perpendicular to the length of the substantially continuous alpha alumina fibers.
- 48. The ceramic oxide pre-form according to claim 41 wherein the ceramic oxide pre-form is elongated and has substantially constant cross-sectional area.
- 49. The ceramic oxide pre-form according to claim 41 wherein the substantially continuous alpha alumina fibers are encapsulated within the porous ceramic oxide material.
- 50. The ceramic oxide pre-form according to claim 41 wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 51. The ceramic oxide pre-form according to claim 41 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 52. The ceramic oxide pre-form according to claim 51 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 53. The ceramic oxide pre-form according to claim 51 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus.
- 54. The ceramic oxide pre-form according to claim 51 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers.
- 55. The ceramic oxide pre-form according to claim 51 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section.
- 56. The ceramic oxide pre-form according to claim 51 wherein the substantially continuous alpha alumina fibers are encapsulated within the porous ceramic oxide material.
- 57. The ceramic oxide pre-form according to claim 51 wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 58. A method for making a porous ceramic oxide, the method comprising:
positioning at least one elongated fiber insert in a cavity, the fiber insert comprising substantially continuous alpha alumina fibers having lengths of at least 5 cm, wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned; introducing a slurry into the cavity such that a pre-determined portion of the elongated fiber insert is coated with the slurry, the slurry comprising liquid medium and discontinuous ceramic oxide fibers dispersed therein; removing at least a sufficient amount of the liquid medium to cause the discontinuous fibers to consolidate and secure the fiber insert to provide an article comprising the elongated fiber insert and the discontinuous fibers, wherein the consolidation of the discontinuous fibers extends along at least a portion of the length of the fiber insert; drying the consolidated article to provide a green ceramic oxide pre-form comprising the elongated fiber insert and the discontinuous fibers, wherein at least one consolidation of the discontinuous fibers secures the fiber insert in place, wherein the consolidation of the discontinuous fibers extends along at least a portion of the length of the fiber insert; and heating the green ceramic oxide pre-form to at least one temperature sufficient to provide a porous ceramic oxide pre-form comprising porous ceramic oxide material securing the substantially continuous alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 59. The method according to claim 58 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 60. The method according to claim 58 wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 61. The method according to claim 58 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 62. The method according to claim 58 wherein the fiber insert further comprises fugitive binder material bonding at least a portion of the substantially continuous, longitudinally aligned, alpha alumina fibers together.
- 63. The method according to claim 62 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 64. The method according to claim 58 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 65. A method for making a porous ceramic oxide, the method comprising:
positioning at least one elongated fiber insert in a cavity, the fiber insert comprising substantially continuous alpha alumina fibers having lengths of at least 5 cm, wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned; introducing a slurry into the cavity such that a pre-determined portion of the elongated fiber insert is coated with the slurry, the slurry comprising liquid medium and discontinuous ceramic oxide fibers dispersed therein; removing a sufficient amount of the liquid medium from the slurry to cause the discontinuous fibers to consolidate and secure the fiber insert to provide an article comprising the elongated fiber insert and the discontinuous fibers, wherein the consolidation of discontinuous fibers extends along at least a portion of the length of the fiber insert; and heating the green ceramic oxide pre-form to at least one temperature sufficient to provide a porous ceramic oxide pre-form comprising porous ceramic oxide material securing the substantially continuous alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 66. The method according to claim 65 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 67. The method according to claim 65 wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 68. The method according to claim 65 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 69. The method according to claim 65 wherein the fiber insert further comprises fugitive binder material bonding at least a portion of the substantially continuous, longitudinally aligned, alpha alumina fibers together.
