JPS62170883A - Control-rod drive mechanism - 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 [Technical Field of the Invention] The present invention improves a ball check valve that is disposed in a drive water flow path for control rod insertion and switches drive water, thereby reducing the radiation dose due to cobalt-60. This invention relates to a control rod drive mechanism (hereinafter referred to as CRD) that attempts to restrict the rate increase.

[Technical background of the invention and its problems] The ball check valve, which is placed in the driving water flow path for inserting control rods in the conventional CRD and switches the driving water, is made of a cobalt base metal (Hainstellite) containing approximately 50% cobalt. It is composed of (referred to as). The reason why cobalt is contained here is mainly to improve corrosion resistance.

However, when used for a long period of time, wear products or corrosion products are brought into the reactor by running water, and the cobalt in these products is irradiated with neutrons and becomes cobalt-60, which has a long half-life. This will increase the radiation dose rate at nuclear power plants. Moreover, if cobalt-60 accumulates, it will increase the radiation exposure of workers during periodic inspections, which is not a good thing for those trying to maintain safety, and furthermore, it will reduce the operating rate of the plant. There are also concerns.

[Object of the Invention] The present invention has been made based on the above points, and its purpose is to eliminate various problems caused by zero cobalt without losing the function of the ball check valve as well as the conventional characteristics. The objective is to provide a control rod drive mechanism capable of

[Summary of the invention] That is, the control rod drive mechanism according to the present invention inserts the control rod connected to the upper end of the piston into the reactor core by supplying driving water from the control rod insertion driving water flow path to raise the piston. At the same time, the control rods are withdrawn from the reactor core by supplying driving water from the drive water flow path for control rod withdrawal and lowering the piston (in the control rod drive [13], the drive water arranged in the drive water flow path for control rod insertion is The ball check valve that performs this switching is characterized by being made of a high-hardness precipitation-hardening nickel-chromium alloy.

In other words, by constructing the ball check valve from a high-hardness precipitation-hardening nickel-chromium alloy, an increase in the radiation dose rate due to cobalt-60 is attempted to be suppressed.

[Embodiments of the invention] An embodiment of the present invention will be described below with reference to the drawings.

The figure is a sectional view showing the schematic structure of the CRD, and the reference numeral 1 in the figure is
is the CRD housing. This CRD housing 1 is fixed to the bottom part 2 of the reactor pressure vessel by welding.

The CRD main body β- is inserted into the CRD housing 1, and the 7 langes 1a of the CRD housing 1 and the CRD
It is fixed by seven flange joints with the flange 3a of the main body β-.

A thermal sleeve 4 is installed concentrically within the CRD housing 1, and a cylinder tube 5 is installed concentrically on the inner peripheral side of the thermal sleeve 4. An index tube 6 is installed concentrically and movably up and down on the inner circumference of the cylinder tube 5, and a piston tube 7 is arranged concentrically on the inner circumference of the index tube 6. A drive piston 8 is formed at the lower end of the index tube 6, and a coupling mechanism 9 is constructed at the upper end, and a control rod 10 is connected via this coupling mechanism 9. Further, a stop piston 11 is formed at the upper end of the piston tube 7. A collet piston 12 is installed at the top of the cylinder tube 5, and the collet piston 12
A collet finger 13 is formed on. Reference numeral 14 in the figure is a collet spring. In the figure, numeral 15 is a control rod guide tube, numeral 16 is a guide cap, and numeral 17 is an outer filter.

A control rod insertion boat 21 and a control rod extraction port 22 are formed in the flange 1a, respectively.

The control rod insertion boat 21 has a drive water channel 23 for control rod insertion.
This control rod insertion drive water flow path 23 communicates with the lower surface side of the drive piston 8. On the other hand, the control rod withdrawal boat 22 is connected to a control rod withdrawal drive water flow path 24 , and the control rod withdrawal drive water flow path 24 is connected to the inside of the piston tube 7 . Valve seats 25a and 25b are formed in the middle of the drive water flow path 23 for control rod insertion, respectively, and a ball check valve 26 is installed between these valve seats 25a and 25b.

In the above configuration, when pulling out the control rod 10 first,
Driving water is supplied from the control rod insertion boat 21. This driving water acts on the lower surface side of the drive piston 8 via the driving water flow path 23 for control rod insertion.

The action of this driving water causes the drive piston 8 and index tube 6 to rise, and as a result, the control rod 10 is inserted into the reactor core. At this time, the ball check valve 26 is pressed against the valve seat 25a by the driving water. The flow of driving water is shown by solid arrows.

Next, when withdrawing the control rod 10, driving water for withdrawal is supplied from the control rod withdrawal boat 22 as indicated by the broken line arrow in the figure. This drive water for withdrawal is supplied to the drive water flow path 24 for control rod withdrawal.
It flows into the piston tube 7 through the opening 27 formed in the piston tube 7, flows between the piston tube 7 and the index tube 6, and acts on the upper surface side of the drive piston 8. - A portion of the drive water for shoplifting moves the collet piston 12 upward through the flow path 28. As the collet piston 12 rises, the collet fingers 13 are expanded and the holding of the index tube 6 is released. As a result, the drive piston 8 and the index tube 6 descend, and the control rod 10 is withdrawn. At this time, the ball check valve 26 is pressed against the valve seat 25a by the driving water.

