CN107369479A - The passive reactor shut-off system and nuclear reactor based on pressure difference for integrated heap - Google Patents
The passive reactor shut-off system and nuclear reactor based on pressure difference for integrated heap Download PDFInfo
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- CN107369479A CN107369479A CN201710642371.3A CN201710642371A CN107369479A CN 107369479 A CN107369479 A CN 107369479A CN 201710642371 A CN201710642371 A CN 201710642371A CN 107369479 A CN107369479 A CN 107369479A
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- G—PHYSICS
- G21—NUCLEAR PHYSICS; NUCLEAR ENGINEERING
- G21C—NUCLEAR REACTORS
- G21C9/00—Emergency protection arrangements structurally associated with the reactor, e.g. safety valves provided with pressure equalisation devices
- G21C9/004—Pressure suppression
- G21C9/012—Pressure suppression by thermal accumulation or by steam condensation, e.g. ice condensers
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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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E30/00—Energy generation of nuclear origin
- Y02E30/30—Nuclear fission reactors
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- General Engineering & Computer Science (AREA)
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Abstract
The invention provides the passive reactor shut-off system and nuclear reactor based on pressure difference for integrated heap, including cylinder block, piston rod is provided with cylinder block, the upper end of piston rod is provided with piston, the diameter of piston is more than the diameter of piston rod, the end set of piston rod above piston has valve cover plate, cylinder block is fixed on valve seat, cylinder connected entrance is offered in the side wall of cylinder block below piston, cylinder connected entrance connects cylinder interior with boron water cavity, valve cover plate is in a side loop, the lower surface of valve cover plate abuts with the upper surface of cylinder block when the pressure of side loop is more than the pressure in boron water cavity, the lower surface of valve cover plate separates with the upper surface of cylinder block when the pressure of side loop is less than the pressure in boron water cavity.The invention is simple in construction, and cost is cheap, without artificial operation, it becomes possible to controls the operation and stopping of reactor, such a construction increases the security of equipment, while also reduces the expense of maintenance.
Description
Technical field
The invention belongs to the control device technical field of nuclear reactor, more particularly, to a kind of for integrated heap
Passive reactor shut-off system and nuclear reactor based on pressure difference.
Background technology
The reactor shut-off system of reactor in the prior art, be mostly by control rod enter out carry out reactor shutdown with
Operation, there is complex operation, the problems such as security is low, in the running of reactor, by adjusting primary side cooling water
Boron concentration control the negative temperature coefficient of reactor core and bulkfactor, and then control the operation and shutdown of reactor, this technology
Security is improved, reduces the expense of maintenance, facilitates the feasibility of maintenance, there is very high economy.
The content of the invention
In view of this, the invention is directed to a kind of passive shutdown system based on pressure difference for integrated heap
System, to improve the runnability of reactor.
To reach above-mentioned purpose, what the technical scheme of the invention was realized in:
For the passive reactor shut-off system based on pressure difference of integrated heap, including cylinder block, piston is provided with cylinder block
Bar, the upper end of piston rod are provided with piston, and the diameter of piston is more than the diameter of piston rod, and the end of the piston rod above piston is set
Valve cover plate is equipped with, cylinder block is fixed on valve seat, and cylinder connected entrance, cylinder are offered in the side wall of the cylinder block below piston
Connected entrance connects cylinder interior with boron water cavity, and valve cover plate is used for the pressure for experiencing a side loop in a side loop
Power, the lower surface of valve cover plate abuts with the upper surface of cylinder block when the pressure of a side loop is more than the pressure in boron water cavity,
The lower surface of valve cover plate separates with the upper surface of cylinder block when the pressure of side loop is less than the pressure in boron water cavity.
Further, the gap passed through for boric acid water is left between the piston body and the madial wall of cylinder block.
Further, the lateral wall of the piston body is provided with screw thread, is left between piston body and the madial wall of cylinder block
The gap passed through for boric acid water.
