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A hybrid rocket motor is manufactured by photopolymerizing the solid fuel grain in a stereolithography method, wherein fuel grains in a plastic matrix are deposited in layers for building a solid fuel rocket body in three dimensions for improved performance and for a compact design, the hybrid rocke

A hybrid rocket motor is manufactured by photopolymerizing the solid fuel grain in a stereolithography method, wherein fuel grains in a plastic matrix are deposited in layers for building a solid fuel rocket body in three dimensions for improved performance and for a compact design, the hybrid rocket motor including radial channels for defining a desired burn profile including the oxidizer to fuel burn ratio.

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1. A fuel grain for providing an exhaust, comprising: a solid fuel body;a solid fuel core;an entry having an entry gas flow;an exit having an exit gas flow for passing a gas flow through the fuel grain between the entry and the exit;at least two axial channels disposed between the entry and exit, th

1. A fuel grain for providing an exhaust, comprising: a solid fuel body;a solid fuel core;an entry having an entry gas flow;an exit having an exit gas flow for passing a gas flow through the fuel grain between the entry and the exit;at least two axial channels disposed between the entry and exit, the solid fuel body and solid fuel core at least partially defining the at least two axial channels, and only one of the at least two axial channels being in axial alignment with at least one of the entry and the exit; andat least one radial channel disposed between the entry and exit, and the at least one radial channel extending radially between two of the at least two axial channels and extending axially through only a portion of a longitudinal axis of the fuel grain, the solid fuel body and solid fuel core at least partially defining the at least one radial channelwherein at least one of the at least one radial channel is a buried channel comprising a first end for receiving the gas flow and a second distal end for expelling the gas flow, wherein only the second end of the buried radial channel is in fluid communication with the first of the at least two axial channels to limit an initial gas flow in the fuel grain. 2. The fuel grain of claim 1, further comprising a core support for at least partially supporting the solid fuel core relative to the solid fuel body. 3. The fuel grain of claim 1, wherein: the at least two axial channels provide for an axial flow of the gas; andthe at least one radial channel provides for a radial flow of the gas, wherein the axial flow and radial flow are defined with respect to a longitudinal axis of the fuel grain. 4. The fuel grain of claim 1, wherein the at least two axial channels are at least partially aligned in parallel with the entry gas flow and only one of the at least two axial channels is in axial alignment with the entry gas flow. 5. The fuel grain of claim 1, wherein the at least two axial channels are at least partially aligned in parallel with the exit gas flow and only one of the at least two axial channels is in axial alignment with the exit gas flow. 6. The fuel grain of claim 1, wherein the radial channel is connected to the two of the at least two axial channels. 7. The fuel grain of claim 1, wherein only one of the at least two axial channels is in axial alignment with the entry gas flow and the exit gas flow, the one axial channel comprising at least a first portion located at the entry and at least a second portion located at the exit. 8. A rocket motor for providing an exhaust, comprising: a fuel grain defining internal channels through which gas is to pass, the fuel grain comprising: a solid fuel body comprising a polymer;a solid fuel core comprising a polymer;an entry having an entry gas flow;an exit having an exit gas flow;at least two axial channels disposed between the entry and exit, only one of the at least two axial channels being in axial alignment with the entry gas flow and the exit gas flow, the solid fuel body and solid fuel core defining at least in part the at least two axial channels; anda radial channel disposed between the entry and exit, and extending between two of the at least two axial channels;wherein the radial channel is a buried channel comprising a first end for receiving a gas flow and a second distal end for expelling the gas flow, wherein only the second end of the buried radial channel is in fluid communication with the one of the at least two axial channels to limit an initial gas flow in the fuel grain,at least one igniter proximal the entry wherein the igniter ignites the fuel grain to create combustion gases that pass through the axial channel and the radial channel, and combustion gases exiting the fuel grain through the exit as the exhaust. 9. The rocket motor of claim 8, wherein: at least a first portion of the one axial channel is located at the entry and at least a second portion of the one axial channel is located at the exit. 10. The rocket motor of claim 8, further comprising intake means, wherein the intake means comprises: an intake manifold having an intake, the intake being an aperture in the intake manifold; andan intake bracket for securing the intake manifold to the fuel grain about the entry. 11. The rocket motor of claim 8, further comprises exhaust means, wherein the exhaust means comprises: an exhaust manifold having a nozzle, the nozzle being an aperture in the exhaust manifold; andan exhaust bracket for securing the exhaust manifold to the fuel grain about the exit. 12. The rocket motor of claim 8, further comprising exhaust means, wherein: the intake means comprises an intake bracket and an intake manifold having an intake, the intake being an aperture in the intake manifold; andthe exhaust means comprises an exhaust bracket and an exhaust manifold having a nozzle, the nozzle being an aperture in the exhaust manifold, the intake bracket and exhaust bracket serving to secure together the intake manifold, exhaust manifold, and fuel grain. 13. The rocket motor of claim 8, wherein: the intake means comprises an intake manifold; andthe igniter is disposed between the intake manifold and fuel grain. 14. The rocket motor of claim 8, wherein the at least two axial channels and the radial channel are configured to control an oxidizer to fuel ratio during burning of the fuel grain. 15. The rocket motor of claim 8, wherein the at least two axial channels and the radial channel are configured to maintain a predetermined burn profile of fuel during burning of the fuel grain. 16. The rocket motor of claim 8, wherein the at least two axial channels and the radial channel are configured to maintain a predetermined propulsion thrust profile of the exhaust during burning of the fuel grain. 17. A solid fuel motor, comprising: a three-dimensional fuel grain formed by a rapid prototyping technique and extending along a longitudinal axis;at least two axial channels defined by the fuel grain; andat least one radial channel defined by the fuel grain, wherein one of the at least one radial channel is disposed between two of the at least two axial channels of the fuel grain, wherein the at least one radial channel extends axially through only a portion of the longitudinal axis of the fuel grain, and wherein at least one of the at least one radial channel is a buried channel comprising a first end for receiving a gas flow and a second distal end for expelling the gas flow, wherein only the second end of the buried radial channel is in fluid communication with the first of the at least two axial channels to limit an initial gas flow in the fuel grain. 18. The motor of claim 17, further comprising: an entry having an entry gas flow; andan exit having an exit gas flow;wherein a first of the at least two axial channels is in fluid communication with the entry gas flow and the exit gas flow. 19. The motor of claim 17, wherein the fuel grain comprises a solid fuel. 20. The motor of claim 17, wherein the fuel grain includes a solid oxidizer. 21. The motor of claim 17, wherein the at least one buried channel is configured within the fuel grain to provide a predetermined burn profile of the fuel grain. 22. The motor of claim 21, wherein the at least one buried channel includes at least two buried channels that differ in at least one of shape or size. 23. The rocket motor of claim 8, wherein the radial channel extends radially between and is connected to the two of the at least two axial channels, the radial channel extending axially through only a portion of a longitudinal axis of the fuel grain. 24. The motor of claim 17, wherein the radial channel is connected to the two of the at least two axial channels.