Passive chemical injection system for controlling a nuclear reaction by delivering a neutron-absorbing chemical into a containment vessel

We claim: 1 . A nuclear power system, comprising: a reactor vessel defining a volume; a reactor core positioned within the volume and including one or more nuclear fuel assemblies configured to generate a nuclear fission reaction; a containment vessel having an inner surface sized to enclose the reactor vessel such that an open volume is defined between the containment vessel and the reactor vessel; and a passive chemical injection system positioned in the open volume and comprising a container sized to hold an amount of a neutron-absorbing chemical in solid form sufficient to at least maintain the nuclear fission reaction at a sub-critical state, wherein the container is configured to release the amount of the neutron-absorbing chemical in solid form directly into the open volume in response to a predetermined temperature and/or a predetermined pressure within the open volume such that the amount of the neutron-absorbing chemical in solid form goes into solution upon mixing with coolant in the open volume and such that the solution fluidly communicates with the inner surface of the containment vessel. 2 . The nuclear power system of claim 1 wherein the neutron-absorbing chemical comprises boron, silver, cadmium, indium, and/or hafnium. 3 . The nuclear power system of claim 1 wherein the neutron-absorbing chemical comprises boron-10. 4 . The nuclear power system of claim 1 wherein the neutron-absorbing chemical in solid form comprises a block of the neutron-absorbing chemical, multiple solid pieces of the neutron absorbing chemical, and/or the neutron-absorbing chemical in granular form. 5 . The nuclear power system of claim 1 wherein the container is configured to release the amount of the neutron-absorbing chemical in solid form directly into the open volume without the use of electrical power. 6 . The nuclear power system of claim 1 wherein the container comprises a latch configured to open in response to the predetermined temperature and/or the predetermined pressure within the open volume to release the amount of the neutron-absorbing chemical in solid form directly into the open volume. 7 . The nuclear power system of claim 1 wherein the container comprises a meltable material configured to melt in response to the predetermined temperature within the open volume to release the amount of the neutron-absorbing chemical in solid form directly into the open volume. 8 . The nuclear power system of claim 1 wherein the reactor vessel is configured to vent the coolant from the volume of the reactor vessel to the open volume during an emergency event. 9 . The nuclear power system of claim 8 wherein the vented coolant is configured to raise a temperature in the open volume to the predetermined temperature and/or raise a pressure in the open volume to the predetermined pressure. 10 . The nuclear power system of claim 1 , further comprising: a vent valve fluidly coupled between the volume of the reactor vessel and the open volume, wherein the vent valve is configured to vent the coolant from the volume of the reactor vessel into the open volume during an emergency event; and a recirculation valve coupled between the volume of the reactor vessel and the open volume, wherein the recirculation valve is configured to recirculate the solution from the open volume into the volume of the reactor vessel. 11 . The nuclear power system of claim 10 wherein the vent valve is configured to vent the coolant in vapor form, wherein the coolant in vapor form is configured to condense within the open volume, and wherein the amount of the neutron-absorbing chemical in solid form is configured to go into solution upon mixing with the condensed coolant in the open volume. 12 . The nuclear power system of claim 1 wherein the reactor vessel does not include any control rod assemblies therein. 13 . A method for controlling a nuclear fission reaction, comprising: operating a nuclear power system to generate a nuclear fission reaction, wherein the nuclear power system comprises: a reactor vessel defining a volume; a reactor core positioned within the volume and including one or more nuclear fuel assemblies configured to generate the nuclear fission reaction; a containment vessel having an inner surface sized to enclose the reactor vessel such that an open volume is defined between the containment vessel and the reactor vessel; and a passive chemical injection system positioned in the open volume and comprising a container sized to hold an amount of a neutron-absorbing chemical in solid form sufficient to at least maintain the nuclear fission reaction at a sub-critical state, wherein the container is configured to release the amount of the neutron-absorbing chemical in solid form directly into the open volume; releasing the amount of the neutron-absorbing chemical in solid form from the container directly into the open volume in response to a predetermined temperature and/or a predetermined pressure within the open volume such that the released amount of the neutron-absorbing chemical in solid form goes into solution upon mixing with coolant in the open volume and such that the solution fluidly communicates with the inner surface of the containment vessel; and circulating the solution from the open volume into the reactor vessel to maintain the fission reaction at least at the sub-critical state. 14 . The method of claim 13 wherein the releasing occurs during an emergency operation of the nuclear power system, wherein the method further comprises, during the emergency operation, venting the coolant from the volume of the reactor vessel to the open volume. 15 . The method of claim 13 wherein the releasing occurs during an emergency operation of the nuclear power system, wherein the method further comprises, during the emergency operation: venting the coolant from the volume of the reactor vessel to the open volume in vapor form; permitting the coolant in vapor form to condense within the open volume; and mixing the condensed coolant with the amount of the neutron-absorbing chemical to form the solution. 16 . The method of claim 13 wherein the releasing comprises releasing the amount of the neutron-absorbing chemical in solid form without the use of electrical power. 17 . The method of claim 13 wherein the container includes a latch, wherein the releasing comprises opening the latch of the container in response to the predetermined temperature and/or the predetermined pressure within the open volume. 18 . The method of claim 13 wherein the releasing comprises melting the container in response to the predetermined temperature within the open volume. 19 . The method of claim 13 wherein the reactor vessel does not include any control rod assemblies therein.