Further, the gap is 5mm.
Further, the edge of the valve cover plate is bent outwardly upwards, and the longitudinal section of valve cover plate is inverted herringbone
Shape structure.
Further, the lower end of the piston rod is provided with plain block.
Further, it is described to match somebody with somebody plain block inner hollow, with inside plain block filled with water.
Further, the piston and it is full of boric acid water with the space between plain block.
Further, the cylinder connected entrance is arranged on between plain block and piston.
The invention is mentioned that a kind of nuclear reactor, including the above-mentioned non-energy based on pressure difference for integrated heap
Dynamic reactor shut-off system.
Relative to prior art, a kind of passive shutdown based on pressure difference for integrated heap described in the invention
System and nuclear reactor have the advantage that:
(1) the invention is simple in construction, and cost is cheap, without artificial operation, it becomes possible to controls the operation of reactor
With stopping, such a construction increases the security of equipment, while the expense of maintenance is also reduced;
(2) piston outer wall of the invention is arranged to helicitic texture, and the design of helicitic texture has high flow resistance, together
When piston outer wall and cylinder inner wall between gap setting and piston body helicitic texture can effectively reduce impurity flow into gas
The inside of cylinder, improve the safety and stability of equipment.
Brief description of the drawings
The accompanying drawing for forming the part of the invention is used for providing further understanding the invention, present invention wound
The schematic description and description made is used to explain the invention, does not form the improper restriction to the invention.
In accompanying drawing:
Fig. 1 is the overall structure diagram of the invention integration heap;
Fig. 2 is the structural representation of the main circulation pump described in the invention embodiment;
Fig. 3 is the structural representation of the steam generator described in the invention embodiment;
Fig. 4 is the front view of the reactor core described in the invention embodiment;
Fig. 5 is the longitudinal sectional view of the reactor core described in the invention embodiment;
Fig. 6 is the top view of the reactor core described in the invention embodiment;
Fig. 7 is the structural representation of the passive reactor shut-off system described in the invention embodiment;
Fig. 8 is the top view of the integrated heap described in the invention embodiment.
Description of reference numerals:
1st, pressure vessel cylinder;101st, upper cover;102nd, low head;103rd, feed-water intake;104th, steam (vapor) outlet;2nd, major cycle
Pump;201st, motor;202nd, main shaft;203rd, impeller;204th, pump case;2041st, floss hole;2042nd, bell-mouth structure of air;205th, it is outer
Shell upper flange;206th, pump inner casing;207th, inner casing upper flange;208th, gland seal device;209th, internal lower house;210th, water middle (center) bearing;
211st, electronic board;212nd, it is indirectly connected with device;3rd, steam generator;301st, steam generator inner cylinder;302nd, outside steam generator
Cylinder;303rd, steam generator intermediate cylinder;304th, to water manifold;3041st, inlet opening;3042nd, apopore;305th, feed pipe;306、
Helix tube;307th, porous support plate;308th, ring flat-plate;309th, tube sheet;310th, cover plate;4th, reactor core;401st, fuel assembly;402nd, fuel
Case;403rd, fuel slab;404th, annular slab;4041st, coolant flow passages;405th, circular lower cover;406th, poisonous substance circulation device;407th, it is malicious
Thing expanded absorber;408th, retainer ring;4081st, fixing hole;4082nd, upper fixed block;4083rd, lower fixed block;5th, poisonous substance tank;501、
Poisonous substance tank inner casing;502nd, poisonous substance tank shell;503rd, poisonous substance tank epimere;504th, poisonous substance tank changeover portion;505th, poisonous substance tank hypomere;6th, it is non-
Active reactor shut-off system;601st, cylinder block;602nd, piston rod;603rd, piston;6031st, screw thread;604th, valve cover plate;605th, valve seat;
606th, with plain block;607th, cylinder connected entrance;608th, gap;A, the first ring cavity;B, the second ring cavity;C, cooling water circulation cavity;d、
Lower boron water cavity;E, upper boron water cavity;F, upper chamber;G, decline passway.
