Patent Number: 039895890
Section: claims

1. A nuclear reactor comprising, a sealed, pressurized, reactor vessel having a plurality of openings in a wall thereof, each opening having a tubular member extending therethrough and sealingly attached thereto, the interior of said tubular member being exposed to the interior of said vessel,  a core fixedly positioned within said reactor vessel, said core including a multiplicity of elongated fuel elements in spaced, parallel relationship, and a multiplicity of control rod channels interspersed among said fuel elements,  means associated with said sealed reactor vessel and said core contained therein for converting heat produced by said core into useful energy,  a plurality of control rod assemblies situated for axial movement within said control rod channels, each of said control rod assemblies including at least one control rod containing neutron absorbing material and a drive shaft attached thereto, a plurality of said drive shafts extending through each of said tubular members attached to said reactor vessel,  sealed hollow hydraulic drive means sealingly attached to each of said tubular members for individually moving said drive shafts, and thereby said at least one control rod associated therewith, into and out of said core, said drive means having the interior thereof exposed to the interior of said tubular members, respectively, said drive means including a plurality of cylinders comprising cylindrical channels for respective movement therein of said control rod drive shafts, said plurality of cylinders being located within said drive means, and latching apparatus entirely within said drive means for positively and mechanically holding individual drive shafts of control rods in a withdrawn position, the ends of said drive shafts terminating within said drive means,  said latching apparatus including complementary engaging members one mounted on said drive shaft and movable to engage another engaging member mounted entirely within said drive means, said other engaging member including an elongated arm of magnetic material mounted pivotally against a resilient means and biased toward said one engaging member when the control rod associated with said one engaging member is in a withdrawn position, and actuating means for said latching apparatus positioned adjacent said latching apparatus and located on the exterior of said drive means,  said actuating means including electromagnetic pole means positioned in alignment with the elongated arm of said other engaging member to move said arm pivotally against said resilient means and away from said one engaging member when said electromagnetic pole means is energized. 2. The nuclear reactor of claim 1, wherein said hydraulic drive means includes decelerating apparatus for smoothly stopping the movement of said control rods during withdrawal from said core, said decelerating apparatus being operated hydraulically. 3. The nuclear reactor of claim 2, wherein said decelerating apparatus comprises a plurality of hydraulic shock absorbers, each of said shock absorbers being associated with an individual control rod drive shaft, each of said hydraulic shock absorbers being formed by an extension of said cylinder within said drive means, said cylinder extension being closed at one end and having its other end opened to the interior of said reactor vessel, said open end having a diameter smaller than the diameter of said cylinder but larger than the diameter of said control rod drive piston, said diameter being sized such that a flow restricting annulus is formed on passage of said piston therethrough, said flow restricting annulus permitting reactor coolant which is trapped within said cylinder extension during withdrawal of individual control rod assemblies to be released therefrom at a preselected rate. 4. The nuclear reactor of claim 2, wherein said decelerating apparatus includes a vent comprising a hole in the wall of said control rod cylinder, said hole flow connecting said cylinder to a pressure source having a lower pressure than the pressure within said reactor vessel, said hole being axially positioned with respect to the lower end of said control rod drive piston such that the hydraulic driving force associated with said drive means and comprising the differential pressure between the pressure within said reactor vessel and the pressure within said low pressure source, is progressively reduced as said control rod reaches a more withdrawn position. 5. The nuclear reactor of claim 1 wherein each of said one engaging members of said latch apparatus comprises a latch rod, each of said rods being located within an extension to each of said control rod cylinders within said drive means, each of said rods having a radial projection at one end for pivotal connection to said drive means and a hook-shaped configuration at the other end of said rods, said other engaging member including a hook-shaped end on each control rod drive piston, and said actuating means allowing individual disengagement of each of said control rod drive shafts from each of said latch rods, respectively. 6. A hydraulically operated control rod drive mechanism for individually moving a plurality of clusters of one or more control rods into and out of a core of a nuclear reactor, each of said clusters including at least one elongated rod containing neutron absorbing material, said drive mechanism having a sealed hollow housing and having mechanical means associated with each of said clusters for individually and positively retaining said clusters in a withdrawn position each of said mechanical means being located entirely within said sealed housing, said mechanical means for retaining each of said clusters in a withdrawn position includes a pair of engaging members, each of said pairs of engaging members for each cluster including a first elongated engaging member of magnetic material connected to said drive mechanism, said first engaging member having a ledge integral therewith, and a second engaging member connected to said cluster, said second engaging member having a ledge integral therewith, said ledges being complementarily positioned so as to become interlocked when said cluster is withdrawn from said core, actuating means for said engaging members located on the exterior of said housing, said actuating members being formed to individually disengage and engaging means, said actuating means including a plurality of electromagnetic pole means positioned respectively adjacent each of said first elongated engaging members to dislodge said ledge when said pole means are energized. 7. The drive mechanism of claim 6, wherein each of said first engaging members comprises a rod with said ledge being integral with one end thereof and being pivotally connected at its other end to said drive mechanism, and wherein each of said second engaging members respectively comprises a rod fixedly connected at one end to its respective cluster, said ledge being integral with the other end, said first and second engaging members thereby having oppositely positioned hook-shaped configurations which interlockingly engage when said cluster is withdrawn from said core. 8. The drive mechanism of claim 6, including means for mechanically maintaining said engaging members in an interlock position said means for mechanically maintaining said engaging members in an interlocked position comprises a resilient member disposed entirely within said drive mechanism and positioned so as to resiliently bias said first engaging member toward an interlocked position. 9. The drive mechanism of claim 6 including decelerating means for smoothly reducing the velocity of said cluster of one or more control rods during withdrawal from said core. 10. The drive mechanism of claim 9 wherein said decelerating means is hydraulically operated and comprises a piston connected to said control rod cluster, a cylinder formed by an elongated channel within said drive mechanism, said piston being mounted for axial movement within said cylinder, said cylinder having a flow restriction formed therein, said flow restriction comprising a localized reduced diameter of said cylinder, said reduced diameter being sized such that a flow restricting annulus is formed on passage of said piston therethrough, said flow restricting annulus allowing hydraulic fluid which is trapped within said elongated channel within said drive mechanism during withdrawal of said control rod to be released therefrom at a preselected rate. 11. The decelerating means of claim 10 including a vent comprising a hole in the wall of said cylinder, said hole flow connecting said cylinder to a pressure source having a pressure lower than the pressure being used to hydraulically withdraw said control rod from said core, said hole being axially positioned within said cylinder such that increased movement of said piston therepast, progressively reduces the hydraulic driving force associated with said drive mechanism, thereby progressively reducing the withdrawal velocity of said control rod.