- 70. The method according to claim 69 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 71. The method according to claim 65 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 72. A method for making a porous ceramic oxide, the method comprising:
positioning at least one elongated fiber insert in a cavity, the fiber insert comprising substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm; introducing a slurry into the cavity such that a pre-determined portion of the elongated fiber insert is coated with the slurry, the slurry comprising liquid medium and discontinuous ceramic oxide fibers dispersed therein; removing at least a sufficient amount of the liquid medium to cause the discontinuous fibers to consolidate and secure the fiber insert to provide an article comprising the elongated fiber insert and the discontinuous fibers, wherein the consolidation of the discontinuous fibers extends along at least a portion of the length of the fiber insert; and drying the consolidated article to provide a green ceramic oxide pre-form comprising the elongated fiber insert and the discontinuous fibers, wherein at least one consolidation of the discontinuous fibers secures the fiber insert in place, and wherein the consolidation of the discontinuous fibers extends along at least a portion of the length of the fiber insert; and heating the green ceramic oxide pre-form to at least one temperature sufficient to provide a porous ceramic oxide pre-form comprising porous ceramic oxide material having an open porosity of at least 85% by volume securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers.
- 73. The method according to claim 72 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 74. The method according to claim 72 wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 75. The method according to claim 72 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 76. The method according to claim 72 wherein the fiber insert further comprises fugitive binder material bonding at least a portion of the substantially continuous, longitudinally aligned, alpha alumina fibers together.
- 77. The method according to claim 76 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 78. The method according to claim 72 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 79. A method for making a porous ceramic oxide, the method comprising:
positioning at least one elongated fiber insert in a cavity, the fiber insert comprising substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm; introducing a slurry into the cavity such that a pre-determined portion of the elongated fiber insert is coated with the slurry, the slurry comprising liquid medium and discontinuous ceramic oxide fibers dispersed therein; removing a sufficient amount of the liquid medium from the slurry to cause the discontinuous fibers to consolidate and secure the fiber insert to provide an article comprising the elongated fiber insert and the discontinuous fibers, wherein the discontinuous fibers consolidate to secure the fiber insert in place, and wherein the consolidation of discontinuous fibers extends along at least a portion of the length of the fiber insert; and heating the green ceramic oxide pre-form to at least one temperature sufficient to provide a porous ceramic oxide pre-form comprising porous ceramic oxide material having an open porosity of at least 85% by volume securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers.
- 80. The green ceramic oxide pre-form according to claim 79 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 81. The method according to claim 79 wherein at least a portion of the discontinuous fibers is alpha alumina discontinuous fibers.
- 82. The method according to claim 79 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers are encapsulated within the green ceramic oxide material.
- 83. The method according to claim 79 wherein the fiber insert further comprises fugitive binder material bonding at least a portion of the substantially continuous, longitudinally aligned, alpha alumina fibers together.
- 84. The method according to claim 79 wherein the fugitive binder material is selected from the group consisting of wax, polyvinyl alcohol, polyvinyl pyrrolidone, epoxy resin, and combinations thereof.
- 85. The method according to claim 79 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 86. A porous ceramic oxide pre-form comprising:
a first porous ceramic article including an aperture for receiving a porous ceramic oxide; and a second ceramic article positioned in the aperture, the second ceramic article comprising porous ceramic oxide material and substantially continuous alpha alumina fibers having lengths of at least 5 cm, the porous ceramic oxide material securing substantially continuous alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 87. The ceramic oxide pre-form according to claim 86 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 88. The ceramic oxide pre-form according to claim 86 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina.
- 89. The ceramic oxide pre-form according to claim 86 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material of the second ceramic article has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus, and wherein the first porous ceramic article comprises ceramic oxide material having a third Young's modulus, and wherein the second Young's modulus is greater than the third Young's modulus.
- 90. The porous ceramic oxide pre-form according to claim 86 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 91. The ceramic oxide pre-form according to claim 90 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina.
- 92. The ceramic oxide pre-form according to claim 90 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material of the second ceramic article has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus, and wherein the first porous ceramic article comprises ceramic oxide material having a third Young's modulus, and wherein the second Young's modulus is greater than the third Young's modulus.
- 93. A porous ceramic oxide pre-form comprising:
a first porous ceramic article including an aperture for receiving a porous ceramic oxide; and a second ceramic article positioned in the aperture, the second ceramic article comprising porous ceramic oxide material and substantially continuous alpha alumina fibers having lengths of at least 5 cm, the porous ceramic oxide material having an open porosity of at least 85% by volume securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers.