Embodiment
It should be noted that in the case where not conflicting, the feature in embodiment and embodiment in the invention can
To be mutually combined.
In the description of the invention, it is to be understood that term " " center ", " longitudinal direction ", " transverse direction ", " on ", " under ",
The orientation or position relationship of the instruction such as "front", "rear", "left", "right", " vertical ", " level ", " top ", " bottom ", " interior ", " outer " are
Based on orientation shown in the drawings or position relationship, it is for only for ease of description the invention and simplifies description, rather than instruction
Or imply that signified device or element must have specific orientation, with specific azimuth configuration and operation, therefore be not understood that
For the limitation to the invention.In addition, term " first ", " second " etc. are only used for describing purpose, and it is not intended that instruction
Or imply relative importance or the implicit quantity for indicating indicated technical characteristic.Thus, " first ", " second " etc. are defined
Feature can express or implicitly include one or more this feature.In the description of the invention, unless separately
It is described, " multiple " are meant that two or more.
, it is necessary to which explanation, unless otherwise clearly defined and limited, term " are pacified in the description of the invention
Dress ", " connected ", " connection " should be interpreted broadly, for example, it may be fixedly connected or be detachably connected, or integratedly
Connection;Can be mechanical connection or electrical connection;Can be joined directly together, can also be indirectly connected by intermediary,
It can be the connection of two element internals.For the ordinary skill in the art, on being understood by concrete condition
State concrete meaning of the term in the invention.
Describe the invention in detail below with reference to the accompanying drawings and in conjunction with the embodiments.
As shown in Fig. 1 to Fig. 8 a kind of integrated heap for heating type, including pressure vessel cylinder 1, in pressure vessel cylinder 1 under
Portion is provided with the poisonous substance tank 5 with the 1 concentric setting of pressure vessel cylinder, and poisonous substance tank 5 includes poisonous substance tank inner casing 501 and poisonous substance tank shell
502, the upper boron water cavity e for accommodating boron water, upper boron water cavity e tops are formed between poisonous substance tank inner casing 501 and poisonous substance tank shell 502
Poisonous substance tank 5 on be provided with passive reactor shut-off system 6 for controlling reactor.Heap is provided among the interior bottom portion of poisonous substance tank 5
Core 4, poisonous substance tank 5 is up-narrow and down-wide, and steam generator 3 is provided with outside the narrow portion of poisonous substance tank 5, and steam generator 3 is direct current spiral
Tubular type.Steam generator 3 is used for the heat exchange of secondary side circuit, and pressure vessel cylinder 1 is internally provided with for driving primary side to return
The drive device that road circulates.
As shown in figure 1, be provided with upper chamber f in the pressure vessel cylinder 1 of the top of steam generator 3, upper chamber f is by poisonous substance tank
5 inside connect with steam generator 3, form annular decline passway g between poisonous substance tank 5 and pressure vessel cylinder 1, under reactor core 4
The circumference at end is provided with the coolant flow passages 4041 of radial direction, and coolant flow passages 4041 connect decline passway g with reactor core 4.Pressure
The lower section of reactor core 4 is provided with lower boron water cavity d in thimble body 1, and upper boron water cavity e connects with lower boron water cavity d, and the lower end of reactor core 4 is set
Toxic circulation device 406, poisonous substance circulation device 406 connect reactor core 4 with lower boron water cavity d.
