JPS59105596A - Method of measuring power of spring disposed to side of web in lattice spacer of fuel assembly and plug gauge therefor - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a fuel rod spacer arranged on the side of a web in a lattice of a lattice spacer of a nuclear reactor fuel assembly to hold fuel rods containing nuclear fuel material in the lattice. This invention relates to a method for measuring the spring force of a compression spring used in a damper, and a plug gauge for a damper that implements this method.

The fuel rods undergo thermal expansion along their length within the nuclear reactor. Therefore, it is necessary for these fuel rods to be able to move freely at both ends in the reactor fuel assembly, and they are guided into the lattices of the lattice-shaped spacer of the reactor fuel assembly and compressed within these lattices. It must be held in place by a spring. Therefore, it is important that the compression springs in each grid of the grid spacer target the fuel rods with an appropriate predetermined spring force on their outer circumferential surface.

For this purpose, it is necessary to accurately measure the spring force of one compression spring in the lattice of the lattice spacer with respect to two contact surfaces as close as possible to the outer peripheral surface of the fuel rod.

According to the invention, in the method of the type mentioned at the outset, a plug gauge having a measuring element for measuring the spring force on its outer circumferential surface, the stopper body on the outside of the plug gauge is connected to a spacer. This is achieved by lifting the stop body from the spacer in order to be inserted into the grid until the compression spring is located exactly on the measuring element in contact with the measuring element and the spring force of the compression spring is measured on the measuring element.

The plug gauge has the same diameter as the fuel rod that will be placed later in the grid of the grid spacer, and will smear this fuel rod when measuring the spring force of the compression spring. The lattice spacer has an accurate insertion depth in the target lattice when measuring the stock in a plug gauge, and the measurement element accurately locates the top of the compression spring in the target lattice to measure the spring force. It acts as if it were captured.

By lifting the stopper body away from the spacer in order to measure the spring force of the compression spring, the generation of frictional forces between the stopper body and the spacer is avoided. This frictional force causes a large measurement error in the spring force measured by the measuring element.

A suitable plug gauge for carrying out the method according to the invention is such that the stopper body is attached to a ring which is disposed longitudinally displaceably between two stop locations on the plug gauge. A chamber with a pressure medium supply line is formed between the ring having the stopper body and the ring having the stopper body, and a return spring acting between the plug gauge and the ring is attached to the ring having the stopper body. characterized.

The plug gauge can be easily inserted into each grid of the grid spacer, and the stopper body can be lifted from the spacer without changing the insertion depth of the plug gauge into the grid.

Furthermore, on the outer circumferential surface of the plug gauge, a measuring element for measuring the spring force is mounted on the piston, which is supported in the plug gauge so as to be movable between two stop locations at right angles to its longitudinal axis. Preferably, the plug gauge is placed in such a way that a chamber with a pressure medium supply line is formed between the plug gauge and the piston.

The present invention will be described in detail below based on two embodiments shown in the drawings.

The plug gauge 2 in FIG. 1 has the shape of a rod and is arranged with its longitudinal axis 3 vertical. The lower end of the plug gauge 2 is located within the lattice 4 of the lattice spacer of the reactor fuel assembly.

The lattice-like spacer has strip-like webs 5 and 6 made of zirconium-soot alloy intersecting each other at right angles and arranged with the ridges facing down.

Each web 5 and 6 has on one side a generally V-shaped compression spring 7 arranged in a first grid 4 and on the opposite side of this web two papillary projections 8 adjacent to each other. It is arranged in the second lattice 4. All projections 8 are installed at the same height. Two protrusions 8 are attached to the webs 6 or 5 on a center line parallel to the longitudinal direction of the lattice 4 between the two webs 5 or 6.

On this center line, in each case on opposite sides of this web, a compression spring 7 is arranged between the two projections 8.

A measuring element 9 for measuring the spring force of the compression spring 7 is fitted into the outer peripheral surface of the end of the force-measuring plug gauge 2 which is intended for insertion into the grid 4. This measuring element 9 precisely captures the compression spring 7 at its apex in its center. For example, a flat piezoelectric element with electrical connection terminals is used as measuring element 9.

