Patent Number: 
Section: claims

1. A core catcher for a nuclear reactor plant that has a reactor vessel, the core catcher comprising:a main body configured to be placed beneath the reactor vessel and having a plurality of cooling fins extending radially on a bottom surface of the main body;a plurality of cooling channels formed between the cooling fins in the main body and extending radially;a distributor arranged in a central region of the bottom surface of the main body and connected to the plurality of cooling channels so that cooling water in the distributor is led inside of the cooling channels; anda side wall part channel formed at a peripheral region of the main body. 2. The core catcher according to claim 1, wherein the main body is divided into a plurality of regions from a center to a periphery thereof and a number of the cooling fins extending radially in an outer region is more than a number of cooling fins extending radially in an inner region so that the cooling fins constitute more cooling channels in the outer region than the inner region. 3. The core catcher according to claim 2, wherein a plurality of the cooling channels are connected to an intermediate header being formed at a border of the regions, the intermediate header is a mixing region where cooling water which passes through each cooling channel is intermingled and supplies the cooling water from the cooling channels formed in the inner region to the cooling channels formed in the outer region. 4. The core catcher according to claim 1, wherein a heat resistant material layer is formed on a top surface of the main body. 5. The core catcher according to claim 4, wherein the heat resistant material layer is formed with one of metal oxide and basalt concrete. 6. The core catcher according to claim 4, wherein a drain sump is formed on a top surface of the heat resistant material layer. 7. The core catcher according to claim 4, wherein a sacrifice concrete layer is formed in a top surface of the heat resistant material layer. 8. The core catcher according to claim 4, wherein the heat resistant material layer is formed so that layering thickness of an outer part in a radial direction of the main body is larger than that of an inner part. 9. The core catcher according to claim 4, wherein the heat resistant material layer includes a first heat resistant material layer and a second heat resistant material layer, the second heat resistant material layer having smaller thermal conductivity than the first heat resistant material layer and being located further outward in a radial direction of the main body than the first heat resistant material layer. 10. The core catcher according to claim 1, wherein at least a part of the coolant injection piping is embedded in a pedestal side wall defining a space in which the main body is located. 11. The core catcher according to claim 1, wherein the main body comprises a combination of a plurality of body sub pieces, a plurality of cooling fins formed radially on a bottom surface of each body sub piece and cooling channels formed radially between the cooling fins. 12. The core catcher according to claim 11, wherein a side facing to a pedestal side wall of the body sub piece located at a periphery extends along the pedestal side wall. 13. The core catcher according to claim 1, further comprising a recirculation piping being configured to return the cooling water emitted from the cooling channel over the main body to the cooling channel. 14. The core catcher according to claim 13, wherein the recirculation piping includes first recirculation piping and second recirculation piping, a location where the second recirculation piping returns the cooling water to the cooling channel is downstream from a location where the first recirculation piping returns the cooling water to the cooling channel. 15. The core catcher according to claim 13, further comprising a dam located between an entering opening of the recirculation piping and an outlet opening of the cooling channel. 16. The core catcher according to claim 15, wherein the dam inclines toward the outlet opening of the cooling channel. 17. The core catcher according to claim 1, wherein at least a part of an inner upside surface of the cooling channel inclines against a horizontal line along a direction in which the cooling water flows. 18. The core catcher according to claim 17, wherein an inclination of the inner upside surface to the horizontal line is larger at downstream of the direction through which the cooling water flows. 19. The core catcher according to claim 1, wherein a plurality of dimples are formed on an inner wall of the cooling channel. 20. The core catcher according to claim 1, further comprising:detection means for detecting an indication of dropping of a molten core; andcooling water supply means for supplying the cooling water to the cooling channel through the cooling water injecting piping if the detection means detects the indication. 21. The core catcher according to claim 20, wherein the cooling water supply means includes:a cistern located above an outlet of the cooling channel and being configured to store the cooling water;an injection valve inserted in the cooling water injecting piping; andan injection valve controller connected to the detection means and being configured to open the injection valve if the detection means detects the indication. 22. The core catcher according to claim 21, whereinthe detection means detects temperature of atmosphere of a lower part of the reactor vessel, andthe injection valve controller opens the injection valve if the temperature of atmosphere of the lower part of the reactor vessel exceeds a predetermined temperature. 23. The core catcher according to claim 21, whereinthe detection means detects temperature of a lower head of the reactor vessel, andthe injection valve controller opens the injection valve if the temperature of the lower head of the reactor vessel exceeds a predetermined temperature. 24. The core catcher according to claim 21, whereinthe detection means detects a water level inside the reactor vessel, andthe injection valve controller opens the injection valve if a certain period elapses while the water level inside the reactor vessel remains less than a specific water level. 25. The core catcher according to claim 20, wherein the cooling water supply means includes:a cistern configured to store the cooling water;a pump configured to send out the cooling water to the water supply chamber from the cistern; anda pump controller connected to the detection means and configured to start the pump if the detection means detects the indication. 26. The core catcher according to claim 1, wherein the cooling channel is formed so that height of a flow area at an outer position of a radial direction is smaller than an inner position. 27. A core catcher for catching core debris generated when a reactor core in a reactor vessel melts and penetrates the reactor vessel, the core catcher comprising:a cooling channel having a plurality of fins attached to a bottom thereof and defining a debris holding region and a plurality of cooling water flow paths, the debris holding region being surrounded by a bottom surface inclined with respect to a horizontal plane and a wall spreading vertically at a periphery of the bottom surface and being opened upward, the cooling water flow paths extending parallel to each other with a fixed horizontal width along the bottom surface of the debris holding region as a top surface of the cooling water flow rises; andheat resistant material attached to a surface of the cooling channel facing to the debris holding region,wherein the cooling water flow paths are formed between the fins. 28. The core catcher according to claim 27, wherein lengths of the cooling water flow paths are equal to each other.