As shown in figure 3, steam generator 3 includes steam generator inner cylinder 301, steam generator outer barrel 302 and positioned at steaming
Steam generator intermediate cylinder 303 between vapour generator inner cylinder 302, steam generator outer barrel 302.Steam generator inner cylinder 302
The top of poisonous substance tank 5 is enclosed on, the lower end of steam generator outer barrel 302 is fixed in one end to water manifold 304, to water manifold 304
Lateral wall of the other end not with steam generator inner cylinder 302 and poisonous substance tank 5 contact.Under steam generator intermediate cylinder 303
End is fixed on the upper surface to water manifold 304, the both sides of steam generator intermediate cylinder 303 to being had on water manifold 304
Inlet opening 3041 and apopore 3042.Feed pipe 305 be located at steam generator outer barrel 302 and steam generator intermediate cylinder 303 it
Between the first ring cavity a in, one end of feed pipe 305 is connected with inlet opening 3041, the other end of feed pipe 305 and is arranged on pressure
Feed-water intake 103 on power thimble body 1 connects.
As shown in figure 3, the interior receivings of the second ring cavity b between steam generator inner cylinder 301 and steam generator intermediate cylinder 303
There are some equally distributed helix tubes 306, helix tube 306 is upward around inner cylinder spiral, the lower end of helix tube 306 and water outlet
Hole 3042 is connected, and the upper end of helix tube 306 is connected with the steam (vapor) outlet 104 being arranged on pressure vessel cylinder 1.Helix tube 306
External diameter is 19mm, and helix tube 306 has some, and the spacing between helix tube 306 and helix tube 306 is 25mm.In order to avoid by
Toll bar vortex vibration frequency caused by the eigentone and primary side water of helix tube 306 causes the possibility of vibration, spiral
Pipe 306 is supported by some porous support plates 307, and porous support plate 307 is located at steam generator inner cylinder 301 and sent out with steam
Arranged between raw device intermediate cylinder 303 and in radioactivity, helix tube 306 passes through the spiral of porous support plate 307.Preferably, it is more
The quantity of hole supporting plate 307 is 16 pieces.In order that the spiral space for obtaining helix tube 306 is bigger, heat exchange is more thorough, steams
Vapour generator intermediate cylinder 303 is located at steam generator inner cylinder 301 with the centre of steam generator outer barrel 302 close to steam generator
The side of outer barrel 302.
As shown in figure 3, it is provided with the outer wall of steam generator outer barrel 302 solid for fixed ring flat-plate 308, ring flat-plate 308
It is scheduled on pressure vessel cylinder 1.Tube sheet 309 is connected with feed-water intake 103 and at steam (vapor) outlet 104 respectively, tube sheet 309 is used respectively
Cover plate 310 is connected with the top of fixed feed pipe 305 and helix tube 306, the first ring cavity a, feed pipe 305 passes through cover plate 310.
As shown in figs. 1 and 8, feed-water intake 103 and steam (vapor) outlet 104 are separately positioned on the pressure vessel cylinder 1 at upper chamber f
Side wall on, the quantity of feed-water intake 103 and steam (vapor) outlet 104 is respectively four, and feed-water intake 103 and steam (vapor) outlet 104 are equal
Even to be arranged alternately, the axial line of feed-water intake 103 and steam (vapor) outlet 104 in same level and intersects at a point.
As shown in Figs. 4-6, reactor core 4 includes fuel assembly 401, and fuel assembly 401 is located in fuel tank 402, fuel assembly
401 and the lower end of fuel tank 402 be separately fixed at the lower end of fuel slabs 403 and the upper end of annular slab 404 on fuel slab 403 and consolidate
Connect, the lower end of annular slab 404 is connected with circular lower cover 405, and fuel slab 403, annular slab 404 and circular lower cover 405 form
One closed cooling water circulation cavity c.Coolant flow passages 4041 are opened on the ring wall of annular slab 404, coolant flow passages
4041 be several, and coolant flow passages 4041 are uniformly distributed around the ring wall of annular slab 404.Some poisonous substance circulation devices 406 are set
Put on circular lower cover 405, poisonous substance circulation device 406 is through circular lower cover 405 and is vertically arranged, poisonous substance circulation device 406
Upper end is located in cooling water circulation cavity c, and the lower end of poisonous substance circulation device 406 is located in lower boron water cavity d, coolant flow passages 4041
In lower boron water cavity d top, lower boron water cavity d is located at the lower section of annular slab 404.The upper end of poisonous substance circulation device 406 is located at cooling agent
The lower section of runner 4041, the lower end of poisonous substance circulation device 406 is close to lower boron water cavity d bottom.