A ring 10 is placed concentrically with respect to the axis 3, and this ring 10 has a longitudinal axis 3 and a ring 1 on its outer circumferential surface.
It has a stopper body 11 that is elongated and extends parallel to the zero axis. This stopper body 11 protrudes from the end surface of the ring 10 on the measuring element 9 side, and
or the upper edge of the web 6.

A screw 12 is provided at the upper end of the plug gauge 2, and a grip 13 having a hollow cylindrical shape at one end is attached to the screw 1.
It is screwed into 2. The ring 10 is located between the grip 13 and a step 14 on the outer peripheral surface of the plug gauge 2 when viewed in the direction of the longitudinal axis 3.

The step 14 on the one hand and the grip 13 on the other hand form two stop points on the plug gauge 2, between which the ring 10 can be moved back and forth in the direction of the longitudinal axis 3 of the plug gauge 2. .

A return spring 15 is placed in the grip 13 relative to the longitudinal axis 3. The return spring 15 abuts against and supports the grip 13 and the end surface of the ring IO on the grip side, and presses the ring 10 toward the stepped portion 14.

Viewed in the direction of the longitudinal axis of the ring 10, which coincides with the longitudinal axis 3, the inner circumference of the ring 10 is made so that the inner diameter of the part of the ring 10 on the grip side is smaller than the inner diameter of the part of the ring 10 on the side of the measuring element 9. A step portion 16 is formed on the surface. Correspondingly, a stepped portion 17 is also formed on the outer peripheral surface of the plug gauge 2 inside the ring 10. This step 17 is the ring 1
An annular chamber 20 is formed between the plug gauge 2 and the ring 10 together with a step 16 on the inner peripheral surface of the plug gauge 2 . This annular chamber is hermetically sealed from the outside by two O-rings 18, 19 fitted onto the inner peripheral surface of the ring 10 concentrically with the longitudinal axis of the ring. A supply line 21 for a pressure medium, for example compressed air, which is provided in the plug gauge 2 and the handle 13, leads into the annular chamber 20 formed by the step 16, 17.

When the plug gauge 2 is inserted into the grid 4, the stopper body 11 finally hits the upper edge of the web 5 or web 6 of the grid spacer, and the plug gauge 2 detects the measuring element when the top of the compression spring 7 is under the pressure F1. The insertion depth into the grid mesh 4 is reached exactly such that it acts on the center of the mesh 9. Then this spring force F.

Compressed air is supplied to the supply pipe 21 to measure the
The ring 10 is pressed against the action of the return spring 15 against the grip 13 on the plug gauge 2. This allows the stopper body 11 to be held from the lattice spacer without changing the insertion depth of the plug gauge 2 into the lattice 4.
I can get two. The new position of the stopper body 11 is indicated by a dashed line in FIG. In this new position, the generation of a frictional force F4 between the stopper body 11 and the spacer is avoided, and the plug gauge 2 comes into contact with all the protrusions 8 in the lattice 4, which are the hindrance. This means that the outer diameter D of the plug gauge 2 is important for accurately measuring the spring force F1 of the compression spring 7 (same as the outer diameter of the fuel rod to be inserted later into the target grid 4). act precisely during the measurement of the spring force F1, and the two projections 8 located on opposite sides of the compression spring 7
The reaction force F2+F3' (is exactly F2=F3=l/2Fl
It means that.

By lifting the stopper body 11 to measure the spring force F1, the measurement error of the spring force F1 can be improved from 3% to 0.3%.

The plug gauge 2, which is shown in FIG. 2 with the same reference numerals j- for the same parts as in FIG. It differs from the plug gauge 2 in FIG. 1 in that it is placed on a piston 25 which is supported. The piston 25 has a pot 26 with a large outer diameter on the outer peripheral surface of the piston 25 at its end located within the plug gauge 2. This pot 26 is 28 mm with respect to the longitudinal axis 3.
A piston 25 is located between the pots 26 and 26 and engages with the bottom of the pot 26. A chamber 29 is formed between the piston 25 and the bottom of the hole 24 and has a pressure medium supply line 30 provided in the plug gauge 2 . This chamber is sealed by an O-ring 31 concentric with the piston 25, which is fitted into the outer peripheral surface of the piston 25.

