Manufacturing of turbine shroud segment with internal cooling passages

1 . A method of manufacturing a turbine shroud segment with internal cooling passages, the method comprising: forming an insert from a low melting point material, the insert having a configuration corresponding to that of the internal cooling passages to be formed in the turbine shroud segment; positioning the insert in a metal injection mold defining a mold cavity having a configuration corresponding to the configuration of the turbine shroud segment to he produced; metal injection molding (MIM) a shroud body about the insert, including injecting a base metal powder mixture into the mold at a temperature inferior to a melting temperature of the insert; and removing the insert by applying a heat treatment to the shroud body at a temperature superior to the melting temperature of the insert, thereby causing the dissolution of the insert. 2 . The method defined in claim 1 , wherein applying a heat treatment comprises sintering the shroud body. 3 . The method defined in claim 1 , wherein the base metal powder mixture is injected at a temperature of not more than about 250 deg. Fahrenheit. 4 . The method defined in claim 1 , wherein the base metal powder mixture is injected at a pressure of not more than about 100 psi. 5 . The method defined in claim 1 , wherein the insert is made out of plastic and the base metal powder mixture is injected at a temperature inferior to about 250 deg. Fahrenheit and at a pressure inferior to about 100 psi. 6 . The method defined in claim 1 , wherein the low temperature melting material is selected from a group consisting of: plastic material, wax and Tin/Bismuth alloy. 7 . The method defined in claim 1 , wherein forming an insert comprises making a one piece body having a perforated panel section defining a network of channels. 8 . A method of manufacturing a shroud segment for a gas turbine engine, the method comprising: forming an insert having a perforated panel section defining a network of channels; metal injection molding (MIM) a shroud segment body about the insert, and dissolving the insert by subjecting the MIM shroud segment body to a heat treatment, the heat treatment including sintering the MIM shroud body. 9 . The method defined in claim 8 , wherein forming an insert comprises molding a solid plastic part having a configuration corresponding to a desired configuration of an internal cooling scheme of the shroud segment. 10 . The method defined in claim 8 , wherein the insert has a melting temperature which is superior to an injection temperature of the MIM material used to form the shroud body, and wherein the melting temperature of the insert is inferior to a sintering temperature of the MIM material. 11 . The method defined in claim 8 , comprising using pins to hold the insert in an injection mold defining a mold cavity having a configuration corresponding to that of the shroud segment to be produced, and wherein the pins also are used to create cooling holes in the MIM shroud segment body. 12 . The method defined in claim 10 , wherein the MIM material is injected at a temperature of not more than about 250 deg. Fahrenheit. 13 . The method defined in claim 10 , wherein the MIM material is injected at a pressure of not more than about 100 psi.