KR100445576B1 - Rotating electrode apparatus for flow-accelerated corrosion test - Google Patents

Abstract

The present invention relates to a immersion test rotary electrode device, the rotor 30 and the magnetic motor 20 is installed in the interior of the autoclave 10 to measure the corrosion sensitivity according to the rotation speed and the rotor ( It consists of a support 40 which receives the corrosion signal and stably transmits it to an external measuring device while suppressing the vibration generated in 30). By varying the diameter of the rotating specimen 35, various velocity fields can be reproduced. It is possible to measure the effect of the corrosion rate according to the quantitative.

Description

Rotating electrode apparatus for flow-accelerated corrosion test

The present invention relates to an immersion test rotary electrode device for testing the corrosion degree of the power plant structure, in particular immersion type that can measure the corrosion behavior of metal materials induced by rotation by rotating the electrode at a constant speed inside the autoclave It relates to an experimental rotary electrode device.

In general, there is a circulation loop for quantitatively testing the degree of corrosion of boiler structures, steam generator tubes, etc. of power plants. The circulation loop is divided into a low pressure part region and a high pressure part region. The low pressure part region is a region for storing / supplying test water and changing hydrochemical conditions, and includes a water supply tank, a supplemental water tank, and a sample tank. The high-pressure part is a region to which high temperature and high pressure of up to 300 ° C. and 200 atm is applied. The autoclave adjusts the pressure to a desired temperature and adjusts the pressure using a high pressure circulation pump that controls the flow rate or flow rate, and an attached heater. In addition to these, a pressure regulator, a high pressure heat exchanger, and a preheater are provided.

Conventionally, various auxiliary facilities are required to produce a high flow rate of about 8 to 12 kPa over the entire high-pressure region of the circulation loop, and in particular, the capacity of the high-pressure circulation pump has been increased. In addition, the existing circulation loop has a problem that can not smoothly rotate the experimental water in the extreme environment of 270 ℃, 150 atm and can not detect the corrosion phenomenon due to the additional flow.

Accordingly, the present invention is to improve the problems of the conventional circulation loop described above, and the object of the present invention is to simplify and reduce the experimental equipment of the high-pressure part by limiting the portion of the high-speed fluid flow to the autoclave.

Still another object of the present invention is to provide a immersion test rotary electrode device which can stably simulate the erosion phenomenon by generating a high flow rate even in an extreme environment of 270 to 300 ° C and 150 to 200 atmospheres.

In order to achieve the above object, the present invention, the rotating rod is connected to the magnetic motor, the rotating specimen coupled to the lower portion of the rotating rod via the housing and the disk, the part is exposed to the corrosion signal by bonding to the center of the lower surface of the rotating electrode A first signal transmission rod for transmitting downward, an insulation tube inserted into the first signal transmission rod so as not to be exposed to the experiment water, a support rod inserted into the insulation tube, and coupled to the lower portion of the housing; A rotating body disposed below the support rod and configured of a first insulating member configured to surround the first signal transmission rod; A guide groove into which the support rod is inserted, and a lower portion of which is fixed to the bottom of the autoclave, a second insulating member elastically supported by a spring under the guide groove of the support, and the second insulating member It is inserted in the center of the upper end includes a support consisting of a second signal transmission rods abutting the first signal transmission rods and a signal cable connected to the lower end.

The rotating specimen is preferably configured such that the circumferential surface is exposed to the test water so that corrosion occurs only at that part. And, it is preferable to configure to extract the corrosion signal of the rotating specimen from the axis center of the rotating body.

According to the immersion type experimental rotary electrode device according to the present invention, even by using a low-capacity high-pressure circulation pump by rotating the rotor connected to the magnetic motor in the interior of the autoclave, it is possible to obtain a high flow rate, It can receive the corrosion signal and send it to external measuring equipment stably while suppressing the vibration generated from the whole.

1 is a cross-sectional configuration of a rotating electrode device according to the present invention installed in an autoclave,

2 is a cross-sectional view showing a rotating body of the rotary electrode device according to the present invention;

Figure 3 is an exploded perspective view of separating the rotating specimen and the signal transmission rod of the rotary electrode device according to the present invention,

4 is a cross-sectional view showing a support of the rotary electrode device according to the present invention.

Explanation of symbols on the main parts of the drawings

10: autoclave 20: magnetic motor

30: rotating body 31: rotating rod

32 housing 33 disc

34: high information bolt 35: rotating specimen

36: first signal transmission rod 37: insulated tube

38: support rod 39: first insulating member

40: support 41: support

42: second insulating member 43: second signal cutting rod

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail.