When the plug gauge 2 is inserted into the grid 4, the compression spring 7 easily pushes the piston 25 back into the plug gauge 2 as far as the step 27 forming the first stop point for the piston 25. Can be done. The plug gauge 2 can thereby be inserted particularly easily into the grate 4, for example by means of a downward movement.

In order to measure the spring force F1 with the plug gauge 2 based on FIG. is also pressed towards the step 28, which together with the pressure guide pot 26 forms the second stop point 1-, so that the measuring element 9 is precisely aligned with the outer peripheral surface of the plug gauge 2 in order to measure the spring force Fl. As a result, measurement errors no longer occur.

[Brief explanation of drawings]

FIG. 1 is a partially cross-sectional side view of a plug gauge according to the present invention in the lattice of a lattice spacer of a nuclear reactor fuel assembly, and FIG. 2 is a part of another embodiment of the plug gauge in FIG. 1. FIG. 3 is a cross-sectional side view. 2 nib lag gauge, 3: longitudinal axis, 4: lattice,
5, 6; Web, 7: Compression spring, 9: Measuring element,
10: Ring, 11: Stopper body, 13, 14
: step part, 20: chamber, 21: compressed medium supply pipe,
25: Piston, 27° 28: Step, 29; Chamber,
30: Compressed medium supply pipe line.

Claims (1)

[Claims] l) A measuring element for measuring spring force in a method for measuring the spring force of a compression spring arranged on the side of a web in a lattice of a lattice spacer of a nuclear reactor fuel assembly. (9) on its outer peripheral surface, the plug gauge (2) has a stopper body (1) on the outside of the plug gauge (2).
1) is inserted into the grid (4) until it contacts the spacer and the compression spring (7) is located exactly on the measuring element (9), transferring the spring force of the compression spring (7) to the measuring element (9). ) to measure the spring force of a compression spring disposed beside the web in the lattice mesh of a lattice-shaped spacer of a nuclear reactor fuel assembly characterized in that the stopper body (11) is lifted from the spacer. Method. 2) A plug gauge having a measuring element (9) on its outer peripheral surface for measuring the spring force of a compression spring placed on the side of the web in the lattice of the lattice spacer of the reactor fuel assembly. (2) until the stopper body (11) on the outside of this plug gauge (2) contacts the spacer and the compression spring (7) is accurately positioned on the measuring element (9). The stopper body (11) is inserted into the plug gauge and carries out the method in such a way that the stopper body (11) is lifted from the spacer in order to measure the spring force of the compression spring (7) with the measuring element (9). 11) is attached to a ring (10), which is attached to the two stopper points (13) on the plug gauge (2) in the direction of the longitudinal axis (3) of the upper knee t- of the plug gauge (2). ;
14), and a chamber (20) with a pressure medium supply conduit (21) is formed between the plug gauge (2) and the ring (10) with the stopper body (11). A plug gauge characterized in that a ring (10) having a stopper body (11) is attached with a return spring (15) that acts between the plug gauge (2) and the ring (10). 3) A plug having a measuring element (9) on its outer peripheral surface in order to measure the spring force of the compression spring arranged on the side of the web in the lattice of the lattice spacer of the 1 reactor fuel assembly. The gauge (2) is placed in the grid (4) until the stopper body (11) on the outside of this plug gauge (2) contacts the spacer and the compression spring (7) is located exactly on the measuring element (9). In order to measure the spring force of the compression spring (7) with the measuring element (9), the stopper body (11) is inserted into the pressure medium supply pipe (30) with a spacer (3) between the stopper body (11) and the spring force of the compression spring (7) with the measuring element (9). In a plug gauge that implements the method for lifting from the chamber, a stopper body (11) is attached to a ring (10), and this ring (10) is placed above the plug gauge (2) with its longitudinal axis ( A ring (10) with a plug gauge (2) and a stopper body (11) is movably placed between the two stopper locations (13:14) on the plug gauge (2) in the direction of 3). A pressure medium supply pipe (21
) is formed, and a plug gauge (2) and a ring (
A return spring (15) is attached that acts between the plug gauge (2) and a measuring element (9) that measures the spring force on the outer circumferential surface of the plug gauge (2). Two stopper locations (
27; 28) is movably supported between the pistons (
25), and the plug gauge (2) and piston (
25) (4) When the pressure is shifted as far as possible toward the dot-shaped contact cylinder (29
) is formed.