KR101291164B1 - Couplant treating device for ultrasonic test - Google Patents

Abstract

The present invention relates to an apparatus for treating ultrasonic contact with a turbine rotor, wherein a wedge unit is processed by treating a contact medium (liquid, such as water), which is used when inspecting whether damage is made in a product or material such as a turbine rotor by ultrasonic inspection. An apparatus for treating a contact medium supplied to 1), comprising: a filter (20) for removing foreign matter in a contact medium; A storage tank 30 positioned downstream of the filter 20 to store the contact medium passing through the filter 20; A bubble removing tank (50) installed downstream of the reservoir (30) to remove bubbles from the contact medium supplied from the reservoir (30); First and second valves 40 installed at inlets and outlets of the reservoir 30 and controlled to be opened and closed to maintain a constant level of the bubble removing tank 50; The filter 20, the storage tank 30, the bubble removing tank 50, and the first and second valves (40, 60) to connect the pipe 10 is characterized in that it consists of.
By the above configuration, the present invention can ensure the accuracy and reliability of the inspection by supplying the foreign matter and bubbles are removed at the same time while maintaining a constant flow rate and pressure of the contact medium supplied to the wedge unit.

Description

Turbine Rotor Ultrasonic Testing Media Treatment System {COUPLANT TREATING DEVICE FOR ULTRASONIC TEST}

The present invention relates to an apparatus for processing ultrasonic contact medium for a turbine rotor, and more particularly, damage to a product or material by using a fluid such as water as a contact medium when ultrasonically inspecting a product or a material such as a turbine rotor for power generation. When inspecting the presence and absence of foreign matter and bubbles from the contact medium (fluid, such as water) supplied to the wedge unit, and by supplying the contact medium at a constant flow rate and pressure to acquire a stable and more accurate flaw detection signal during ultrasonic inspection It relates to a turbine rotor ultrasonic flaw detection apparatus for enabling.

A turbine is a device that converts thermal energy of high temperature and high pressure steam supplied from a heat source such as a boiler or a steam generator of a nuclear power plant into mechanical energy (rotary energy), which is essential for producing electricity in nuclear power plants and thermal power plants. It is one of the component parts.

Such turbines comprise one or more rotors (rotors), which are divided into high, medium and low pressure rotors, which are generally arranged on one axis of rotation.

The rotor is composed of rows in which a plurality of blades are arranged radially about the axis of rotation about the axis of rotation (rotor wheel), and a plurality of such blade rows are arranged in the longitudinal direction of the axis of rotation, and are fastened to the axis of rotation. The high pressure steam collides at a high speed, and the rotor has a large rotational force.

Methods of fastening a plurality of blades to a rotating shaft (rotor wheel) include a fine tree dovetail, an axial entry dovetail, and a pinned finger dovetail.

In particular, the low pressure rotor uses low pressure steam, so that a relatively large blade is fastened and installed on the rotor wheel. Thus, the low pressure rotor has a complex structure in which a blade of the low pressure rotor is firmly installed on the rotor wheel. The coupling structure is provided in the rotor wheel, and the rotor wheel of the final stage is formed with a fastening hole through which a pin is inserted into the lower surface of the blade to insert the blade to the rotor wheel more firmly. More than a thousand are formed per rotor.

Turbine rotors with such a complicated structure are operated while continuously friction with high-temperature, high-pressure steam, which may cause creep and fatigue damage, and corrosion cracking due to water vapor. The rotor must be checked for damage and safety.

According to domestic and international data, about 30% of the total cracks generated in the turbine rotor are generated in the blade roots and pins. Therefore, the damage of the turbine rotor should be regularly checked. It is most preferable to carry out after dismantling the blade from the rotor, but in this case, it takes a lot of time to disassemble and assemble the blade, and it is usually performed by non-destructive inspection in the fastened state because the blade must be rebalanced after reassembly. .

On the other hand, in the case of a large turbine rotor is a weight of more than 100 tons because the inspection must proceed in a state in which both ends of the rotor is stably supported using a turning roller, the inspection direction is limited.

In addition, blade roots such as Pine Tree Dovetail and Axial Entry Dovetail can be inspected externally by visual inspection, magnetic particle inspection, eddy current inspection, penetration inspection, etc. In the case of the pinned finger dovetail that connects the blade root to the pin, the pin is the weakest structurally and must be periodically inspected, but the internal structure of the dovetail is complicated and the diameter is about Ultrasonic signal due to poor contact surface conditions for the inspection due to pinning traces and irregularities in assembly due to pinning traces fixed to the pins and narrow contact area due to only exposed ends of the pins. Is difficult to acquire and interpret automatically. So far, the ultrasonic test on the pin part is performed by manual ultrasonic There is a situation.

