Resistors for dynamic braking

What is claimed is: 1. A resistor comprising: an elongated cylindrical body that extends along a center axis from a first terminal end to an opposite, second terminal end, the body having elongated members interconnected to one another at nodes to define openings between the nodes and the elongated members for flow therethrough of a cooling fluid, wherein the elongated members and the nodes form a lattice structure with the elongated members being elongated in multiple different directions relative to each other in a three-dimensional space, and at least some of the nodes are located at different radial distances from the center axis, wherein the body is configured to receive electric current from a powered system and to conduct and provide electric resistance to the electric current to dissipate at least part of the electric current as heat from the body, wherein the body also is configured to be coupled with at least one other resistor of the powered system in one or more of a parallel or series arrangement in an electric circuit. 2. The resistor of claim 1 , wherein the body is a fractal structure defined by the elongated members and the nodes. 3. The resistor of claim 1 , wherein the body is a tube defined by the elongated members and the nodes, the tube having an open interior channel, the openings between the nodes and the elongated members fluidly connected to the interior channel. 4. The resistor of claim 1 , wherein the body includes multiple rows of the openings along a length of the cylindrical body, each of the rows including multiple of the openings spaced apart around a circumference of the cylindrical body. 5. The resistor of claim 1 , wherein the first terminal end of the cylindrical body is configured to receive the electric current and the second terminal end is configured to be coupled with the at least one other resistor. 6. The resistor of claim 1 , wherein the openings defined between the elongated members and the nodes are interconnected to enable the cooling fluid to flow through the body via the openings to dissipate the heat from the body. 7. The resistor of claim 1 , wherein the body includes one or more of a ceramic material or a metallic material. 8. The resistor of claim 1 , wherein the body has an elongated center portion and an elongated outer portion disposed radially outside of the center portion relative to the center axis of the body and surrounding the center portion, the elongated members and the nodes disposed at both the center portion and the outer portion. 9. The resistor of claim 8 , wherein the center portion of the body has a different density of the nodes and the elongated members than the outer portion of the body. 10. The resistor of claim 9 , wherein the elongated members and the nodes of the outer portion are closer together than the elongated members and the nodes of the center portion such that the openings in the outer portion are smaller than the openings in the center portion. 11. The resistor of claim 1 , wherein the powered system, the resistor, and the at least one other resistor are disposed on a vehicle. 12. The resistor of claim 1 , wherein the elongated members and the nodes are disposed along an entire length of the cylindrical body from the first terminal end to the second terminal end to provide a continuous electrically conductive path from the first terminal end to the second terminal end through the elongated members and the nodes. 13. A method for manufacturing a resistor, the method comprising: successively applying layers of material on each other, each of the layers forming a cross-sectional shape of a three-dimensional resistor body; and fusing adjacent layers of the layers that are successively applied with each other to form the resistor body, wherein the layers are successively applied and fused to form the resistor body to have an elongated cylindrical shape that extends along a center axis from a first terminal end to an opposite, second terminal end, the resistor body comprised of elongated members interconnected to one another at nodes to define openings between the nodes and the elongated members for flow therethrough of a cooling fluid, wherein the elongated members and the nodes form a lattice structure with the elongated members being elongated in multiple different directions relative to each other in a three-dimensional space, and at least some of the nodes are located at different radial distances from the center axis, wherein the resistor body is formed to receive electric current from a powered system and to dissipate at least part of the electric current as heat from the resistor body, and the resistor body is formed to be coupled with at least one other resistor of the powered system in one or more of a parallel or series arrangement in an electric circuit. 14. The method of claim 13 , wherein the layers are successively applied and the adjacent layers are fused together to form the resistor body as a fractal structure defined by the elongated members and the nodes. 15. The method of claim 13 , wherein the layers are successively applied and the adjacent layers are fused together to form the resistor body having an open interior channel, the openings between the nodes and the elongated members fluidly connected to the interior channel. 16. The method of claim 13 , wherein the layers are successively applied and the adjacent layers are fused together to form the resistor body as a tube defining an interior channel that extends an entire length of the resistor body, wherein the center axis of the resistor body extends through the interior channel. 17. The method of claim 13 , wherein the layers are successively applied and the adjacent layers are fused together to form the resistor body with an elongated center portion and an elongated outer portion disposed radially outside of the center portion relative to the center axis of the body and surrounding the center portion, the elongated members and the nodes disposed at both the center portion and the outer portion. 18. A resistor comprising: an elongated cylindrical body that extends along a center axis from a first terminal end to an opposite, second terminal end, the body having elongated members interconnected to one another at nodes to define openings between the nodes and the elongated members for flow therethrough of a cooling fluid, the elongated members and the nodes disposed along an entire length of the body from the first terminal end to the second terminal end to provide a continuous electrically conductive path from the first terminal end to the second terminal end through the elongated members and the nodes, wherein the body is configured to receive electric current at the first terminal end from a powered system and to conduct and provide electric resistance to the electric current to dissipate at least part of the electric current as heat from the body, and the second terminal end of the body is configured to be coupled with at least one other resistor of the powered system in one or more of a parallel or series arrangement in an electric circuit. 19. The resistor of claim 18 , wherein the body defines an interior channel extending from the first terminal end to the second terminal end and the center axis extends through the interior channel, wherein the openings between the nodes and the elongated members are fluidly connected to the interior channel. 20. The resistor of claim 18 , wherein the elongated members and the nodes form a lattice structure with the elongated mem