JPH0656171B2 - Fittings for fixing the metal body to the wall of the fuel channel - Google Patents

Description

Description: FIELD OF THE INVENTION The present invention relates to a joint for securing a metal body to a wall portion of a fuel channel made of a zirconium alloy for a nuclear fuel assembly.

(Prior Art) For such a joint, see US Pat. No. 4,526,74.
No. 4 specification is disclosed. The fuel channel shown in this U.S. patent specification is made of a zirconium alloy. A square section sleeve made of zirconium alloy is connected to the lower part of the fuel channel, and the lower part base, which is a metal body, is connected to this sleeve by bolts. The metal main body has an inlet opening in the center thereof, and water is supplied from the inlet opening toward the fuel channel to cool the nuclear fuel arranged in the fuel channel. The bolt connecting the metal body and the sleeve,
Mounted through a hole provided in the sleeve and through a screw hole provided in the lower part base, and arranged to press the inner surface of the sleeve against a contact surface formed in the lower part base, which is a metal body There is. The bolt is made of a material having a coefficient of thermal expansion greater than that of the zirconium alloy of the sleeve, and the head of the bolt has an annular conical surface with a corresponding conical surface of the bore of the sleeve at room temperature. Is embedded in the sleeve so that it contacts the.

(Problems to be Solved by the Invention) In the above-described conventional joint, when the bolt head conical surface is heated from room temperature to the reactor temperature,
The thermal expansion is larger than the thermal expansion of the corresponding conical surface provided on the sleeve that is the wall portion of the fuel channel, and generally, the thermal expansion is almost doubled.
Therefore, the bolt head is subjected to compressive stress acting at a right angle to its conical surface, which in turn causes the bolt to be tensioned in its axial direction. This tension becomes extremely large and there is a danger that the bolt will break.

An object of the present invention is to reduce the mechanical stress applied to the bolt as the temperature rises, and to reduce the axial tension acting on the bolt when heated from room temperature to the reactor temperature. is there.

(Means for Solving the Problems) The reference numerals used in one embodiment of the present invention to be described later are additionally shown for reference, and the present invention is made of a zirconium alloy for a nuclear fuel assembly. A joint for fixing a metal body 3 to the wall of a fuel channel 1 having a conical bolt head 6 and a central axis 5 extending longitudinally through a hole provided in said wall. And a bolt 4 arranged to press the wall portion against the contact surface 12 formed on the metal body 3, the bolt 4 having a thermal expansion coefficient greater than that of the zirconium alloy. Made of a material having a modulus, said bolt head 6 is provided in said wall portion such that an annular conical surface 7 of said bolt head 6 contacts a corresponding conical surface 8 of said hole at room temperature. It is embedded in the joint The metal body 3 has a surface portion 1 facing the wall portion.
1, the surface portion 11 is located immediately adjacent to the bolt head 6 and distributed around the bolt 4, and the surface portion 11 is relative to the contact surface 12. Is displaced in the direction of the central axis 5,
A gap 13 is defined between the wall portion and the metal body 3.

(Operation) In the present invention, the metal body 3 has the surface portion 11, and the surface portion 11 forms the gap 13 with the wall portion of the fuel channel 1. Since this gap 13 is arranged around the bolt head 6 and in the vicinity thereof,
When the temperature rises and the axial tension applied to the bolt 4 increases, the wall portion of the fuel channel 1 is deformed into the gap 13. Therefore, the axial tension applied to the bolt 4 is relieved.

(Effect of the Invention) According to the present invention, the tension applied in the axial direction of the bolt when the temperature becomes high is reduced, so that the life of the bolt can be extended. Moreover, it becomes possible by adopting an extremely simple means.

(Embodiment) FIG. 1 shows a joint for fixing a metal body to a fuel channel 1 for a nuclear fuel assembly. The top of the fuel channel 1 is provided with an eyebolt 2 for lifting and lowering the fuel channel 1 in cooperation with a lifting device (not shown). The lower wall part of the fuel channel 1 encloses the upper part of the bottom part 3, which is a metal body, with almost no play, and a plurality of bolts 4 (only one is shown in FIG. 1). Absent)
By means of the lower wall part and the bottom part 3 of the fuel channel 1.
And are fixed. The joint of the present invention uses the bolt 4
And an improved metal body. An inlet opening (not shown) is provided inside the central portion of the bottom portion 3, and water flows through the inlet opening to the fuel channel 1.
It is designed to cool the nuclear fuel that is supplied to and placed inside.

