JP3167771B2 - Reactor and fuel assemblies - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a nuclear reactor, and more particularly to a boiling water reactor and a fuel assembly having a control rod with a lower insertion.

[0002]

2. Description of the Related Art Generally, a control rod is used in a boiling water reactor as one method for controlling a surplus reaction. As shown in a cross-sectional view of FIG. Is composed of a large number of B ₄ C (boron compound) rods 2 arranged in a cross, and a fuel bundle 5 in which a plurality of fuel rods 3 arranged in a bundle is surrounded by a channel box 4. The fuel assemblies 5 are arranged between the fuel assemblies 5 at a ratio of one to four. For example, in the case of a reactor with an electric output of 1.35 million kW, as shown in the second quadrant layout of all the cores in FIG.
The book is used.

[0003] When the operation of the control rod 1 is stopped, all the control rods 1 are inserted into the core at all strokes when the operation of the reactor is stopped, and control is performed so that the reactor becomes subcritical. During operation, the number of control rods 1 and the insertion depth are adjusted so that a part of the control rods 1 is pulled out and becomes critical. FIG. 8 is a perspective view of the control rod 1. The control rod 1 is usually provided with a handle 6 at the upper end, a B ₄ C rod 2 as a neutron absorber at the center, and a lower skirt 7 at the lower part. ing.

FIG. 8 shows an example in which B ₄ C is used as a neutron absorber, but there is also an example in which Hf (hafnium) or the like is used. Conventionally, the control rod effective length (length of the effective portion) 8 in which the neutron absorbing material is disposed in the control rod 1 is, as shown in the fuel and control rod effective length configuration diagram of FIG. It is designed to be almost the same as or slightly shorter than the active fuel length (fuel length) 9 of 5. As shown in the longitudinal sectional view of FIG. 10, the boiling water reactor has an area called a lower plenum 13 below a core support plate 12 supporting a core 11 in a reactor pressure vessel 10. The coolant discharged from the circulation pump flows upward in the lower plenum 13.

A control rod guide tube 14 is disposed in the lower plenum 13. The control rod 1 is housed in the control rod guide tube 14 when the control rod 1 is pulled out. The control rod guide tube 14 is connected to a control rod drive mechanism 16 outside the reactor pressure vessel 10 through a control rod drive mechanism housing 15, and the control rod 1 is inserted into the reactor core 11.
The control rod drive mechanism 16 controls the insertion and withdrawal. The lengths of the control rod guide tube 14 and the control rod drive mechanism housing 15 are generally the same as the stroke length of the control rod 1.

[0006]

The shortening of the control rod 1 in the core 11 not only reduces the cost of the control rod 1 itself, but also reduces the cost of the control rod 1 itself, and furthermore, the control rod guide tube 14 and the control rod driving mechanism attached to the control rod 1. Since the housing 15 etc. can be shortened,
The length of the lower plenum 13 is also reduced,
Can be made compact, and the cost can be further reduced. At the same time, by shortening the control rod drive mechanism housing 15 and the reactor pressure vessel 10, when the lower end of the reactor containment vessel (not shown) containing the reactor pressure vessel 10 is set at the same height as the conventional one, Since the core position is shifted below the reactor pressure vessel, the position of the center of gravity is lowered and the earthquake resistance is improved.

Further, the value of the control rod 1 is reduced by neutron absorption in the core 11 and the value of the control rod is usually about 10%.
When it decreases, it is replaced with a new control rod 1 at the time of periodic inspection.
Therefore, since the shortening of the control rod 1 contributes to the reduction of radioactive waste, a reasonable reduction in the length of the control rod 1 has been demanded. However, from the viewpoint of nuclear reaction, simply shortening the length of the control rod 1 reduces the value of the control rod by that much, and for example, a shortage of the reactor shutdown margin occurs. When the reactor is stopped, all the control rods 1 are inserted into the core 11 and the reactor is in a subcritical state. In this reactor stopped state, one of the control rods 1 is removed from the core 11. It is required that the reactor be subcritical even if it is withdrawn.

[0008] The subcriticality when the control rod 1 having the largest control rod value is pulled out is the furnace stop margin. As for the reactor shutdown function in the event of an emergency, the function can be achieved if the control rod 1 is rapidly inserted from the lower end of the core 11 to about 50 % of the total core length. However, there is no restriction on shortening the control rod.