As it can be seen in figures 5 and 6, the poisonous substance expansion absorption for reducing boric acid water concentration is additionally provided with circular lower cover 405
Device 407.Poisonous substance circulation device 406 and poisonous substance expanded absorber 407 are uniformly distributed.Hexagonal structure is easier to smoothly insertion, lifting,
Robot manipulator structure in the water used when more adaptation is reloaded.In order to capture conveniently, fuel assembly 401 is arranged to the structure of hexagon,
The cross-sectional area of fuel assembly 401 is hexagon.Use is connected with the lateral wall of the annular slab 404 of the lower section of coolant flow passages 4041
In fixed retainer ring 408.Some fixing holes 4081 for being used for fixed vertical direction are offered in retainer ring 408.Fixture
It is fixed on through fixing hole 4081 on pressure vessel cylinder 1.
As shown in Fig. 2 drive device includes being arranged on the main circulation pump 2 on the top of pressure vessel cylinder 1, the rotation of main circulation pump 2
Shaft axis overlap with the axis of pressure vessel cylinder 1, and main circulation pump 2 includes the motor 201 outside pressure vessel cylinder 1, electricity
Motivation 201 is supported on the top of pressure vessel cylinder 1 by electronic board 211.The output shaft of motor 201 and the one of main shaft 202
End is affixed by being indirectly connected with device 212, and the other end of main shaft 202 is connected with impeller 203.Main shaft 202 extend into cylindrical shape
Inside pump case 204, pump case 204 and main shaft 202 are concentric, and the upper end of pump case 204 is fixed in by shell upper flange 205
On pressure vessel cylinder 1.Impeller 203 is located inside pump case 204, and the lower end of impeller 203 is slightly protruded above under pump case 204
End.Some floss holes for discharging cooling water are provided with the side wall of pump case 204 in the upper chamber f of the top of impeller 203
2041, floss hole 2041 connects upper chamber f with poisonous substance tank 5.Floss hole 2041 uniformly divides around the axial line of pump case 204
Cloth.
As shown in figure 1, impeller 203 is arranged on inside the steam generator inner cylinder 301 of the top of poisonous substance tank 5, pump case 204
Caliber is less than the interior caliber of steam generator inner cylinder 301, and steam generator inner cylinder 301 extends up to feed-water intake 103 and steamed
Then the top of vapor outlet 104 is consolidated towards its end and the inwall of pressure vessel cylinder 1 after the direction bending of the inwall of pressure vessel cylinder 1
Connect, some inner cylinder spout holes corresponding with floss hole 2041 are provided with the side wall of steam generator inner cylinder 301.Floss hole 2041
The steam generator inner cylinder 301 of lower section is fixed on the upper end of steam generator inner cylinder 301 by fixed plate.
As shown in Fig. 2 it is provided between the main shaft 202 and pump case 204 of the top of impeller 203 for supports main shaft 202
Pump inner casing 206, pump inner casing 206 are cylindrical shape, and pump inner casing 206 and main shaft 202 are concentric, and pump inner casing 206 is close to motor 201
One end is connected with inner casing upper flange 207, and inner casing upper flange 207 is fixed in the upper end of shell upper flange 205, main shaft 202 and inner casing
Connected between upper flange 207 by gland seal device 208.For supports main shaft 202, the pump inner casing 206 of the lower section of shell upper flange 205
Internal orifice dimension be slightly larger than the diameter of main shaft 202, the ring wall inner hollow of the pump inner casing 206 of the lower section of shell upper flange 205.Pump inner casing
Internal lower house 209 is provided between 206 lower end and impeller 203, is provided with internal lower house 209 for fixed main shaft
202 water middle (center) bearing 210.Water middle (center) bearing 210 is hydrostatic bearing.