- 94. The ceramic oxide pre-form according to claim 93 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 95. The ceramic oxide pre-form according to claim 93 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 96. The ceramic oxide pre-form according to claim 93 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material of the second ceramic article has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus, and wherein the first porous ceramic article comprises ceramic oxide material having a third Young's modulus, and wherein the second Young's modulus is greater than the third Young's modulus.
- 97. The porous ceramic oxide pre-form according to claim 93 wherein at least a portion of the substantially continuous, longitudinally aligned, alpha alumina fibers is in the form of tows.
- 98. The ceramic oxide pre-form according to claim 93 wherein the substantially continuous, longitudinally aligned, alpha alumina fibers are in the form of tows, and wherein the porous ceramic oxide material is comprised of alpha alumina.
- 99. A method for making a porous ceramic oxide pre-form for an article comprising metal matrix material, the method comprising:
designing an article to comprise metal matrix composite material reinforced, at least in part, with substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm, the metal matrix composite material to comprise at least one ceramic oxide pre-form comprising ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers, wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus; and preparing, based on the resulting design, a porous ceramic oxide pre-form comprising the ceramic oxide material securing the substantially continuous, alpha alumina fibers in place, wherein the ceramic oxide material extends along at least a portion of the length of the alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 100. The method according to claim 99 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 101. The method according to claim 99 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina.
- 102. The method according to claim 99 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 103. The method according to claim 102 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina.
- 104. The method according to claim 102 the metal matrix is one of aluminum or an alloy thereof.
- 105. The method according to claim 99 wherein the metal matrix is one of aluminum or an alloy thereof.
- 106. A method for making a porous ceramic oxide pre-form for an article comprising metal matrix material, the method comprising:
designing an article to comprise metal matrix composite material reinforced, at least in part, with substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm, the metal matrix composite material to comprise at least one ceramic oxide pre-form comprising ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers, wherein the substantially continuous, longitudinally aligned, alpha alumina fibers have a first Young's modulus and the ceramic oxide material has a second Young's modulus, and wherein the first Young's modulus is greater than the second Young's modulus; and preparing, based on the resulting design, a porous ceramic oxide pre-form comprising the ceramic oxide material having an open porosity of at least 85% by volume securing substantially continuous alpha alumina fibers in place, wherein the ceramic oxide material extends along at least a portion of the length of the alpha alumina fibers.
- 107. The method according to claim 106 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 108. The method according to claim 106 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 109. The method according to claim 106 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 110. The method according to claim 109 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 111. The method according to claim 109 wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 112. The method according to claim 109 wherein the metal matrix is one of aluminum or an alloy thereof.
- 113. The method according to claim 106 wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 114. The method according to claim 106 wherein the metal matrix is one of aluminum or an alloy thereof.
- 115. A method for making a porous ceramic oxide pre-form for an article comprising metal matrix material, the method comprising:
designing an article to comprise metal matrix composite material reinforced, at least in part, with substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm; preparing, based on the resulting design, an elongated pre-form comprising the substantially continuous, longitudinally aligned, alpha alumina fibers and binder material bonding fibers together; preparing a green ceramic oxide pre-form comprising green ceramic oxide material extending along at least a portion of the length of the elongated pre-form; and heating the green ceramic oxide pre-form to provide a porous ceramic oxide pre-form comprising ceramic oxide material securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the ceramic oxide material extends along at least a portion of the length of the alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 116. The method according to claim 115 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 117. The method according to claim 115 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 118. The method according to claim 115 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 119. The method according to claim 118 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 120. The method according to claim 118 wherein the metal matrix is at least one of aluminum or an alloy thereof.
- 121. The method according to claim 115 wherein the metal matrix is at least one of aluminum or an alloy thereof.
