CN1588559A - Shut-down method and shut-down system for low temperature heat supply or research pile super design reference fault - Google Patents
Shut-down method and shut-down system for low temperature heat supply or research pile super design reference fault Download PDFInfo
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- CN1588559A CN1588559A CNA2004100691858A CN200410069185A CN1588559A CN 1588559 A CN1588559 A CN 1588559A CN A2004100691858 A CNA2004100691858 A CN A2004100691858A CN 200410069185 A CN200410069185 A CN 200410069185A CN 1588559 A CN1588559 A CN 1588559A
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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Abstract
The invention is a low-temperature heater or a heater stopping method and system for researching over-design reference-casuded accident, and its characteristic: it arranges at leas two cavity grid cells near the center in the heater core, where the cavity grid cell is made of a material with a small neutron absorption section, and as the heater works normally, it charges nitrogen gas into the cavity grid cells and as the over-design reference-caused accident happens, injects boric or deionized water into the cavity grid cells, so as to introduce negative reactivity and realize heater stop. As compared with the heater stopping method that injects boric water, it remarkably avoids large amount of boric water from mixing with slowing-down water, thus unnecessary to arrange a complex boron eliminator so as to cost large amount of processing time. Besides, in an accident state, the time of injecting boric or deionized water into the cavity grid cells is shorter than the born-injection response time of a nuclear power station, even equal to the falling time of a control rod.
Description
Technical field
The invention belongs to nuclear reactor control field, be specifically related to a kind of shut-down method and reactor shut-off system of nuclear reactor accident.
Background technology
China pays much attention to the safety of nuclear facilities; new design and the low temperature heating reactor of building or research reactor all must be studied the accident of external power circuit breaking protective system tripping and the tripping of control rod withdrawal accident protection system; these two kinds all is the super design reference accident; though probability is very low, it threatens very big to nuclear reactor safety.Especially low temperature heating reactor and research reactor do not allow outside the factory emergent.For eliminating above two kinds of super design reference accidents, the shut-down method and the reactor shut-off system of necessary research and design super design reference accident.The method that adopts nuclear power plant accident to add boron water adds B solution in moderator be to solve one of above-mentioned super design reference accident way.Because nuclear power station has the boron disposal system, and just containing boron in the moderator when normally moving, is very easily with adding boron water realization shutdown therefore.And low temperature heating reactor or research reactor do not remove the boron system, so adopt the method that adds boron water in cooling (slowing down) agent under the accident, certainly will generate a large amount of boron waters, and this has not only increased the complicacy of going boron to handle, and will expend the quite long processing time.Especially utilize cooling (casualization) agent of the low temperature heating reactor that Nuclear Power Station's Exhausted Fuels builds up to add that the water capacity in pressure accumulation pond is very big, be greater than 1000 tons of water, the boron in the more difficult removal water.
Summary of the invention
The purpose of this invention is to provide and a kind ofly can avoid a large amount of boron waters to mix, need not to be provided with except that boron complicated technology system and expend in a large number except that the low temperature heating reactor in boron processing time or the shut-down method and the reactor shut-off systems of research reactor super design reference accident with a large amount of cooling (slowing down) water.
The present invention is achieved in that a kind of low temperature heating reactor or research reactor super design reference breakdown method, in reactor core, arrange at least two cavity lattice cells of making by the little material in neutron-absorption cross-section near centre, during normal reactor operation, inflated with nitrogen in this cavity lattice cell, when the super design reference accident takes place, inject boron water or deionized water to the cavity lattice cell, introduce negative reactivity, realize shutdown.
A kind of low temperature heating reactor or research reactor super design reference breakdown system, it is included in the reactor core near centre and is provided with the cavity lattice cell of at least two length of being made by the little material in neutron-absorption cross-section greater than core height and closed at both ends, one end of a pipeline inserts the bottom of cavity lattice cell, its other end passes reactor vessel, link to each other with fluid reservoir through injecting solenoid valve, fluid reservoir top also is connected with gas admittance valve and vent valve, one of another root pipeline terminates to the top of cavity lattice cell, its other end passes reactor vessel, link to each other with nitrogen cylinder with steam supply valve through connecting distributing valve, steam supply valve also links to each other with gas admittance valve.
A kind of low temperature heating reactor or research reactor super design reference breakdown system, in reactor core, be provided with the cavity lattice cell of at least two length of making by the little material in neutron-absorption cross-section greater than core height and upper end closed lower end opening near centre, one end of a pipeline inserts the cavity lattice cell until its top from lower ending opening, its other end passes reactor vessel and links to each other with gas-holder, also links to each other with nitrogen cylinder, vacuum tank respectively through gas filling valve, exhaust solenoid valve simultaneously.
