Detection apparatus, system, and method for detection of coolant flow rate and temperature in a nuclear environment

What is claimed is: 1. A detection apparatus structured to be situated within a flow of a fluid in a nuclear containment, the detection apparatus comprising: a support comprising a body, the body having a channel formed therein; a drogue situated in the support and being disposed within the channel; and a measurement apparatus comprising a load detection apparatus that is situated between the drogue and the support and that is structured to output a signal that is responsive to a load on the drogue due to the fluid within the channel, wherein the support further comprises a mount disposed within the channel, wherein the mount supports the drogue within the channel and the drogue is situated on the mount, wherein the support further includes a base that includes a first portion affixed to the body at a lower input end of the channel and a second portion affixed to the body at an upper outlet end of the channel, and wherein the mount is fixedly connected with the first portion and moveably connected with the second portion. 2. The detection apparatus of claim 1 wherein the second portion has a receptacle formed therein, the mount being telescopingly received in the receptacle. 3. The detection apparatus of claim 2 wherein a part of the mount extends between the first portion and the drogue, the load detection apparatus being situated on the part of the mount. 4. The detection apparatus of claim 1 wherein the drogue disposed within the channel is spaced from the body. 5. The detection apparatus of claim 4 wherein the support has a number of openings formed therein that are in flow communication with the channel and that are structured to permit the fluid to flow through the channel and past the drogue. 6. The detection apparatus of claim 4 wherein the support has a number of openings formed therein that are in flow communication with the channel and that are structured to permit the fluid to be stagnant in the channel while resisting the fluid from flowing through the channel and past the drogue. 7. A nuclear power system comprising: a nuclear reactor comprising a containment, a core situated within the containment, and a fluid situated within the containment and in communication with the core; a plurality of detection apparatuses situated within the containment and disposed in the fluid, each detection apparatus comprising a support, a drogue, and a measurement apparatus; the support comprising a body, the body having a channel formed therein; the drogue situated in the support and being disposed within the channel; wherein the support further comprises a mount disposed within the channel, wherein the mount supports the drogue within the channel and the drogue is situated on the mount, wherein the support further includes a base that includes a first portion affixed to the body at a lower input end of the channel and a second portion affixed to the body at an upper outlet end of the channel, and wherein the mount is fixedly connected with the first portion and moveably connected with the second portion; the measurement apparatus comprising a load detection apparatus that is situated between the drogue and the support and that is structured to output a signal that is responsive to a load on the drogue due to the fluid within the channel; and a processor apparatus comprising a processor and a storage, the load detection apparatus being in communication with the processor; the storage having stored therein a number of instructions which, when executed on the processor, cause the processor to perform operations comprising: receiving the signal from each of at least some of the plurality of detection apparatuses as a number of inputs to the processor; and determining at least one of a temperature of the fluid and a flow rate of the fluid based at least in part upon the number of inputs. 8. The nuclear power system of claim 7 wherein at least a subset of the plurality of detection apparatuses are oriented within the containment such that the channel is parallel with a flow direction of the fluid. 9. The nuclear power system of claim 7 wherein: a detection apparatus of the plurality of detection apparatuses has as its support a support which has a number of openings formed therein that are in flow communication with its channel and that are structured to permit the fluid to flow through its channel and past its drogue; and another detection apparatus of the plurality of detection apparatuses has as its support another support which has another number of openings formed therein that are in flow communication with its channel and that are structured to permit the fluid to be stagnant in its channel while resisting the fluid from flowing through its channel and past its drogue. 10. The nuclear power system of claim 9 wherein the operations further comprise: determining that the signal from the another detection apparatus is unvarying; and concluding, based at least in part upon the determining, that the fluid has a temperature that is unvarying. 11. The nuclear power system of claim 9 wherein the operations further comprise: receiving as the signal from the another detection apparatus a signal that is based at least in part upon a buoyancy of the drogue of the another detection apparatus in the fluid; and employing a temperature calibration data set that is that is based at least in part upon buoyancy to determine the temperature. 12. The nuclear power system of claim 10 wherein the operations further comprise: making a determination that the signal from the detection apparatus is varying; and further concluding, based at least in part upon the determination, that the fluid has a flow rate that is varying. 13. The nuclear power system of claim 9 wherein the operations further comprise: receiving as the signal from the detection apparatus a signal that is based at least in part upon a fluid drag between the drogue of the detection apparatus and the flowing of fluid through the channel and past the drogue of the detection apparatus; and employing a flow rate calibration data set that is that is based at least in part upon fluid drag to determine a flow rate of the fluid. 14. The nuclear power system of claim 9 wherein the operations further comprise: determining that the signal from the another detection apparatus is varying; and concluding, based at least in part upon the determining, that the fluid has a temperature that is varying. 15. The nuclear power system of claim 14 wherein the operations further comprise receiving as the signal from the detection apparatus a signal that is based at least in part upon: a fluid drag between the drogue of the detection apparatus and the flowing of fluid through the channel and past the drogue of the detection apparatus; and a buoyancy of the drogue of the detection apparatus in the fluid. 16. The nuclear power system of claim 7 wherein: a first subset of the plurality of detection apparatuses are positioned within the fluid upstream of the core; and a second subset of the plurality of detection apparatuses are positioned within the fluid downstream of the core. 17. The nuclear power system of claim 16 wherein: the nuclear reactor further comprises an outlet through which the fluid flows; and a third subset of the plurality of detection apparatuses are positioned within the fluid between the outlet and the first subset.