1 is a cross-sectional configuration diagram of a rotary electrode device according to the present invention installed in an autoclave, and FIG. 2 is a cross-sectional view illustrating a rotating body of the rotary electrode device according to the present invention.

As shown in FIG. 1, the rotary electrode device according to the present invention is installed in a vertical direction in a state in which the rotor 30 and the support 40 are coupled to the inside of the autoclave 10, and the rotor ( 30 is connected to the magnetic motor 20 is configured to rotate.

As shown in FIG. 2, the rotating body 30 is coupled to a rotating rod 31 connected to the magnetic motor 20 through a housing 32 and a disc 33 at a lower portion of the rotating rod 31. And a part of which is exposed the rotating specimen 35, the first signal transmission rod 36, and the first signal transmission rod 36, which are connected to the center of the lower surface of the rotation specimen 35 to transmit a corrosion signal downward. An insulator tube 37 inserted into and not exposed to the test water, a support rod 38 inserted therein and coupled to a lower portion of the housing 32, and a lower portion of the support rod 38. And a first insulating member 39 disposed at and arranged to surround the first signal transfer rod 36.

The rotating rod 31 is coupled to the connecting member 21 of the magnetic motor 20 with the upper end inserted into the cover part of the autoclave 10, and the housing 32 covering the rotating specimen 35 at the lower end thereof. ) To the bolt as a medium. Here, the rotating rod 31 serves to connect the external magnetic motor 20 and the rotating specimen (35). In addition, the rotating rod 31 may be made of stainless steel having high corrosion resistance, and manufactured to have a diameter of about 14 mm to reduce the influence on the vibration phenomenon of the electrode at high speed.

The rotating specimen 35 is connected to the rotating rod 31 through the housing 32 and the disk 33 so that the circumferential surface thereof is exposed to the experimental water of the autoclave 10. Therefore, the rotating specimen 35 can grasp the degree of corrosion of the rotational flow in the experiment water of the autoclave 10. Here, the rotating specimen 35 is preferably configured such that only the circumferential surface is exposed to the test water so that corrosion occurs only at that portion. In addition, the rotating specimen 35 is preferably made of a cylindrical carbon steel material without changing the shape. Based on the diameter of the rotating specimen 35 of 70 mm, the flow field can be reproduced at a rotational speed of 1800 to 2500 rpm with a rotational linear speed of 8 to 12 kPa on the surface of the electrode. Of course, by changing the diameter of the rotating specimen 35 and increasing the rotational speed of the magnetic motor 20 can be obtained a larger velocity field.

The housing 32 is divided into an upper housing 32a for connecting the rotary rod 31 and a lower housing 32a for connecting the support rod 38, and the upper and lower housings 32a and 32b, respectively, The outside is screwed and connected. Here, the housing 32 is preferably made of a nonmetallic polymer resin. The disc 33 is fitted in the upper and lower housings 32 and a plurality of high information bolts 35 are coupled to each other while penetrating the housing 32 and the rotating specimen 35. Here, the disk 33 is made of a stainless material with high corrosion resistance to prevent deformation of the housing 32 in a high temperature state, it is possible to improve the airtightness to the coupling portion of the housing 32 due to thermal expansion. On the other hand, the waterproof sheet 33a is inserted between the rotating specimen 35 and the disk 33 to prevent direct penetration of the test water. An O-ring 33b is inserted into a portion where the disc 33 and the high information bolt 35 are connected.

The first signal transmitting rod 36 is coupled to the bottom surface of the rotating specimen 35 by a screwing method. In other words, as shown in FIG. 3, the first signal transmission rod 36 has a male screw 36a formed at an upper end thereof to be coupled to the female screw hole 35a formed in the rotating specimen 35. The first signaling rod 36 penetrates through the housing 32 and is in contact with the first signaling rod 36 of the support 40. Here, the first signal transfer rod 36 serves to transmit the corrosion signal of the rotating specimen 35 downward.

The insulator tube 37 has a first signal transfer rod 36 inserted therein so as not to be exposed to the test water. Insulating tube 37 is preferably made of the same non-metallic polymer resin as the housing (32). The first signal transmission rod 36 is inserted into the center of the insulator tube 37, while the insulator tube 37 is inserted into the center of the support rod 38, and the sealing of the insulator tube 37 is performed at a high temperature. It is preferable to use thermal expansion between the signal transfer rod 36 and the support rod 38.

