Composite stator sleeve for electric machine

What is claimed is: 1 . A stator housing assembly, comprising: a stator housing defining a stator cavity configured to contain a pressurized cooling fluid; and a stator sleeve defining a longitudinal axis and configured to encase the stator cavity, wherein the stator housing defines a first end section and a second end section that define the stator cavity, wherein the stator sleeve comprises a plurality of layers of composite materials that include more than one high strength fiber material, wherein the stator sleeve includes: a first sealing portion configured to position against the first end section of the stator housing; a second sealing portion configured to position against the second end section of the stator housing: and a medial portion between the first and second sealing portions, wherein the high strength fiber materials include a plurality of carbon fibers and a plurality of glass fibers, and wherein a proportion of glass fibers to carbon fibers is higher in the first and second sealing portions than the medial portion. 2 . The stator housing assembly of claim 1 , wherein a composition and direction of orientation of the high strength fiber materials varies along the longitudinal axis. 3 . The stator housing assembly of claim 1 , where a composition and direction of orientation of the high strength fiber materials is configured to reduce radial deflections in a center of the stator sleeve due to a change in temperature or pressure. 4 . The stator housing assembly of claim 1 , wherein a coefficient of thermal expansion (CTE) of each of the first and second sealing portions of the stator sleeve is greater than a CTE of the medial portion. 5 . The stator housing assembly of claim 1 , a composition of the composite materials of the plurality of layers of the first and second sealing portions is different from a composition of the composite materials of the plurality of layers of the medial portion. 6 . The stator housing assembly of claim 1 , wherein the stator sleeve defines an inner radial surface and an outer radial surface, and wherein the plurality of glass fibers line the inner and outer radial surfaces. 7 . The stator housing assembly of claim 1 , wherein the plurality of carbon fibers are oriented circumferentially around the longitudinal axis, and wherein the plurality of glass fibers are oriented multi-directionally and include a first plurality of glass fibers oriented around the longitudinal axis and a second plurality of glass fibers oriented along the longitudinal axis. 8 . The stator housing assembly of claim 1 , wherein each of the first and second end sections of the stator housing comprises one or more grooves extending around the longitudinal axis, each groove configured to receive at least one O-ring, wherein the first sealing portion is configured to position against an O-ring positioned around the first end section of the stator housing, and wherein the second sealing portion is configured to position against an O-ring positioned around the second end section of the stator housing. 9 . An electric machine, comprising: a shaft; a rotor coupled to the shaft and comprising a permanent magnet assembly; a stator comprising a stator core separated from the permanent magnet assembly of the rotor by a radial gap; and a stator housing assembly comprising: a stator housing defining a stator cavity configured to contain a pressurized cooling fluid, wherein the stator is positioned within the stator cavity; and a stator sleeve defining a longitudinal axis and positioned against the stator housing and within the radial gap, wherein the stator housing defines a first end section and a second end section that define the stator cavity, wherein the stator sleeve comprises a plurality of layers of composite materials that include more than one high strength fiber material, wherein the stator sleeve includes: a first sealing portion configured to position against the first end section of the stator housing; a second sealing portion configured to position against the second end section of the stator housing; and a medial portion between the first and second sealing portions, wherein the high strength fiber materials include a plurality of carbon fibers and a plurality of glass fibers, and wherein a proportion of glass fibers to carbon fibers is higher in the first and second sealing portions than the medial portion. 10 . The electric machine of claim 9 , wherein a composition and direction of orientation of the high strength fiber materials varies along the longitudinal axis. 11 . The electric machine of claim 9 , where a composition and direction of orientation of the high strength fiber materials is configured to reduce radial deflections in a center of the stator sleeve due to a change in temperature or pressure. 12 . A method of fabricating a stator sleeve, comprising: laying-up a plurality of plies with high strength fibers and resin; and polymerizing the resin to form the stator sleeve, wherein the stator sleeve defines a longitudinal axis and comprises a plurality of layers of composite materials that include more than one high strength fiber material, wherein the stator sleeve is configured to encase a stator cavity configured to contain a pressurized cooling fluid, wherein the stator sleeve includes: a first sealing portion configured to position against a first end section of a stator housing; a second sealing portion configured to position against a second end section of the stator housing; and a medial portion between the first and second sealing portions, wherein the more than one high strength fiber material includes a plurality of carbon fibers and a plurality of glass fibers, and wherein a proportion of glass fibers to carbon fibers is higher in the first and second sealing portions than the medial portion. 13 . The method of claim 12 , wherein the plurality of plies comprises: one or more glass plies, each comprising the plurality of glass fibers; and one or more carbon plies, each comprising the plurality of carbon fibers oriented unidirectionally around the longitudinal axis. 14 . The method of claim 13 , wherein the one or more carbon plies comprise: one or more long carbon plies extending a length of the stator sleeve; and one or more short carbon plies positioned within the medial portion, wherein each of the one or more short carbon plies extends less than the length of the stator sleeve. 15 . The method of claim 12 , wherein the plurality of plies use different combinations of high strength fibers for the medial portion and the first and second sealing portions of the stator sleeve. 16 . The method of claim 15 , wherein the plurality of plies further comprises one or more mixed plies, each comprising: a glass portion positioned within the first and second sealing portions and comprising the plurality of glass fibers; and a carbon portion positioned within the medial portion and comprising the plurality of carbon fibers. 17 . The method of claim 15 , wherein a coefficient of thermal expansion (CTE) of each of the first and second sealing portions of the stator sleeve is greater than a CTE of the medial portion.