Modular nuclear reactors including fuel elements and heat pipes extending through grid plates, and methods of forming the modular nuclear reactors

What is claimed is: 1. A modular nuclear reactor, comprising: a plurality of sections, each section comprising: a tank comprising a front plate, a back plate, side plates, a top plate, and a bottom plate; a plurality of grid plates within the tank, each grid plate of the plurality of grid plates comprising a plurality of apertures and vertically separated from an adjacent grid plate; a plurality of fuel elements extending through each grid plate of the plurality of grid plates; and a plurality of heat pipes extending through each grid plate of the plurality of grid plates, the top plate, and an upper reflector; and a side reflector material surrounding the plurality of sections. 2. The modular nuclear reactor of claim 1 , wherein the tank is filled with a heat transfer fluid, the heat transfer fluid in contact with the plurality of fuel elements, the plurality of heat pipes, and the plurality of grid plates. 3. The modular nuclear reactor of claim 2 , wherein the heat transfer fluid comprises sodium. 4. The modular nuclear reactor of claim 1 , wherein each heat pipe of the plurality of heat pipes comprises potassium, sodium, or a combination thereof. 5. The modular nuclear reactor of claim 1 , wherein the tank is an inner tank, the inner tank surrounded by an outer tank, the outer tank comprising the upper reflector and a lower reflector. 6. The modular nuclear reactor of claim 1 , wherein each grid plate of the plurality of grid plates comprises stainless steel. 7. The modular nuclear reactor of claim 6 , wherein the each heat pipe of the plurality of heat pipes comprises 316 stainless steel. 8. The modular nuclear reactor of claim 1 , wherein the tank comprises stainless steel. 9. The modular nuclear reactor of claim 1 , wherein each heat pipe of the plurality of heat pipes is welded to the top plate and the upper reflector. 10. The modular nuclear reactor of claim 1 , wherein each section comprises about between 100 heat pipes and 300 heat pipes. 11. The modular nuclear reactor of claim 1 , wherein the plurality of sections comprises six sections, the six sections arranged in a circular pattern, a central opening shaped and configured to receive a control rod. 12. A method of forming a modular nuclear reactor, the method comprising: assembling a plurality of prefabricated fuel elements on a bottom plate of an inner tank and through apertures in a plurality of grid plates, the plurality of grid plates vertically separated from an adjacent grid plate; assembling a plurality of prefabricated heat pipes on the bottom plate of the inner tank, through the apertures in the plurality of grid plates, and through an upper reflector; forming a seal between the one or more prefabricated heat pipes and a top plate of the inner tank; coupling each of the top plate and the bottom plate to side plates, a front plate, and a back plate, the grid plates located within the inner tank; forming an outer tank substantially surrounding the inner tank; filling the inner tank with a heat transfer fluid; and placing a side reflector material proximate the outer tank. 13. The method of claim 12 , further comprising selecting the heat transfer fluid to comprise sodium. 14. The method of claim 12 , further comprising selecting the bottom plate and the plurality of grid plates to comprise 316 stainless steel. 15. The method of claim 12 , further comprising selecting the one or more prefabricated heat pipes to comprise sodium, potassium, or a combination thereof. 16. The method of claim 12 , wherein forming an outer tank substantially surrounding the inner tank comprises welding the plurality of prefabricated heat pipes to the upper reflector.