Apparatus and methods for additively manufacturing microtube heat exchangers

What is claimed is: 1. An additively manufactured heat exchanger, comprising: a microtube array comprising a plurality of microtubes forming a substantially parallel array and extending from a base plate, the plurality of microtubes comprising a first plurality of microtubes and a second plurality of microtubes; a header comprising a plurality of header sections, the plurality of header sections comprising: a first header section integrated with the first plurality of microtubes at the base plate and configured to direct a first fluid through the first plurality of microtubes so as to exchange heat with an external fluid; and a second header section integrated with the second plurality of microtubes at the base plate and configured to direct a second fluid through the second plurality of microtubes so as to exchange heat with the external fluid, and a fin disposed between each adjacent microtube in at least one column of microtubes, the fin further being disposed perpendicular to and starting from the base plate to a surface of the microtubes; wherein the microtube array, the base plate, the fin, and the header are three-dimensionally (3-D) printed together to form a continuous body. 2. The heat exchanger of claim 1 , wherein the microtube array has a non-planar configuration relative to a plane normal to the base plate. 3. The heat exchanger of claim 1 , wherein the external fluid comprises a gas. 4. The heat exchanger of claim 1 , wherein a diameter of each of the plurality of microtubes is equal to or less than 2 millimeters (mm). 5. The heat exchanger of claim 1 , wherein the external fluid flows substantially orthogonal to a flow direction of the first and second fluids. 6. The heat exchanger of claim 1 , wherein the header comprises a top surface at the base plate or a section thereof, and at least one surface coupled longitudinally to the top surface at an angle relative to the top surface. 7. The heat exchanger of claim 1 , wherein at least one of the plurality of microtubes is curved. 8. The heat exchanger of claim 1 , wherein at least one of the plurality of microtubes is pleated. 9. The heat exchanger of claim 1 , wherein the header comprises a channel having a cross-sectional surface. 10. The heat exchanger of claim 9 , wherein the cross-sectional surface is substantially triangular. 11. The heat exchanger of claim 9 , wherein the channel is substantially orthogonal to the microtube array. 12. The heat exchanger of claim 9 , wherein the header comprises a first surface substantially parallel to the base plate, a second surface coupled longitudinally to the first surface at a first angle, and a third surface coupled longitudinally to the second surface at a second angle, the first, second, and third surfaces defining the channel. 13. The heat exchanger of claim 1 , wherein the microtube array has a non-planar configuration relative to a plane normal to first fluid flow. 14. The heat exchanger of claim 13 , wherein the non-planar configuration of the microtube array comprises a curved configuration. 15. The heat exchanger of claim 13 , wherein the non-planar configuration of the microtube array comprises a pleated configuration. 16. The heat exchanger of claim 1 , wherein the fin is configured to provide structural support to the column of microtubes. 17. The heat exchanger of claim 16 , further comprising a fin disposed between each adjacent microtube in at least one row of microtubes in the array. 18. The heat exchanger of claim 1 , wherein the heat exchanger is additively manufactured at an angle relative to the base plate; and the at least one fin configured to provide the microtube array with structural support. 19. An additively manufactured compact heat exchanger, comprising: a base plate; a first plurality of microtubes forming an array, the first plurality of microtubes substantially parallel and extending from the base plate; a first header section, the first header section integrated with the first plurality of microtubes at the base plate and configured to direct a first fluid through the first plurality of microtubes so as to exchange heat with an external fluid, and a fin disposed between each adjacent microtube in at least one column of the array, the fin further being disposed perpendicular to and starting from the base plate to a surface of the first plurality of microtubes; wherein the microtube array, the base plate, the fin, and the first header section are three-dimensionally printed together to form a continuous body. 20. The additively manufactured compact heat exchanger of claim 19 , further comprising: a second plurality of microtubes forming an array, the second plurality of microtubes substantially parallel and extending from the base plate; and a second header section, the second header section integrated with the second plurality of microtubes at the base plate and configured to direct a second fluid through the second plurality of microtubes so as to exchange heat with the external fluid. 21. The additively manufactured compact heat exchanger of claim 19 , wherein at least one of the first plurality of microtubes is curved. 22. The additively manufactured compact heat exchanger of claim 19 , wherein at least one of the first plurality of microtubes is pleated. 23. The additively manufactured compact heat exchanger of claim 19 , wherein the external fluid comprises a gas. 24. A transport vehicle, comprising: a three-dimensionally (3-D) printed support structure, the 3-D printed support structure comprising a 3-D printed microtube lattice array, a fin disposed between each adjacent microtube in at least one column of the 3-D printed microtube lattice array, the fin further being disposed perpendicular to and starting from the support structure to a surface of the 3-D printed microtube lattice array, the 3-D printed microtube lattice array configured to transfer heat between a first fluid and a second fluid, wherein the 3-D printed support structure is 3-D printed together to form a continuous body. 25. The transport vehicle of claim 24 , the 3-D printed microtube lattice array comprising: a plurality of microtubes configured to carry the first fluid; and a plurality of interstitial paths configured to a carry the second fluid. 26. The transport vehicle of claim 25 , wherein heat is transferred from the first fluid to the second fluid. 27. The transport vehicle of claim 25 , wherein heat is transferred from the second fluid to the first fluid. 28. The transport vehicle of claim 25 , wherein the first fluid is a liquid. 29. The transport vehicle of claim 28 , wherein the liquid is engine oil. 30. The transport vehicle of claim 25 , wherein the second fluid is engine coolant. 31. The transport vehicle of claim 25 , wherein the second fluid is a gas. 32. The transport vehicle of claim 31 , wherein the gas is forced air. 33. A method of additively manufacturing a heat exchanger in a transport vehicle using three dimensional (3D) printing, the method comprising: additively manufacturing a hollow support structure; additively manufacturing a microtube lattice array within the hollow support structure, and additively manufacturing a fin disposed between each adjacent microtube in at least one column of