As shown in Fig. 2 sucked for the ease of primary side recirculated water is easier by main circulation pump 2, the lower end of pump case 204
It is arranged to downward opening bell-mouth structure of air 2042.In order to make full use of the inner space of reactor pressure vessel, reduce whole
The volume of individual pressure vessel, while a series of problems caused by thermal expansion during reactor operation can be reduced.Main shaft 202 is set
Put and overlapped in the top of pressure vessel, the axis of main shaft 202 with the axis of pressure vessel.
As shown in fig. 7, passive reactor shut-off system 6 is hydraulic pressure operating valve, hydraulic pressure operating valve is arranged on the upper end of poisonous substance tank 5,
The quantity of hydraulic pressure operating valve has three.Passive reactor shut-off system 6 includes cylinder block 601, and piston rod is provided with cylinder block 601
602, the upper end of piston rod 602 is provided with piston 603, and the diameter of piston 603 is more than the diameter of piston rod 602, the top of piston 603
The end set of piston rod 602 have valve cover plate 604.Cylinder block 601 is fixed on valve seat 605, the cylinder of the lower section of piston 603
Cylinder connected entrance 607 is offered in the side wall of body 601, the cylinder connected entrance 607 inside poisonous substance tank 5 by cylinder interior with it is upper
Boron water cavity e is connected, and valve cover plate 604 is located at the pressure that the outside of poisonous substance tank 5 is used to experience a side loop.The pressure of side loop
The lower surface of valve cover plate 604 abuts with the upper surface of cylinder block 601 when power is more than the pressure in upper boron water cavity e, now boron water
Chamber is in air-tight state, when the pressure of a side loop is less than the pressure in upper boron water cavity e the lower surface of valve cover plate 604 with
The upper surface of cylinder block 601 is separated, and now boron water cavity is opened.
As shown in fig. 7, the side wall of piston 603 is provided with screw thread 6031, use is left between piston 603 and the madial wall of cylinder
In the gap 608 for the 5mm that boric acid water passes through.For the ease of the circulation of boric acid water, the upward bent outward in edge of valve cover plate 604
Song, the longitudinal section of valve cover plate 604 is inverted herringbone structure.The lower end of piston rod 602 is provided with plain block 606.Trim
The inner hollow of block 606, with inside plain block 606 filled with water.Piston 603 and it is full of boric acid water with the space between plain block 606.Cylinder
Connected entrance 607 is arranged on between plain block 606 and piston 603.
As shown in figure 1, pressure vessel cylinder 1 includes upper cover 101 and low head 102, upper cover 101 and low head 102 it
Between be connected through a screw thread, poisonous substance tank 5 is arranged in low head 102, and drive device is arranged in upper cover 101.Poisonous substance tank 5 includes
Poisonous substance tank hypomere 505, poisonous substance tank changeover portion 504 and poisonous substance tank epimere 503, poisonous substance tank changeover portion 504 are tapered tubular, poisonous substance tank
The caliber of epimere 503 is less than the caliber of poisonous substance tank hypomere 505, and steam generator inner cylinder 301 is enclosed on the outside of poisonous substance tank epimere 503,
The internal diameter of steam generator inner cylinder 301 is equal to the external diameter of poisonous substance tank epimere 503.
The operation principle of the invention:
Primary side cooling water is in pressure vessel inner loop, and primary side cooling water is after the heating of reactor core 4, in main circulation pump
Floss hole 2041 is moved across in the presence of 2 from the bottom up and inner cylinder spout hole is discharged into upper chamber f, then from steam generation
The gap of the helix tube 306 of device 3 is returned in reactor core 4 to flowing down by decline passway g and coolant flow passages 4041, is completed once
The circulation of cooling water.
