Build part and method of additively manufacturing the build part

What is claimed is: 1. A method comprising: additively-manufacturing a build part by consecutively depositing and fusing layers of material in a stack oriented along a build axis, wherein the layers of material are consecutively deposited and fused according to a build plan to define one or more fluid channels through the build part for directing fluid through the build part, wherein the layers of material are consecutively deposited and fused to orient each of the one or more fluid channels such that a centerline of the respective fluid channel is angled no greater than a maximum offset angle relative to the build axis throughout the length of the respective fluid channel, wherein the maximum offset angle is no less than 45 degrees and no greater than 75 degrees, and wherein the layers of material are consecutively deposited and fused such that at least one of: (i) a first fluid channel of the one or more fluid channels includes a bend that separates a first segment of the first fluid channel from a second segment of the first fluid channel, and the centerline of the first fluid channel along the first segment is angled greater than the maximum offset angle relative to the centerline along the second segment; or (ii) the first fluid channel intersects a second fluid channel of the one or more fluid channels at a juncture location, and the centerline of the first fluid channel extending from the juncture location is angled greater than the maximum offset angle relative to the centerline of the second fluid channel extending from the juncture location. 2. The method of claim 1 , wherein the layers of material are consecutively deposited in the stack located on a platform such that the build part grows in a build direction relative to the platform, the build axis parallel to the build direction. 3. The method of claim 1 , wherein the maximum offset angle is no greater than 60 degrees. 4. The method of claim 1 , wherein the layers of material are consecutively deposited and fused such that the one or more fluid channels are free of internal support structures as the layers are deposited and fused to define the one or more fluid channels. 5. The method of claim 1 , wherein the layers of material are consecutively deposited and fused such that at least a subset of the one or more fluid channels has a circular cross-sectional shape. 6. The method of claim 1 , wherein the one or more fluid channels include multiple fluid channels, and additively-manufacturing the build part includes consecutively depositing and fusing the layers of material to define a hydraulic manifold that includes multiple interconnected pipes defining the fluid channels. 7. The method of claim 1 , wherein the build part is produced such that the first fluid channel intersects the second fluid channel at the juncture location, wherein the centerline of the first fluid channel extending from the juncture location is angled no greater than the maximum offset angle relative to the build axis, and the centerline of the second fluid channel extending from the juncture location is angled no greater than the maximum offset angle. 8. The method of claim 1 , wherein the build part is produced such that the first fluid channel includes the bend, and the centerline of the first fluid channel, along the length of the bend, is angled no greater than the maximum offset angle relative to the build axis. 9. The method of claim 1 , wherein the layers of material are composed of at least one metal. 10. The method of claim 1 , wherein the layers of material are consecutively deposited and fused such that the first fluid channel has a broad diameter section, a narrow diameter section, and a transition region extending from the broad diameter section to the narrow diameter section, and a tangent line extending from an inner wall of the first fluid channel along the transition region is angled no greater than the maximum offset angle relative to the build axis. 11. The method of claim 1 , wherein the layers of material are consecutively deposited and fused such that the one or more fluid channels include a primary fluid channel and multiple branch fluid channels that intersect the primary fluid channel at different locations along the length of the primary fluid channel, and wherein a line extending from a first end of the primary fluid channel to a second end of the primary fluid channel opposite the first end is oblique relative to the build axis. 12. A method comprising: producing a design for a build part that includes plural fluid channels extending through a body of the build part with at least some of the fluid channels extending in different directions and intersecting one another within the body, wherein producing the design includes determining a selected axis through the build part which is oriented no greater than a maximum offset angle relative to a respective centerline of each of the fluid channels, throughout the respective lengths of the fluid channels, the maximum offset angle being no less than 45 degrees and no greater than 75 degrees; selecting an orientation for the build part relative to a build surface of a platform such that the selected axis is orthogonal to the build surface; and generating, via one or more processors, a build plan based on the design and the orientation, the build plan including instructions for an additive manufacturing system to produce the build part on the platform in a build direction parallel to the selected axis. 13. The method of claim 12 , further comprising additively-manufacturing the build part by consecutively depositing and fusing layers of material in a stack according to the build plan. 14. The method of claim 12 , wherein the design is produced such that at least one of: (i) a first fluid channel of the fluid channels includes a bend that separates a first segment of the first fluid channel from a second segment of the first fluid channel, and the centerline of the first fluid channel along the first segment is angled greater than the maximum offset angle relative to the centerline along the second segment; or (ii) the first fluid channel intersects a second fluid channel of the fluid channels at a juncture location, and the centerline of the first fluid channel extending from the juncture location is angled greater than the maximum offset angle relative to the centerline of the second fluid channel extending from the juncture location. 15. The method of claim 12 , wherein the maximum offset angle is no greater than 60 degrees. 16. The method of claim 12 , wherein the build plan is generated such that the fluid channels are free of internal support structures as the build part is produced on the platform. 17. The method of claim 12 , wherein the build plan is generated such that build part is composed of at least one metal as the build part is produced on the platform. 18. The method of claim 12 , wherein the design for the build part is produced such that the build part represents a hydraulic manifold that includes multiple interconnected pipes defining the fluid channels. 19. The method of claim 12 , wherein a first fluid channel of the fluid channels has a broad diameter section, a narrow diameter section, and a transition region extending from the broad diameter section to the narrow diameter section, wherein the orientation for the build part is selected relative to the build surface such that a tangent line extending from an inner wall of the first fluid channel along the transition region is angled no greater than the maximum offset angle re