Phase change insert for ultrasound imaging probe

What is claimed is: 1 . An ultrasound imaging probe comprising: a housing formed of a layer of a thermally conductive material having an exterior surface and an interior surface defining an interior space therein and a tab extending inwardly from the interior surface into the interior space; an imaging device disposed within the interior space of the housing and including at least one heat-generating component; and at least one thermal energy storage insert spaced from and disposed in thermal contact with the imaging device within the interior space of the housing, the at least one thermal energy storage insert containing a phase change material (PCM) therein, an alignment feature formed within a wall of the at least one thermal energy storage insert and adapted to engage and receive a mechanical fastener extending between the interior surface of the housing and the at least one thermal energy storage insert to align the at least one thermal energy storage insert with the housing, and an exterior shape that conforms to the interior space of the housings wherein the alignment feature is an aperture in the wall of the at least one thermal energy storage insert adapted to seat on the mechanical fastener of the housing to align the at least one thermal energy storage insert with the housing, wherein the mechanical fastener is formed as the tab located on and extending outwardly from the interior surface of the housing into the interior space of the housing for insertion within the aperture, and wherein the at least one thermal energy storage insert is additively manufactured to conform to a shape of the interior space of the housing. 2 . The ultrasound imaging probe of claim 1 , wherein the at least one thermal energy storage insert is additively manufactured without gaps between walls of the at least one thermal energy storage insert. 3 . The ultrasound imaging probe of claim 1 , wherein the at least one thermal energy storage insert is formed of an additively manufactured heat conducting material. 4 . The ultrasound imaging probe of claim 1 , further comprising a heat spreader disposed within the interior space of the housing in thermal contact with the imaging device, and wherein the at least one thermal energy storage insert is attached to the heat spreader. 5 . The ultrasound imaging probe of claim 4 , wherein the at least one thermal energy storage insert is formed as a part of the heat spreader. 6 . The ultrasound imaging probe of claim 5 , wherein at least one thermal energy storage insert comprises a cover directly attached to the heat spreader to define a volume between the cover and the heat spreader wherein the PCM is contained within the volume. 7 . The ultrasound imaging probe of claim 1 , wherein the PCM is selected from a liquid PCM and a composite PCM. 8 . The ultrasound imaging probe of claim 1 , wherein the at least one thermal energy storage insert comprises multiple chambers within the at least one thermal energy storage insert. 9 . The ultrasound imaging probe of claim 8 , wherein the multiple chambers are not connected to one another. 10 . An ultrasound imaging system comprising: a processing unit configured to receive and process acquired ultrasound image data to create ultrasound images derived from the ultrasound image data; a display operably connected to the processing unit to present the created ultrasound images to a user; and an ultrasound imaging probe operably connected to the processing unit to obtain the ultrasound image data, the ultrasound imaging probe comprising: a housing consisting of a layer of a thermally conductive material having an exterior surface and an interior surface defining an interior space therein, and a tab extending inwardly from the interior surface into the interior space; an imaging device disposed within the interior space of the housing and including at least one heat-generating component; and at least one thermal energy storage insert spaced from and disposed in thermal contact with the imaging device within the interior space of the housing, the at least one thermal energy storage insert containing a phase change material (PCM) therein and an alignment feature formed within a wall of the at least one thermal energy storage insert and adapted to engage and receive a mechanical fastener extending between the interior surface of the housing and the at least one thermal energy storage insert to align the at least one thermal energy storage insert with the housing, wherein the thermal energy storage insert is manufactured with an exterior shape that conforms to the interior space of the housing, wherein the alignment feature is an aperture in the wall of the at least one thermal energy storage insert adapted to seat on the mechanical fastener of the housing to align the at least one thermal energy storage insert with the housing, wherein the mechanical fastener is formed as the located on and extending outwardly from the interior surface of the housing into the interior space of the housing for insertion within the aperture, and wherein the at least one thermal energy storage insert is additively manufactured to conform to a shape of the interior space of the housing. 11 . The ultrasound imaging system of claim 10 , wherein the at least one thermal energy storage insert is additively manufactured without gaps between walls of the at least one thermal energy storage insert.