The support rod 38 is such that the insulating tube 37 is inserted therein and coupled to the lower portion of the housing 32. The upper end of the support bar 38 is coupled to the housing 32 by a screwing method, and is firmly fixed to the side of the housing 32 by a fixing screw. Here, the support rod 38 serves to prevent damage to the rotating shaft due to vibration generated when the rotating specimen 35 rotates at high speed. The support rod 38 is preferably made of stainless steel having a high corrosion resistance and preferably manufactured with a diameter of about 14 mm.

The first insulating member 39 is disposed below the support rod 38 and surrounds the first signal transfer rod 36. Here, the first insulating member 39 serves to insulate the first signal transfer rod 36. As the first insulating member 39, it is preferable to use a material in which a heat resistance and abrasion resistance are mixed with a nonmetallic polymer resin and a ceramic.

As shown in FIG. 4, the support 40 has a guide groove 41a into which the support rod 38 is fitted, and a lower support 41 fixed to the bottom of the autoclave 10. A second insulating member 42 elastically supported by a spring 42a under the guide groove 41a of the support 41 and inserted into the center of the second insulating member 42 and having an upper end thereof The second signal transfer rod 43 is disposed in contact with the first signal transfer rod 36 and connected to the lower end of the signal cable 43a.

A guide groove 41a into which the support rod 38 of the rotating body 30 is fitted is formed at an upper portion of the support 41, and as shown in FIG. 1, at the bottom of the autoclave 10. It is fixedly installed. The support 41 serves to suppress the vibration generated from the rotating body 30 by inserting the support rod 38 into the guide groove 41a. The through hole is formed in the guide groove 41a of the support 41 to allow the signal cable 43a to pass therethrough. Here, the upper end of the support 41 is angularly processed so that the rotating body 30 can be easily separated from the support 40. It is preferable that the support 41 is made of stainless steel having high corrosion resistance.

The second insulating member 42 is elastically supported by a spring 42a at a lower portion thereof while being inserted into the guide groove 41a of the support 41, and is fixed to one side of the support 41 by a high information bolt. It is supposed to be.

The second signal transmitting rod 43 is inserted into the second insulating member 42 so that an upper end thereof comes into contact with the lower end of the first signal transmitting rod 36, and a signal cable 43a is provided at the lower end thereof. It is connected.

According to the configuration of the embodiment of the present invention, a high flow rate can be obtained by rotating the rotary body 30 axially connected to the magnetic motor 20 inside the autoclave 10, and is fixed to the lower portion of the autoclave 10 The stationary body 40 receives the corrosion signal and stably sends it to the external measuring equipment while suppressing the vibration generated from the rotating body 30.

According to the immersion test rotary electrode device according to the present invention as described above, it is possible to experiment by limiting the portion of the high-speed fluid flow to the autoclave unlike the conventional, greatly reducing the experimental cost by simplifying and lowering the experimental equipment You can do it. In addition, by varying the diameter of the rotating specimen to reproduce a variety of velocity fields it is possible to measure the influence of the corrosion rate according to the flow rate more quantitatively.

Claims (3)

The rotating rod 31 connected to the magnetic motor 20, the rotating specimen 35 coupled to the lower portion of the rotating rod 31 via the housing 32 and the disk 33, and partly exposed, the rotating specimen ( 35, a first signal transmission rod 36 for transmitting a corrosion signal downward and a first signal transmission rod 36 inserted therein so as not to be exposed to the test water. The insulation tube 37 is inserted into the support rod 38 and coupled to the lower portion of the housing 32, and installed below the support rod 38 to surround the first signal transmission rod 36. Rotator 30 composed of a first insulating member 39; A guide groove 41a into which the support rod 38 is fitted is formed at an upper portion thereof, and a support 41 is fixed to the bottom of the autoclave 10 and a lower portion of the guide groove 41a of the support 41. A second insulating member 42 elastically supported via a spring 42a, and is installed in the center of the second insulating member 42, and an upper end thereof contacts the first signal transmitting rod 36 and a lower end thereof. A support 40 composed of a second signal transfer rod 43 to which a signal cable 43a is connected; Submerged experimental rotary electrode device comprising a. The method of claim 1, The rotating specimen 35 is a immersion test rotary electrode device, characterized in that the circumferential surface is exposed to the test water so that corrosion occurs only in that portion. The method according to claim 1 or 2, Immersion test rotary electrode device, characterized in that to extract the corrosion signal of the rotating specimen 35 in the center of the axis of the rotating body (30).