Patent Number: 
Section: claims

1. A traveling wave reactor for a space exploration,wherein a nuclear reactor core of the traveling wave reactor is separated into several modules in a traveling wave direction;the reactor is sequentially provided with a starting source module and a plurality of new fuel modules at zero burnup;all the modules are coaxially assembled in the traveling wave direction by assembling parts, andeach module further comprises a heat pipe;the heat pipe in each module ispositioned at a front part of the module,extends out of the module at a rear part of the module, andsequentially passes through all the modules positioned rear of the module;the starting source module is used for emitting neutron flow to enable at least one of the new fuel modules to reach nuclear criticality, and to continue to form a critical traveling wave;after a period of time of burn-up, the nuclear reactor core of the traveling wave reactor is provided with the starting source module, a spent fuel module, a critical fuel module and the new fuel modules sequentially in the traveling wave direction; andthe spent fuel module is generated after a first new fuel module of the new fuel modules is subjected to a critical nuclear reaction,a certain amount of fissile nuclide is generated after the first new fuel module experiences an amount of nuclear conversion reactions, so as to enter a nuclear criticality state,and in the state, a number of neutrons released by the critical fuel module by nuclear fission reaction exceeds a number of neutrons absorbed by the critical fuel module, so as to promote nuclear conversion in the first new fuel module on one side of the first new fuel module. 2. The traveling wave reactor for a space exploration according to claim 1, wherein the reactor is configured to allow all the modules to be transported from land to the space, and then have the travelling wave reactor assembled in space. 3. The traveling wave reactor for a space exploration according to claim 1, wherein the starting source module comprises a starting source inner layer and a starting source outer layer in a radial direction, the starting source inner layer being provided with a neutron source material, and the starting source outer layer being a neutron shielding layer. 4. The traveling wave reactor for a space exploration according to claim 1, wherein the new fuel module comprises a new fuel inner layer and a new fuel outer layer in a radial direction, the new fuel inner layer being filled with a convertible material, and the new fuel outer layer being a neutron shielding layer. 5. The traveling wave reactor for a space exploration according to claim 1, wherein uniform sections of all the modules in the traveling wave reactor are in butt joint. 6. The traveling wave reactor for a space exploration according to claim 1, wherein the assembling parts comprises a fastening hasp and a fastening bolt which are arranged on edge sides of two end portions of each module, and each two adjacent modules are detachably assembled by the fastening hasp and the fastening bolt. 7. The traveling wave reactor for a space exploration according to claim 1, wherein each module in the traveling wave reactor further comprises a butt joint positioning member for coaxial butt joint during assembly. 8. The traveling wave reactor for a space exploration according to claim 7, wherein the butt joint positioning member comprises a bump and a groove which are coaxially arranged at two ends of each module, and during assembly, the bump and the groove on each two adjacent modules match each other. 9. The traveling wave reactor for a space exploration according to claim 1, wherein the reactor is configured to allow the traveling wave reactor to be used as a power source for the space exploration, and to allow a specific application mode to be followed:firstly, a set number of starting source module and new fuel modules of the traveling wave reactor are launched to a preset position of the space;then, the new fuel modules are sequentially and axially connected by the assembling parts to form a new fuel module group; andfinally, the starting source module is mounted at a head end of the new fuel module group by the assembling parts, andthe heat pipe extending out of an end portion is connected to a thermoelectric conversion device,then start the traveling wave reactor to burn. 10. The traveling wave reactor for a space exploration according to claim 9, whereinwhen the traveling wave reactor operates, spent fuel is continuously accumulated at a rear portion of the traveling wave direction to form the spent fuel modules, andon the premise of ensuring a criticality of the nuclear reactor core by nuclear physics calculation, the reactor is configured to allow the starting source module and part of the spent fuel modules to be separated from the traveling wave reactor and discarded.