The present invention arranges an amount of cavity lattice cell at the reactor core of low temperature heating reactor or research reactor, inflated with nitrogen in the chamber when normal operation, outside under the power cut-off accident, the solenoid valve outage is also opened automatically, boron water or deionized water are injected in the cavity lattice cell by gravity or pressurization, introduce bigger negative reactivity, can realize hot shutdown, even can reach cold shut.If the serial connection expression " is piled the power height " and the shutdown contact of " heap outlet temperature height " in the power of electromagnetic valve loop, can also eliminate the serious consequence of control rod withdrawal accident protection system tripping.The present invention provides a kind of new independently shut-down method and reactor shut-off system, to guarantee the safety of low temperature heating reactor or research reactor.Annotate the shut-down method of boron water with nuclear power station and compare, its remarkable result is to avoid a large amount of boron waters to mix with a large amount of cooling (slowing down) water, like this, need not to be provided with except that the complicated technology system of boron with expend a large amount of processing times.And injecting boron water or deionized water under accident conditions in the cavity lattice cell, to annotate the boron response time than nuclear power station short, even can be suitable with control rod rod response time that falls.
Description of drawings
Fig. 1 is a synoptic diagram of reactor shut-off system provided by the present invention;
Fig. 2 is another synoptic diagram of reactor shut-off system provided by the present invention.
Among the figure, 1. inject solenoid valve 2. distributing valves 3. steam supply valves 4. and add air valve 5. vent valves 6. fluid reservoirs 7. nitrogen cylinders 8. cavity lattice cells 9. reactor cores 10. reactor vessels 11. exhaust solenoid valves 12. gas filling valves 13. gas-holder 14. vacuum tanks 15. nitrogen cylinders 21,22,23. pipelines.
Embodiment
A kind of low temperature heating reactor or research reactor super design reference breakdown method, be in reactor core, to arrange at least two cavity lattice cells of making by the little material in neutron-absorption cross-section near centre, during normal reactor operation, inflated with nitrogen in this cavity lattice cell, when the super design reference accident takes place, inject boron water or deionized water to the cavity lattice cell, introduce negative reactivity, realize shutdown.
Said cavity lattice cell is the little lattice cell shape parts of being made by aluminium or zirconia material in neutron-absorption cross-section, and be arranged near the higher position of reactor core neutron flux, in the cavity lattice cell, inject boron water or deionized water, under accident, can absorb a large amount of neutrons or change Water-Uranium Ratio (H/U
235), make moderation of neutrons, introduce negative reactivity, realize shutdown.Wherein, the size of injecting deionized water introducing negative reactivity is also arranged relevant with reactor core concrete structure and cavity lattice cell.The design of Nuclear Power Station's Exhausted Fuels low-temperature heat supply core shows:
For the reactor core of 24 groups and 9 " cavity lattice cell " compositions of control rod in 88 box irradiated fuel assemblies, the insertion fuel assembly, introduce negative reactivity behind hot full power " cavity lattice cell " water-filling and be approximately 2%;
For the reactor core of 13 " cavity lattice cell " compositions of 32 groups of boxes of control rod in 108 box irradiated fuel assemblies, the insertion fuel assembly, introduce negative reactivity behind hot full power " cavity lattice cell " water-filling:
13 " cavity lattice cell " water-filling afterreactions descend 3.55%
8 " cavity lattice cell " water-filling afterreactions descend 2.13%
5 " cavity lattice cell " water-filling afterreactions descend 1.11%
4 " cavity lattice cell " water-filling afterreactions descend 0.846%;
For the high flux heap (research reactor) of thimble tube fuel element, district's batch turning in 80 box-packed years four, the balance batch turning was loaded down, and reactor core is arranged four boxes " cavity lattice cell ".Introduce negative reactivity behind " cavity lattice cell " water-filling: be about 1% for the high-enriched uranium fuel element; Be about 0.5% for the slightly enriched uranium fuel element.
Details are as follows for reactor shut-off system provided by the present invention:
As shown in Figure 1, the Nuclear Power Station's Exhausted Fuels low temperature heating reactor that is 200MW with a thermal power is an example.Cavity lattice cell 8 inserts in the reactor core 9, be arranged near in reactor core 9 lattice cells, cavity lattice cell 8 is lattice cell linear elements of being made by aluminium or zirconium, cavity lattice cell 8 is longer than reactor core 9, upper and lower side all stretches out 10~20cm, and sealing, one end of pipeline 21 is inserted into the bottom of cavity lattice cell 8, its other end passes heap container 10, link to each other with fluid reservoir 6 through injecting solenoid valve 1, fluid reservoir 6 tops also are connected with gas admittance valve 4 and vent valve 5, and one of pipeline 22 terminates to the top of cavity lattice cell 8, its other end passes heap container 10, links to each other with nitrogen cylinder 7 with steam supply valve 3 through distributing valve 2.Close gas admittance valve 4 before opening heap, open vent valve 5, distributing valve 2, steam supply valve 3 and inject solenoid valve 1, boron water or deionized water in the cavity lattice cell 8 are pressed onto in the fluid reservoir 6, when vent valve 5 a large amount of deflations, close steam supply valve 3 and inject solenoid valve 1, close vent valve 5 again, open gas admittance valve 4.When accident or check, inject solenoid valve 1 outage and automatic the unlatching, boron water in the fluid reservoir 6 or deionized water inject cavity lattice cell 8 by deadweight or pressurization, and the introducing negative reactivity is realized shutdown.This programme is applicable to the reactor shut-off system of injecting boron water or deionized water mode.It is short that this injection mode is annotated the boron response time than nuclear power station, and its response time can be suitable with control rod corresponding time of falling.