Secondary side cooling water enters helix tube 306 from the warp of feed-water intake 103 to water manifold 304, through helix tube 306 and once
Side cooling water contact fully heat exchange, finally flows out from steam (vapor) outlet 104, realizes cooling and the secondary side circuit of side loop
Heating.Reactor is by the boric acid water regulation reactor capability being enclosed in the poisonous substance tank 5 outside reactor core 4, when main circulation pump 2 is pressed
When power declines, three passive reactor shut-off systems 6 of the upper end of poisonous substance tank 5 are opened, and boric acid water is automatically injected in reactor core 4, realize reaction
The slow shutdown of heap.
The operation principle of main circulation pump 2:Whole main circulation pump 2 drives main shaft 202 by motor 201 by being spaced connector
Being rotated, the primary side recirculated water in pressure vessel cylinder 1 flows up in the presence of impeller 203, and by pump case
Floss hole 2041 on 204 emits water, is exchanged heat into the top of steam generator 3.In order to reduce weight, improve
Rigidity, the bottom of main shaft 202 are hollow, and top is solid, and main shaft 202 passes through shell upper flange 205.The footpath of whole main circulation pump 2
Supported to load by the journal bearing of the water middle (center) bearing 210 and motor 201 that are located at lower housing portion, axial load is by motor
201 cod support.The water middle (center) bearing 210 of main circulation pump 2 is the hydrostatic bearing acted on by main circulation pump 2 from pressure, this
Kind bearing does not need lubricating oil, and its principle is non-contacting in operation, so abrasion are few, essentially without maintenance.In main shaft
202 tops have gland seal device 208 to seal the high temperature and high pressure steam that reactor pressure vessel top is full of.Main circulation pump 2 is installed
At the surface axis of pressure vessel cylinder 1, the inner space of reactor vessel cylinder 1 is not only taken full advantage of, is reduced
The volume of whole pressure vessel cylinder 1, while a series of problems caused by thermal expansion during reactor operation can be reduced, make core
Reactor plant is compact-sized, and reliability is high, security is good.
The operation principle of steam generator 3:Steam generator 3 uses deep bid tubular type, is designed as four Hes of feed-water intake 103
Four steam (vapor) outlets 104 are adjacent to be alternately arranged.The secondary side water of steam generator 3 is entered by feed-water intake 103, passes through feed pipe
305 downwardly into in water manifold 304, and the water to water manifold 304 enters lower part helical pipe 306 under the effect of the pressure
In, the reclaimed water of helix tube 306, by being exchanged heat with the water of primary side outside pipe, forms steam to steam (vapor) outlet during rising
104, so as to which pushing turbine does work and drives electrical power generators.The current direction of primary side and secondary side is on the contrary, can fully exchange heat.
By giving water management to single feed-water intake 103, the Power operation of steam generator 1/4 can be achieved, if not blocking, steam hair
Raw device 3 is with Power operation at full capacity.
This steam generator 3 is applied not only on nuclear reactor, can also use the occasion in other heat exchange, such as firepower hair
On the heat exchange heat-transfer equipment of electric system or chemical industry.The invention uses pressure vessel and the integrated design of steam generator 3
The inner space of reactor pressure vessel is taken full advantage of, while four feed-water intakes 103 and steam (vapor) outlet 104 are set, effectively
The volume for reducing whole steam generator 3, improve heat exchange efficiency.In addition, pass through the control to four feed-water intakes 103
The power adjusting of steam generator 3 can be achieved, operation is easy to operate.