The bolt 4 has a conical bolt head 6 and a central axis 5 extending through a hole having a conical surface 8 formed in the wall portion of the fuel channel 1. Further, the bolt 4 is arranged to press the wall portion of the fuel channel 1 against the contact surface 12 formed on the bottom portion 3. Bolt head 6
The annular conical surface 7 of is mechanically in contact with the corresponding conical surface 8 of the hole formed in the wall portion of the fuel channel 1 at room temperature, as shown in FIG. It is embedded in the wall of the fuel channel 1.

The bolt 4 is fitted in a screw hole 9 formed in the bottom part 3. The outermost end of the screw hole 9 is an annular conical surface 1
It is 0. This conical surface 10 is in contact with a portion of the conical surface 7 of the bolt head 6 at room temperature, as shown in FIG.
There will be a small play between them as shown. The generatrix of the conical surface 7 of the bolt 4 forms an angle α with the central axis 5 of the bolt 4, and this angle α is 3
0 ° to 50 °, preferably 35 ° to 45 °
Is in the range.

The fuel channel 1 is made of a zirconium alloy, and its coefficient of thermal expansion is less than 10 × 10 ^-6 ° C ^-1 . An example of such an alloy is Zircaloy 4, which has a coefficient of thermal expansion of 8.2 x 1
It is smaller than 0 ^-6 ° C ^-1 .

Bolt 4 is made of a material whose yield point at 286 ° C exceeds 120 N / mm ² , preferably 140 N / mm ^2.
Made from the above materials. Such materials are for example Incolo
It is y800. The coefficient of thermal expansion of this material in the range of 20 ° C to 286 ° C is larger than 13 × 10 ^-6 ° C ^-1 .
This material within the range of 20 ° C to 286 ° C is 20 ° C of the zirconium alloy used for the fuel channel 1.
It has a thermal expansion coefficient exceeding 50% or more, usually 70% or more, over the average thermal expansion coefficient in the range of ˜286 ° C.

The shortest distance E between the inner wall surface of the fuel channel 1 and the threaded portion of the bolt 4 is smaller than the largest diameter D of the bolt head 6. Normally, E is smaller than 0.5D.

The contact surface 12 between the inside of the fuel channel 1 and the outside of the bottom portion 3 has a vertical extension H along the main part of the circumference of the fuel channel 1. At each bolt head 4, the vertical extension of the contact surface 12 has a minimum value M.
The surface of the bottom portion 3 facing the wall of the fuel channel 1 is milled, arranged around each screw hole 9 and facing the fuel channel 1 and immediately adjacent to the screw hole 9. An annular, generally flat surface portion 11 is formed.
The surface portion 11 has contact surfaces 1 such that an annular gap 13 is defined between the wall portion of the fuel channel 1 and the bottom portion 3.
It is displaced in the direction of the axis 5 of the bolt 4 with respect to 2.
In the case of new and fresh fuel assemblies, the width of the gap 13 closest to the bolt head 6 is at least 7% and at most 50% of the wall thickness of the fuel channel 1. Suitably, the gap width is selected within the range of 0.3-0.8 mm.

According to the part of the bottom part 3 shown in FIG. 4, the bottom part 3 has a surface part 11 of an annular milled area, whose radial annular width, measured from the edge of the screw hole 9, is at its maximum. It varies between a small width and a width approximately twice the minimum width. In the joint according to one embodiment of the present invention, the above-mentioned minimum width is selected to be larger than 30% of the maximum diameter of the screw hole 9, and preferably larger than 50%. Also, the minimum width is selected to be less than 200% of the maximum diameter of the screw hole 9, preferably less than 150%.