Next, the case of emergency reactor shutdown (hereinafter referred to as scram) will be explained. In this case, high-pressure water is first supplied from inside the furnace as shown by the dashed-dotted line arrow in the figure, and acts on the lower surface side of the ball check valve 26 through the flow path 29. As a result, the ball check valve 26 is pressed against the upper valve seat 25b. The high-pressure water then acts on the lower surface of the drive piston 8 through the control rod insertion driving water flow path 23, and as a result, the control rod 10 is urgently inserted into the reactor core via the drive piston 8 and the index tube 6. Ru. In addition to using reactor water as a scram method, there is also a method of supplying high-pressure driving water from the control rod insertion boat 21.

Next, the ball check valve 26 will be explained.

The ball check valve 26 is composed of a nickel-chromium alloy consisting of 38% by weight chromium, 3.8% by weight aluminum, and the balance nickel and incidental impurities. That is, by constructing the ball check valve 26 from a nickel-chromium alloy that does not contain cobalt and has excellent corrosion and wear resistance, an increase in the radiation dose rate due to cobalt 60 is suppressed.

Therefore, the characteristics of the conventionally used ball check valve made of Haynes Stellite and the ball check valve 26 of this embodiment having the above structure are compared as shown in Table 1 below.

As is clear from Table 1, when the nickel-chromium alloy according to this example is used, although the specific gravity is lower than that of the cobalt-based alloy, it has a lower specific gravity than the cobalt-based alloy in terms of Young's modulus, tensile strength, and hardness. Same as base alloy. Next, regarding wear resistance, wear resistance is determined by mechanical properties, especially hardness, and as mentioned above, hardness remains the same as before, so when using a cobalt-based alloy It can be seen that the wear resistance is equivalent to that of Next, let's consider the chemical properties. Regarding this point, 20%N
aCj2.5%NH408,5%H2804,5%CH
It has been confirmed through experiments that no change occurred even after immersion in solutions such as 3C0OH and artificial sweat at room temperature for 72 hours continuously. As described above, it has excellent corrosion resistance.

According to this embodiment, the following effects can be achieved.

(1) First, the ball check valve 26 is made of a cobalt-free nickel-chromium based alloy consisting of 38% by weight of chromium, 3.8% by weight of aluminum, and the balance being nickel and incidental impurities. The base alloy has excellent corrosion and wear resistance. Therefore, the amounts of corrosion products and wear products are at or below the conventional level, and since they do not contain cobalt, the above products flow into the reactor, and the cobalt is irradiated with neutrons. This results in cobalt-60, and the problem that this cobalt-60 increases the radiation dose rate can be effectively solved. Therefore, it is possible to reduce the radiation exposure of workers during periodic inspections and improve the operating rate of the plant.

(2) Next, since the specific gravity of the ball check valve 26 is reduced, the operation time of the ball check valve is shortened, and the operation can be switched smoothly.

It should be noted that the present invention is not limited to the above embodiments, but chromium in a range of 30 to 45% by weight, aluminum in a range of 2.5 to 5% by weight, and the balance being nickel and incidental impurities. If it exists, it can fully perform its function as a ball check valve.

[Effects of the Invention] As detailed above, according to the control rod drive mechanism according to the present invention, it is possible to effectively control the increase in radiation dose rate due to cobalt-60 without losing the function as a ball check valve. This has great effects, such as reducing the radiation exposure of workers during periodic inspections and improving safety.

[Brief explanation of drawings]

The figure is a sectional view of a control rod drive mechanism showing an embodiment of the present invention. 1... Control rod drive mechanism housing (CRD housing), β-... Control rod drive mechanism body (CRD body), 6
... Index tube, 8 ... Drive screw 1
10... Control rod, 21... Control rod insertion port, 22... Control rod extraction boat, 23... Drive water flow path for control rod insertion, 24... Drive water flow for control rod extraction Road, 2
6...Ball check valve

Claims (2)

[Claims] (1) The control rod connected to the upper end of the piston is inserted into the reactor core by supplying driving water from the drive water flow path for control rod insertion to raise the piston, and the drive water is supplied from the drive water flow path for control rod withdrawal. In a control rod drive mechanism that pulls out a control rod from a reactor core by supplying water and lowering the piston, the ball check valve, which is arranged in the drive water flow path for inserting the control rod and switches the drive water, is made of highly hard deposits. A control rod drive mechanism characterized by being made of hardened nickel-chromium alloy. (2) The above nickel-chromium alloy has a chromium content of 30 to 4
2. The control rod drive mechanism according to claim 1, wherein the control rod drive mechanism comprises 5% by weight of aluminum, 2.5 to 5% by weight of aluminum, and the balance consisting of nickel and incidental impurities.