Heat exchangers, heat exchanger tubes, and additive manufacturing cold spray processes for producing the same

What is claimed is: 1. A method for producing a heat exchanger (HX) tube having an elongated tube body, the method comprising: providing a sacrificial release layer formed on a mandrel; producing at least the elongated tube body of the HX tube by depositing a feedstock powder over the mandrel utilizing a cold spray process; and after producing, removing the HX tube from the mandrel by dissolving the sacrificial release layer to release the HX tube from the mandrel. 2. The method of claim 1 further comprising selecting the feedstock powder to comprise a Non-Equilibrium Alloy (NEA) predominately composed of aluminum, by weight. 3. The method of claim 2 wherein the NEA feedstock powder comprises an alloy matrix throughout which a first minority constituent is dispersed, the first minority constituent precipitating from the alloy matrix when the NEA feedstock powder is exposed to temperatures exceeding a critical temperature threshold (T CRITICAL ) for a predetermined time period; wherein the HX tube is exposed to a maximum temperature (T SPRAY_MAX ) during the cold spray process; and wherein T SPRAY_MAX is maintained below T CRITICAL to preserve a non-equilibrium state of the NEA feedstock powder through the cold spray process. 4. The method of claim 3 wherein T CRITICAL is less than a melt point of the NEA feedstock powder and greater than 300 degrees Celsius. 5. The method of claim 2 further comprising selecting the NEA feedstock powder to contain, by weight percent: between 85 and 90 aluminum; between 8 and 10 percent iron; between 1 and 3 percent silicon; and between 1 and 2 percent vanadium. 6. The method of claim 1 further comprising selecting at least a portion of the mandrel to have a polygonal cross-sectional geometry, as taken in a section plan orthogonal to a longitudinal axis of the mandrel, the polygonal cross-sectional geometry transferred to at least a portion of the elongated tube body spray-deposited onto the outer surfaces of the mandrel. 7. The method of claim 1 further comprising controlling the cold spray process to impart the elongated tube body with an increasing wall thickness when moving toward a terminal end portion of the first MIX tube. 8. The method of claim 2 wherein utilizing a cold spray process further comprises: rotating the mandrel in a first direction by a predetermined angular displacement to position a first side of the mandrel with respect to a nozzle of a cold spray apparatus utilized to deposit the elongated tube body; after rotating the mandrel, depositing the NEA feedstock powder onto the first side of the mandrel utilizing a sweeping motion during which the nozzle of the cold spray apparatus is moved with respect to the mandrel along the longitudinal axis thereof; and repeating the steps of rotating and depositing to build-up the elongated tube body over the mandrel. 9. The method of claim 3 , wherein after utilizing the cold spray process, heat treating the HX tube utilizing an annealing process having a maximum anneal temperature (T ANNEAL_MAX ) less than T CRITICAL . 10. The method of claim 1 wherein the dissolving the sacrificial release layer further comprises submerging the HX tube and the mandrel in a chemical bath. 11. A method for producing a heat exchanger (HX) tube having an elongated tube body, the method comprising: providing a mandrel with a sacrificial release layer, the mandrel including a solvent-receiving flow channel and the sacrificial release layer including a plug portion that blocks an outlet of the solvent-receiving flow channel; producing at least the elongated tube body of the HX tube by depositing a feedstock powder over the mandrel utilizing a cold spray process; and after producing, removing the HX tube from the mandrel by introducing an etchant into the solvent-receiving flow channel to dissolve the plug portion and a remainder of the sacrificial release layer.