An object of the present invention is to provide a control rod having a good control characteristic and a short control rod while maintaining good control characteristics, in designing a control rod. It is an object of the present invention to provide a reactor and a fuel assembly in which a control rod guide tube, a control rod drive mechanism housing, a reactor pressure vessel, and the like, which are associated with the reactor, can be shortened, and earthquake resistance is improved and cost is reduced.

[0010]

In order to achieve the above object, a first aspect of the present invention is to provide a fuel assembly comprising a plurality of fuel rods arranged in a channel box and a fuel bundle comprising a plurality of fuel rods arranged in a channel box. A boiling water reactor in which a control rod made of a neutron absorbing material is provided between the fuel assemblies so as to be able to be inserted and withdrawn from the lower part to control the reactivity of the fuel rods, wherein the fuel assembly has at least two or more in the axial direction. and is divided into regions, the upper end of the uppermost reactivity of the upper region is smaller than the reaction of the region other than the top, and the control rod <br/> Keru us when inserted full stroke neutron absorber during cold Is below the lower end of the uppermost region of the fuel assembly , and
One that the located within 3 inches below the bottom end, characterized by. Claim 2 of the present invention provides a fuel assembly for a boiling water reactor , wherein a fuel bundle in which a number of fuel rods are arranged is surrounded by a channel box, wherein the fuel assembly is at least two or more in the axial direction. The reactivity of the uppermost region in the cold state is lower than the reactivity of the region other than the uppermost region, and the lower end of the uppermost region of the fuel assembly is made of a neutron absorbing material. above der than the neutron absorber upper end at full stroke control rod insertion is more inserted into and removed from the vicinity of the side of the fuel assembly
And within 3 inches of the upper edge
And According to a third aspect of the present invention, in the fuel assembly according to the second aspect, the uppermost region is a blanket.
It is characterized by being.

[0011]

[Action] With this configuration, reactor shutdown margin is Ru is extended secured
Together with the control rod is short of, the control rod guide tubes attached to this shortening of the control rods, a nuclear reactor pressure vessel lower plenum length is shortened by shortening of such control rod drive mechanism housing becomes compact, the reactor pressure The position of the center of gravity of the container is lowered, the seismic resistance is improved, and the cost can be reduced.

[0012]

An embodiment of the present invention will be described with reference to the drawings. The same components as those of the above-described conventional technology are denoted by the same reference numerals, and detailed description thereof will be omitted. The relationship between the fuel assembly and the control rods in the first embodiment is shown in the effective length configuration of the fuel and control rods in FIG. The length 41 has a positional relationship when the entire stroke is inserted from the lower part of the core, and the fuel assembly 20 has an upper blanket 22 made of natural uranium as a low-reactivity fuel at the upper part and an enriched fuel part 23 at the lower part. On the other hand, the upper end of the neutron absorber, which is the control rod effective length 41 of the control rod 40, is located below the lower end or lower end of the upper blanket 22 of the fuel assembly 20.

Next, the operation of the above configuration will be described. The above configuration is based on the evaluation of the relationship between the control rod withdrawal amount in a cold state and the furnace stop margin. FIG. 2 is a characteristic diagram of the change in the furnace stop margin with respect to the control rod withdrawal amount. The distance that the control rod is pulled out from the upper end of the fuel assembly 20 is
The vertical axis shows the change in the reactor shutdown margin based on the reactor shutdown margin in the core of the fuel assembly without the upper blanket 22 (%
Δk).

The hatched portion crossing each of the curves BL ₁ , BL ₂ , BL ₃ in the figure is the boundary between the upper blanket 22 and the enriched fuel portion 23, the left side of the hatched portion is the upper blanket region, and the right is the enriched fuel portion. Area. Here, the curve BL _O is the core of the fuel assembly without the upper blanket 22, and the curve BL ₁ ,
BL ₂ and BL ₃ show the case of the core with the fuel assembly 20 in which the thickness of the upper blanket 22 is 6, 12, and 24 inches, respectively.