As shown in Figure 2, be example also with 200MW Nuclear Power Station's Exhausted Fuels low temperature heating reactor.The cavity lattice cell 8 of right quantity is inserted in the reactor core 9, and cavity lattice cell 8 is longer than reactor core 9, and 10~20cm and sealing are stretched out in the upper end, and 50~100cm and opening are stretched out in the lower end.One end of a pipeline 23 inserts cavity lattice cell 8 on reactor core 9 more than the plane from opening part, and the other end passes heap container 10 and links to each other with gas-holder 13, and the while, it also linked to each other with vacuum tank 14 with nitrogen cylinder 15 with solenoid valve 11 through gas filling valve 12 respectively.Before opening heap,, to 8 inflations of cavity lattice cell water level in the cavity lattice cell 8 is pressed onto between reactor core 9 lower planes and cavity lattice cell 8 opening parts by gas filling valve 12, and utilizes gas-holder 13 to slow down water-level fluctuation in the cavity lattice cell 8.When accident or test, solenoid valve 11 outages are also opened, and the gas in the cavity lattice cell 8 is rushed down in the vacuum tank 14, and cavity lattice cell 8 charges into cooling (casualization) agent, introduces negative reactivity, realizes shutdown.This programme is only applicable to the reactor shut-off system of water flooding regime.
Above-mentioned two kinds of reactor shut-off systems are equally applicable to research reactor.
Claims (3)
1. low temperature heating reactor or research reactor super design reference breakdown method, it is characterized in that: in reactor core, arrange at least two cavity lattice cells of making by the little material in neutron-absorption cross-section near centre, during normal reactor operation, inflated with nitrogen in this cavity lattice cell, when the super design reference accident takes place, in the cavity lattice cell, inject boron water or deionized water, introduce negative reactivity, realize shutdown.
2. low temperature heating reactor or research reactor super design reference breakdown system, it is characterized in that: in reactor core, be provided with the cavity lattice cell (8) of at least two length of making by the little material in neutron-absorption cross-section greater than reactor core (9) height and closed at both ends near centre, one end of a pipeline (21) inserts the bottom of cavity lattice cell (8), its other end passes reactor vessel, link to each other with fluid reservoir (6) through injecting solenoid valve (1), fluid reservoir (6) top also is connected with gas admittance valve (4) and vent valve (5), one of another root pipeline (22) terminates to the top of cavity lattice cell (8), its other end passes reactor vessel, link to each other with nitrogen cylinder (7) with steam supply valve (3) through connecting distributing valve (2), steam supply valve (3) also links to each other with gas admittance valve (4).
3. low temperature heating reactor or research reactor super design reference breakdown system, it is characterized in that: in reactor core, be provided with the cavity lattice cell (8) of at least two length of making by the little material in neutron-absorption cross-section greater than reactor core (9) height and upper end closed lower end opening near centre, one end of pipeline (23) inserts cavity lattice cell (8) until its top from lower ending opening, the other end passes reactor vessel and links to each other with gas-holder (13), also links to each other with nitrogen cylinder (15), vacuum tank (14) respectively through gas filling valve (12), exhaust solenoid valve (11) simultaneously.
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103137223A (en) * | 2011-11-30 | 2013-06-05 | 阿海珐核能公司 | Assembly and method for injecting water containing a neutron-absorbing element to cool a nuclear reactor core in a crisis situation |
CN104616707A (en) * | 2014-12-30 | 2015-05-13 | 中国原子能科学研究院 | Boron injection system for second reactor shutdown system of research reactor |
CN105788689A (en) * | 2016-01-21 | 2016-07-20 | 新核(北京)能源科技有限公司 | Low temperature well-type nuclear heating reactor heat supply system |
CN109215813A (en) * | 2018-09-13 | 2019-01-15 | 中国核动力研究设计院 | Pressurized-water reactor thimble tube complementary shutdown system and method |
-
2004
- 2004-07-07 CN CNB2004100691858A patent/CN1271640C/en active Active
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103137223A (en) * | 2011-11-30 | 2013-06-05 | 阿海珐核能公司 | Assembly and method for injecting water containing a neutron-absorbing element to cool a nuclear reactor core in a crisis situation |
CN104616707A (en) * | 2014-12-30 | 2015-05-13 | 中国原子能科学研究院 | Boron injection system for second reactor shutdown system of research reactor |
CN105788689A (en) * | 2016-01-21 | 2016-07-20 | 新核(北京)能源科技有限公司 | Low temperature well-type nuclear heating reactor heat supply system |
CN109215813A (en) * | 2018-09-13 | 2019-01-15 | 中国核动力研究设计院 | Pressurized-water reactor thimble tube complementary shutdown system and method |
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