The passive shutdown of reactor is realized by passive reactor shut-off system 6, when primary side circuit pressure is high, by
It is more than the pressure of boric acid water, under pressure, the lower surface of valve cover plate 604 and cylinder block in the pressure of a side loop
601 upper surface abuts, the closing of boron water cavity, and the boric acid water in lower boron water cavity d can not enter reactor core 4.Poisonous substance circulation device 406, it is
A kind of cellular mixing preventer, it can control boron water-carrying capacity under differential pressure action, realize dense to a side loop boron water
The regulation of degree, so as to realize the regulation to reactor capability.When the rotating speed of main circulation pump 2 reduces, or in a side loop
Pressure when declining, the lower surface of valve cover plate 604 separates with the upper surface of cylinder block 601, and the boric acid water in boron water cavity can be with
Flowed out by the gap 608 between piston 603 and cylinder, the boric acid water of outflow is then introduced by lower boron water cavity d by drainage tube
Interior, under the effect of the pressure, the boric acid water in lower boron water cavity d is flowed into reactor core 4 by poisonous substance circulation device 406, and boric acid has suction
The effect of neutron is received, it is achieved thereby that passive shutdown.
The preferred embodiment of the invention is the foregoing is only, is not intended to limit the invention creation, it is all at this
Within the spirit and principle of innovation and creation, any modification, equivalent substitution and improvements made etc., the invention should be included in
Protection domain within.
Claims (10)
1. the passive reactor shut-off system based on pressure difference for integrated heap, it is characterised in that:Including cylinder block (601), cylinder
Piston rod (602) is provided with body (601), the upper end of piston rod (602) is provided with piston (603), and the diameter of piston (603) is big
Diameter in piston rod (602), the end set of the piston rod (602) above piston (603) have valve cover plate (604), cylinder
Body (601) is fixed on valve seat (605), and cylinder connected entrance is offered in the side wall of the cylinder block (601) below piston (603)
(607), cylinder connected entrance (607) connects cylinder interior with boron water cavity, and valve cover plate (604) is located in a side loop and is used for
Experience the pressure of a side loop, the lower end of valve cover plate (604) when the pressure of a side loop is more than the pressure in boron water cavity
Face abuts with the upper surface of cylinder block (601), valve cover plate (604) when the pressure of a side loop is less than the pressure in boron water cavity
Lower surface separated with the upper surface of cylinder block (601).
2. the passive reactor shut-off system based on pressure difference according to claim 1 for integrated heap, it is characterised in that:Institute
State the gap (608) left between piston (603) and the madial wall of cylinder block (601) and passed through for boric acid water.
3. the passive reactor shut-off system based on pressure difference according to claim 1 for integrated heap, it is characterised in that:Institute
The lateral wall for stating piston (603) is provided with screw thread (6031), and use is left between piston (603) and the madial wall of cylinder block (601)
In the gap that boric acid water passes through (608).
4. the passive reactor shut-off system based on pressure difference according to claim 3 for integrated heap, it is characterised in that:Institute
It is 5mm to state gap (608).
5. the passive reactor shut-off system based on pressure difference according to claim 1 for integrated heap, it is characterised in that:Institute
The edge for stating valve cover plate (604) is bent outwardly upwards, and the longitudinal section of valve cover plate (604) is inverted herringbone structure.
6. the passive reactor shut-off system based on pressure difference according to claim 1 for integrated heap, it is characterised in that:Institute
The lower end for stating piston rod (602) is provided with plain block (606).
7. the passive reactor shut-off system based on pressure difference according to claim 6 for integrated heap, it is characterised in that:Institute
State and match somebody with somebody plain block (606) inner hollow, it is internal filled with water with plain block (606).
8. the passive reactor shut-off system based on pressure difference according to claim 6 for integrated heap, it is characterised in that:Institute
State piston (603) and be full of boric acid water with the space between plain block (606).
9. the passive reactor shut-off system based on pressure difference according to claim 6 for integrated heap, it is characterised in that:Institute
Cylinder connected entrance (607) is stated to be arranged on between plain block (606) and piston (603).
A kind of 10. nuclear reactor, it is characterised in that:Including described in any one of claim 1 to 9 be used for integrated heap based on
The passive reactor shut-off system (6) of pressure difference.
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