According to FIG. 2, when the control rod withdrawal amount is the same, the curve BL increases as the upper blanket 22 becomes thicker.
_The reactor shutdown margin is larger than the reference core indicated by _O. In other words, immediately reactor shutdown margin is deteriorated and begin to pull out all the control rods in the curve BL _O. However, the upper blanket 22
In the curve BL ₁ when the thickness of the furnace is 6 inches, the furnace stop margin hardly changes even if all the control rods are pulled out to the lower end of the upper blanket 22, that is, if the furnace is pulled out 6 inches, and the furnace is pulled out even if it is further pulled out 2 to 3 inches. Deterioration of stop margin is small.

The curve BL ₂ is a core of the fuel assembly 20 in which the thickness of the upper blanket 22 is set to 12 inches, but all the control rods are pulled out to the lower end of the upper blanket 22 as in the case of the curve BL _1. The furnace stop margin hardly changes, and the furnace stop margin is hardly degraded by pulling out a few inches from the lower end of the upper blanket 22. Moreover, similar results in the curve BL ₃ where the thickness of the upper blanket 22 is 24 inches obtained.

As described above, the effective fuel length of the fuel assembly 21
When the control rod 40 is inserted from below the core in the core of the fuel assembly 20 in which the fuel with low reactivity at the time of cold in the upper region, for example, a blanket 22 made of natural uranium, the control rod 40 becomes effective. It can be seen that even if the upper end of the portion is about the same as the lower end of the upper blanket 22, or slightly below, the furnace stop margin hardly deteriorates.
Therefore, the control rod 40 can be made shorter in the thickness of the upper blanket + α than the control rod 1 of the conventional example.

For example, when the thickness of the upper blanket 22 is 12 inches, the control rod of about 144 inches in the related art can be shortened by 12 inches or more. In addition, the control rod guide tube 14 and the control rod drive mechanism housing 15 can be shortened by about 12 inches at a time as the control rods are shortened by 12 inches or more, so that the conventional reactor pressure vessel 10 having a height of about 20 m can be reduced by about 60 cm. It can be lowered and the position of the center of gravity can be shifted downward by about 90 cm.

The effective length configuration of the fuel and control rods shown in FIG. 3 is a modification of the first embodiment, in which the fuel assembly 24 has a lower blanket 25 at the bottom in addition to the upper blanket 22 at the top.
Is divided into two regions, and the high-reactivity fuel
26, a low-reactivity fuel 27 is arranged below the control rod 40. The control rod 40 is formed at the lower end of the upper blanket 22 of the fuel assembly 24 or at a length shorter than the lower end similarly to the first embodiment. Control rods with an effective length of 41 are combined.

Further, the effective length configuration of the fuel and the control rods in FIG. 4 shows another modified example of the first embodiment as in FIG. 3, and the fuel assembly 28 includes an upper blanket 22 and a lower blanket. The middle of 25 is divided into three regions, and a low-reactivity fuel 27 is disposed above, a high-reactivity fuel 26 is disposed in the middle, and a medium-reactivity fuel 29 is disposed below. Also in this case, the control rod 40 is a lower end of the upper blanket 22 of the fuel assembly 28 or a single control rod 40 having a control rod effective length 41 shorter than the lower end as in the first embodiment. It is configured in combination. As in the two modified examples shown in FIGS. 3 and 4, the fuel assemblies 24 and 28 in which fuels having different reactivity in the active fuel length are arranged in various combinations are also provided with the upper blanket 22 at the top. With this configuration, the same operations and effects as those of the above-described embodiment shown in FIG. 1 can be obtained.

FIG. 5 is a cross-sectional view of a fuel assembly according to a second embodiment of the present invention. In the first embodiment, as a means for lowering the reactivity of the uppermost portion in a cold state, an upper portion is used. Although the use of natural uranium as the blanket 22 has been illustrated, as shown in FIG. 5, the number of fuel rods 3 in the uppermost region of the fuel assembly 30 is smaller than the number of fuel rods in regions other than the uppermost region. The same effect can be obtained.
That is, the fuel assembly 30 has a configuration in which the fuel rod 3 in the uppermost region of the surface facing the control rod 40 is removed.

According to this configuration, in the upper part of the fuel assembly 30, the water that is the neutron moderator and the coolant contains about 70% of the voids due to the heat generated by the fuel rods 3 during the output operation. In the shortage state, the water is slightly increased by the amount of the removed fuel rod 3, and the deceleration state of the neutrons is improved. Therefore, the decrease in the reactivity is small and does not hinder the operation. However, since no voids are generated in a cold state, water equivalent to the volume of the removed fuel rod 3 increases, and the parasitic absorption ratio of neutrons by water increases, thereby decreasing the reactivity. Act on.