- 122. A method for making a porous ceramic oxide pre-form for an article comprising metal matrix material, the method comprising:
designing an article to comprise metal matrix composite material reinforced, at least in part, with substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm; preparing, based on the resulting design, an elongated pre-form comprising the substantially continuous, longitudinally aligned, alpha alumina and binder material bonding fibers together; preparing a green ceramic oxide pre-form comprising green ceramic oxide material extending along at least a portion of the length of the elongated pre-form; and heating the green ceramic oxide pre-form to provide a porous ceramic oxide pre-form comprising ceramic oxide material having an open porosity of at least 85% by volume securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the ceramic oxide material extends along at least a portion of the length of the alpha alumina fibers.
- 123. The method according to claim 122 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 124. The method according to claim 122 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 125. The method according to claim 122 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 126. The method according to claim 125 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 127. The method according to claim 125 wherein the metal matrix is at least one of aluminum or an alloy thereof.
- 128. The method according to claim 122 wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 129. The method according to claim 122 wherein the metal matrix is at least one of aluminum or an alloy thereof.
- 130. A metal matrix composite article comprising a porous ceramic oxide and metal matrix material, wherein the ceramic oxide pre-form comprises substantially continuous alpha alumina fibers having lengths of at least 5 cm and a porous ceramic oxide material extending along at least a portion of the length of the substantially continuous alpha alumina fibers, wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned, and wherein the porous ceramic oxide material is infiltrated with at least a portion of the metal matrix material.
- 131. The metal matrix composite article according to claim 130 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 132. The metal matrix composite article according to claim 130 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 133. The metal matrix composite article according to claim 132 wherein the metal matrix material is aluminum or an alloy thereof.
- 134. The metal matrix composite article according to claim 130 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers.
- 135. The metal matrix composite article according to claim 130 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section.
- 136. The metal matrix composite article according to claim 130 wherein the ceramic oxide pre-form is elongated and has a rectangular cross-section perpendicular to the length of the substantially continuous alpha alumina fibers.
- 137. The metal matrix composite article according to claim 130 wherein the ceramic oxide pre-form is elongated and has substantially constant cross-sectional area.
- 138. The metal matrix composite article according to claim 130 wherein the substantially continuous alpha alumina fibers are encapsulated within the porous ceramic oxide material.
- 139. The metal matrix composite article according to claim 130 wherein the metal matrix material is aluminum or an alloy thereof.
- 140. The metal matrix composite article according to claim 130 wherein the article is a brake caliper.
- 141. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 140 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 142. The metal matrix composite article according to claim 130 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows, and wherein the porous ceramic oxide material is comprised of alpha alumina.
- 143. The metal matrix composite article according to claim 130 wherein the metal matrix material is aluminum or an alloy thereof, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 144. The metal matrix composite article according to claim 130 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 145. The metal matrix composite article according to claim 130 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 146. The metal matrix composite article according to claim 130 wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows, and wherein the article is a brake caliper.
- 147. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 146 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 148. A metal matrix composite article comprising a porous ceramic oxide and metal matrix material, wherein the ceramic oxide pre-form comprises substantially continuous, longitudinally aligned, alpha alumina fibers having lengths of at least 5 cm and a porous ceramic oxide material having an open porosity of at least 85% by volume extending along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the porous ceramic oxide material is infiltrated with at least a portion of the metal matrix material.
- 149. The metal matrix composite article according to claim 148 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 150. The metal matrix composite article according to claim 148 wherein the porous ceramic oxide material is comprised of alpha alumina.
- 151. The metal matrix composite article according to claim 148 wherein the metal matrix material is aluminum or an alloy thereof.
- 152. The metal matrix composite article according to claim 148 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers.
- 153. The metal matrix composite article according to claim 148 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section.
- 154. The metal matrix composite article according to claim 148 wherein the ceramic oxide pre-form is elongated and has a rectangular cross-section perpendicular to the length of the substantially continuous alpha alumina fibers.
- 155. The metal matrix composite article according to claim 148 wherein the ceramic oxide pre-form is elongated and has substantially constant cross-sectional area.
- 156. The metal matrix composite article according to claim 148 wherein the substantially continuous alpha alumina fibers are encapsulated within the porous ceramic oxide material.