Connect the joint shown in FIG. 3A to the reactor temperature, for example, 2
When heating to a temperature above 50 ° C, the bolt head 6
The different diameters contained in the conical surface 7 of the bulge expand more than the respective corresponding diameters of the conical surface 8 of the hole formed in the wall of the fuel channel 1. The gap 13 then allows the wall portion of the fuel channel 1 around the bolt head 6 to be deformed into the gap 13, as can be seen in FIG. 3B. As described above in the related art, when the temperature of the bolt 4 becomes high, a large amount of axial tension is applied to the bolt 4. However, in the present invention, since the bolt 13 is provided with such a gap 13, The wall portion of the channel 1 is adapted to be able to deform and enter into the gap 13, so that the tension in the axial direction of the bolt 4 is significantly reduced.

In the case of the fitting shown in the attached drawing, the fuel channel 1
Made from Zircoloy 4 and Bolt 4 Incoly 800
The tensile stress of the bolt 4 is
3 to form 200 N / mm ² to 20 N / m
It has been found that it is possible to reduce to m ² .

Alternatively, the annular milled area may be formed with a circular annular width, such as the surface portion 11 'of the area shown in FIG.

The invention also comprises two milled surfaces of similar shape to the surface portion 11 in FIG. 4 joining an elongated surface intended for a joint with two bolts. Thus, it also includes a joint that is horizontally adjacent to each other and rotated by 90 °.

[Brief description of drawings]

FIG. 1 is a side view of a fuel channel and associated bottom portion for a nuclear fuel assembly of one embodiment of the present invention, including a partial vertical cross-section of the wall portion of the fuel channel, and FIG. FIG. 3A is a horizontal sectional view taken along line II-II of FIG. 3, FIG. 3A is a partial horizontal sectional view taken along line III-III of FIG. 1 of a joint in an unused fuel assembly at room temperature, and FIG. First joint of the same joint, but at elevated temperature, eg at reactor temperature
3 is a sectional view taken along line III-III of FIG. 4, FIG. 4 is a side view of a portion of the bottom portion shown in FIG. 1, and FIG. It is a figure. 1 ... Fuel channel, 3 ... Bottom part, 4 ... Bolt, 5 ... Central axis, 6 ... Bolt head, 7 ... Conical surface, 8 ... Conical surface, 9 ... Screw hole, 11 ... ... the surface part,
12 ... contact surface, 13 ... gap.

Claims (4)

[Claims] 1. A metal body (3) for a wall portion of a fuel channel (1) made of a zirconium alloy for a nuclear fuel assembly.
A fitting for fixing a metal body having a conical bolt head (6) and a central axis (5) extending longitudinally through a hole provided in the wall portion. 3)
A bolt (4) arranged to press the wall portion against a contact surface (12) formed in the bolt, the bolt (4) having a coefficient of thermal expansion greater than that of the zirconium alloy. The bolt head (6) such that the annular conical surface (7) of the bolt head (6) contacts the corresponding conical surface (8) of the hole at room temperature. In the joint, embedded in the wall part, the metal body (3) has a surface part (11) facing the wall part, the surface part (11) being Located near the bolt head (6) and distributed around the bolt (4), the surface portion (11) also has the central axis relative to the contact surface (12). Is displaced in the direction of (5), and the wall portion and the gold Coupling characterized in that a gap (13) is defined between it and the metal body (3). 2. The joint according to claim 1, wherein the metallic body (3) is the bottom part of a nuclear fuel assembly, the upper part of the bottom part being almost free of play. Around the lower part of the fuel channel (1), and the bolt (4) is screwed into a screw hole (9) provided in the upper part of the bottom part and oriented horizontally. A joint characterized by that. 3. The joint according to claim 2, wherein the shortest distance (E) between the inner wall surface of the fuel channel (1) and the threaded portion of the bolt (4). ) Is the largest diameter (D) of the bolt head (6)
A joint characterized by being smaller. 4. The joint according to claim 2, wherein the bolt (4) is made of a material whose coefficient of thermal expansion exceeds the coefficient of thermal expansion of the zirconium alloy by at least 50%. A joint characterized in that