It should be noted that such an operation and effect are obtained by the fuel assembly.
Although it can be obtained by removing the fuel rods 3 near the center in the cross section of 30, it is more remarkable to remove the fuel rods 3 around the center than near the center. This is because the water is full, and the neutron absorption effect becomes particularly large when the water increases near this area.
Accordingly, by reducing the number of fuel rods in the uppermost region of the fuel assembly 30, the reactivity of the uppermost region in a cold state can be reduced, and as described in the first embodiment, the control rods are shorter. Can be achieved.

[0024]

As described above, according to the present invention, it is possible to shorten the length of the control rod by improving the furnace stop margin, thereby reducing the length of the control rod guide tube, control rod drive mechanism housing, etc. attached to the control rod. As a result, the length of the lower plenum is shortened, and the reactor pressure vessel is made compact and cost is reduced. At the same time, the shortening of the control rod drive mechanism housing and the reactor pressure vessel lowers the position of the center of gravity of the reactor core in the reactor containment vessel, and has the effect of improving seismic resistance.

[Brief description of the drawings]

FIG. 1 is a diagram showing the effective length of fuel and control rods according to a first embodiment of the present invention.

FIG. 2 is a characteristic diagram of a change in a furnace stop margin with respect to a control rod withdrawal amount according to the first embodiment of the present invention.

FIG. 3 is a diagram showing the effective lengths of fuel and control rods according to a modification of the first embodiment of the present invention.

FIG. 4 is a diagram showing the effective lengths of fuel and control rods according to another modification of the first embodiment of the present invention.

FIG. 5 is a cross-sectional view of a fuel assembly and a control rod according to a second embodiment of the present invention.

FIG. 6 is a cross-sectional view of a conventional fuel assembly and a control rod.

FIG. 7 is a layout diagram of a second quadrant of all cores.

FIG. 8 is a perspective view of a control rod.

FIG. 9 is a diagram showing the effective length of a conventional fuel and control rod.

FIG. 10 is a longitudinal sectional view of a boiling water reactor.

[Explanation of symbols]

2 ... B ₄ C rods, 3 ... fuel rod, 10 ... reactor pressure vessel, 13
... lower plenum, 14 ... control rod guide tube, 15 ... control rod drive mechanism housing, 16 ... control rod drive mechanism, 20, 24, 28, 30 ...
Fuel assembly, 21 ... Effective fuel length, 22 ... Upper blanket,
23: concentrated fuel section, 25: lower blanket, 26: high reactivity fuel, 27: low reactivity fuel, 29: medium reactivity fuel, 40: control rod, 41: control rod effective length.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-54-162086 (JP, A) JP-A-63-51094 (JP, A) JP-A-2-51094 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) G21C 7/00 G21C 7/08 G21C 3/328 G21C 5/18 G21C 5/20

Claims (3)

(57) [Claims] A fuel rod comprising a plurality of fuel rods arranged in a channel box is surrounded by a plurality of fuel assemblies, and a control rod made of a neutron absorbing material can be inserted and removed between fuel assemblies from below. In the boiling water reactor provided to control the reactivity of the fuel rod, the fuel assembly is axially divided into at least two or more regions, and the reactivity of the uppermost region in a cold state is the highest. less than the reaction of the other regions, and the upper end of the contact Keru neutron absorber during full stroke insertion of the control rods, a lower than a lower end of the top region of the fuel assembly, and the lower end
Reactor, characterized in that, being located within three inches below the. 2. A boiling water reactor comprising a fuel bundle in which a number of fuel rods are arranged and surrounded by a channel box.
In the reactor fuel assembly, the fuel assembly is axially divided into at least two or more regions, and the reactivity of the uppermost region in a cold state is smaller than the reactivity of the region other than the uppermost region, And the lower end of the uppermost region of the fuel assembly is above the upper end of the neutron absorber at the time of full stroke insertion of a control rod made of a neutron absorbing material and inserted from the lower portion near the side of the fuel assembly. And its upper end
A fuel assembly located within 3 inches of the fuel cell. 3. The fuel assembly according to claim 2, wherein said uppermost region is a blanket .