- 157. The metal matrix composite article according to claim 148 wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned.
- 158. The metal matrix composite article according to claim 148 wherein the metal matrix material is aluminum or an alloy thereof.
- 159. The metal matrix composite article according to claim 148 wherein the article is a brake caliper.
- 160. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 159 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 161. The metal matrix composite article according to claim 148 wherein the porous ceramic oxide material is comprised of alpha alumina, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 162. The metal matrix composite article according to claim 148 wherein the metal matrix material is aluminum or an alloy thereof, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 163. The metal matrix composite article according to claim 148 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 164. The metal matrix composite article according to claim 148 comprising at least two groupings of the substantially continuous alpha alumina fibers spaced apart with the porous ceramic oxide material between the groupings of substantially continuous alpha alumina fibers, wherein at least two of the groupings having a rectangular cross-section, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 165. The metal matrix composite article according to claim 148 wherein the metal matrix material is aluminum or an alloy thereof, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 166. The metal matrix composite article according to claim 148 wherein the article is a brake caliper, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 167. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 166 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 168. A metal matrix composite article comprising a porous ceramic oxide and metal matrix material, wherein the ceramic oxide pre-form comprises:
a first porous ceramic article including an aperture for receiving a porous ceramic oxide; and a second ceramic article positioned in the aperture, the second ceramic article comprising porous ceramic oxide material and substantially continuous alpha alumina fibers having lengths of at least 5 cm, the porous ceramic oxide material securing the substantially continuous alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous alpha alumina fibers, and wherein the substantially continuous alpha alumina fibers are essentially longitudinally aligned, and wherein the porous ceramic oxide material is infiltrated with at least a portion of the metal matrix material.
- 169. The metal matrix composite article according to claim 168 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 170. The metal matrix composite article according to claim 168 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina.
- 171. The metal matrix composite article according to claim 168 wherein the article is a brake caliper.
- 172. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 171 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 173. The metal matrix composite article according to claim 168 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 174. The metal matrix composite article according to claim 168 wherein the article is a brake caliper, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 175. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 174 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 176. A metal matrix composite article comprising a porous ceramic oxide and metal matrix, wherein the ceramic oxide pre-form comprises:
a first porous ceramic article including an aperture for receiving a porous ceramic oxide; and a second ceramic article positioned in the aperture, the second ceramic article comprising porous ceramic oxide material having an open porosity of at least 85% by volume and substantially continuous alpha alumina fibers having lengths of at least 5 cm, the porous ceramic oxide material securing the substantially continuous, longitudinally aligned, alpha alumina fibers in place, wherein the porous ceramic oxide material extends along at least a portion of the length of the substantially continuous, longitudinally aligned, alpha alumina fibers, and wherein the porous ceramic oxide material is infiltrated with at least a portion of the metal matrix material.
- 177. The metal matrix composite article according to claim 176 wherein the substantially continuous alpha alumina fibers have lengths of at least 10 cm.
- 178. The metal matrix composite article according to claim 176 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina.
- 179. The metal matrix composite article according to claim 176 wherein the article is a brake caliper.
- 180. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 179 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
- 181. The metal matrix composite article according to claim 178 wherein the porous ceramic oxide material of the second ceramic article is comprised of alpha alumina, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 182. The metal matrix composite article according to claim 179 wherein the article is a brake caliper, and wherein at least a portion of the substantially continuous alpha alumina fibers is in the form of tows.
- 183. A disc brake for a motor vehicle comprising a rotor; inner and outer brake pads disposed on opposite sides of the rotor and movable into braking engagement therewith; a piston for urging the inner brake pad against the rotor; and the brake caliper according to claim 182 comprising a body member having a cylinder positioned on one side of the rotor and containing the piston, an arm member positioned on the other side of the rotor and supporting the outer brake pad, and a bridge extending between the body member and the arm member across the plane of the rotor.
Parent Case Info
[0001] This application claims priority to U.S. Provisional Patent Application No. 60/236,091, filed Sep. 28, 2000, the disclosure of which is incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60236091 |
Sep 2000 |
US |