초록 ▼

A green body ceramic matrix composite material (30) is formed using ceramic fibers (32) in an intermediate state disposed in a green body ceramic matrix material (34). The fibers may be in either a dry but unfired (green) condition or in a partially fired condition. Selective control of the degree o

A green body ceramic matrix composite material (30) is formed using ceramic fibers (32) in an intermediate state disposed in a green body ceramic matrix material (34). The fibers may be in either a dry but unfired (green) condition or in a partially fired condition. Selective control of the degree of pre-firing (pre-shrinkage) of the fibers may be used to control the level of residual stresses within the resulting refractory material resulting from differential shrinkage of the fibers and the matrix material during processing of the composite material.

대표청구항 ▼

The invention claimed is: 1. A method of making a ceramic matrix composite refractory material, the method comprising: partially processing ceramic fibers to only pre-shrink the fibers; surrounding the partially pre-shrunk ceramic fibers with a ceramic matrix material in a green body state to form

The invention claimed is: 1. A method of making a ceramic matrix composite refractory material, the method comprising: partially processing ceramic fibers to only pre-shrink the fibers; surrounding the partially pre-shrunk ceramic fibers with a ceramic matrix material in a green body state to form a green body ceramic matrix composite material; and firing the green body ceramic matrix composite material to form a refractory material; wherein the amount of pre-shrinkage of the fibers is selected in response to an expected degree of shrinkage of the ceramic matrix material during the firing step. 2. The method of claim 1, further comprising partially pre-shrinking the fibers prior to the step of surrounding to a degree necessary to achieve a ratio of matrix shrinkage to fiber shrinkage during the steps of surrounding and firing of less than 5:1. 3. The method of claim 1, further comprising partially pre-shrinking the fibers prior to the step of surrounding to a degree necessary to achieve a ratio of matrix shrinkage to fiber shrinkage during the steps of surrounding and firing of less than 3:1. 4. The method of claim 1, further comprising partially pre-shrinking the fibers prior to the step of surrounding to a degree necessary to achieve a ratio of matrix shrinkage to fiber shrinkage during the steps of surrounding and firing of less than 2:1. 5. The method of claim 1, further comprising partially pre-shrinking the fibers prior to the step of surrounding to a degree necessary to achieve a ratio of matrix shrinkage to fiber shrinkage during the steps of surrounding and firing of approximately 1:1. 6. The method of claim 1, further comprising selecting the fibers to comprise alumina-silica. 7. The method of claim 1, further comprising selecting the matrix material to comprise alumina. 8. A method of making a ceramic matrix composite refractory material, the method comprising: selecting a type of ceramic fiber for use in a ceramic matrix composite material; determining an expected amount of shrinkage of the selected type of fiber during processing at elevated temperatures; selecting a type of ceramic matrix material; determining an expected amount of shrinkage of the matrix material during processing at elevated temperatures; partially pre-shrinking the ceramic fiber by a predetermined amount prior to surrounding the fiber with the matrix material to ton a ceramic matrix composite material; and firing the ceramic matrix composite material at an elevated temperature; wherein an amount of the pre-shrinkage of the fiber is controlled to be responsive to the expected amount of shrinkage of the selected matrix material so that shrinkage of the ceramic matrix composite material during firing is isotropic. 9. A method of making a ceramic matrix composite refractory material, the method comprising: selecting a type of ceramic fiber for use in a ceramic matrix composite material; determining an expected amount of shrinkage of the selected type of fiber during processing at elevated temperatures; selecting a first and a second type of ceramic matrix material; determining respective expected amounts of shrinkage of the first and the second types of matrix material during processing at elevated temperatures; and partially pre-shrinking the ceramic fiber by a predetermined amount prior to surrounding The fiber with a selected one of the first and the second types of matrix material to form a ceramic matrix composite material; and processing the ceramic matrix composite material at an elevated temperature; wherein an amount of the pre-shrinkage of the fiber is controlled to be responsive to the type of selected matrix material so that shrinkage of the fiber will correspond to shrinkage of the matrix material during the processing of the ceramic matrix composite material.