In this way, when the ultrasonic flaw detection is carried out by a manual method, the reliability of the test is completely determined by the inspector's capability, etc., and the history management between the flaw detection results by inspection cycle is virtually impossible.

Therefore, the applicant proposes a device that can automatically and efficiently inspect the root surface of the turbine blade by the gap method and registered as patent No. 10-0901964 (blade root automatic ultrasonic wedge set). I have received it.

However, the above ultrasonic flaw detection device exhibits high accuracy of inspection accuracy and reliability even when the surface of the inspection object is flat or less than a certain level (the level that does not interfere with the movement of the wedge wing 200 in which the ball is mounted). In the case of (Pin), air is collected between the wedge and the subject or excessive gap is obtained under conditions in which pinning marks or excessive unevenness on the assembly surface exist to fix the pin. There is also a problem in the stability of the ultrasonic signal.

One of the methods to solve the contact problem is the immersion ultrasonic scanning method, which is a method in which a subject is put in a water, which is a contact medium, to radiate ultrasonic waves. Since it is difficult to put the subject, a 'local immersion method' is used, in which the contact medium is sprayed only on the inspection target area.

Local invasion is a method of forming and inspecting a contact medium film by spraying a large amount of water on the surface of a subject at high speed, and can be easily applied even when irregularities are present on the surface of the subject, but the contact medium always has a constant flow rate and pressure. Not only must this be supplied, but if foreign matter or bubbles are included in the contact medium, the ultrasonic signals may become unstable, thereby reducing the reliability of the test results.

The present invention has been made to solve the problems of the prior art as described above, the present invention is to supply a contact medium to the wedge unit used when inspecting the product or material, such as a turbine rotor for power generation by the ultrasonic flaw detection method It is an object of the present invention to provide an ultrasonic flaw detection medium treatment apparatus that can remove foreign substances and bubbles that may exist in the contact medium and supply a contact medium with a constant flow rate and pressure.

An object of the present invention as described above is an ultrasonic flaw detection medium processing apparatus, a filter for removing foreign matter in the contact medium; A storage tank located downstream of the filter and storing the contact medium passing through the filter; A bubble removing tank installed at a downstream side of the reservoir to remove bubbles from the contact medium supplied from the reservoir; First and second valves installed at inlets and outlets of the reservoir to be opened and closed to maintain a constant level of the bubble removing tank; And a pipe connecting the filter, the reservoir, the bubble removing tank and the first and second valves.

At this time, the inlet and outlet of the filter is provided with a differential pressure switch, the first and second valves may be implemented to control the opening and closing operation by the differential pressure switch.

In addition, the bubble removal tank is provided with a level switch, the first and second valves may be implemented by the opening and closing operation is controlled by the level switch.

In addition, the bubble removal tank is provided with an inlet and an outlet, respectively, the outlet may be implemented to be formed at a position relatively lower than the position of the inlet.

According to the present invention, when inspecting for damage to the products and materials such as turbine rotor by ultrasonic flaw detection, foreign matter and bubbles are removed while maintaining the constant flow rate and pressure of the contact medium supplied to the wedge unit. By supplying the contact medium in this state, the accuracy and reliability of the inspection can be ensured.

1 is a block diagram showing an example of an ultrasonic flaw detection medium processing apparatus according to the present invention.

Hereinafter, the configuration of the present invention through the accompanying drawings showing a preferred embodiment in more detail.

The present invention relates to a contact medium treatment apparatus for processing and supplying a contact medium to the ultrasonic flaw detection unit (1), the present invention as shown in Figure 1 pipe 10, filter 20, reservoir 30 ), The first valve 40, the bubble removing tank 50 and the second valve (60).

The filter 20 is a device for increasing the reliability of the ultrasonic signal by removing foreign matters and the like contained in the contact medium supplied to the wedge unit 1 along the pipe 10. Is installed.

In addition, an opening and closing valve is provided at each inlet and outlet of the pair of filters 20, whereby when the filter 20 is blocked by foreign substances, the use of one filter can be blocked and the other filter can be used without stopping the operation. The filter can be replaced.

A reservoir 30 is provided downstream of the pair of filters 20, and the first and second valves 40 and 60 are provided at the inlet and outlet of the reservoir, respectively.

Since the reservoir 30 is installed downstream of the filter 20, when foreign matter accumulates and is blocked in the filter 20, the flow rate of the contact medium flowing into the reservoir 30 may be reduced. The height of the contact medium inside the bubble removing tank 50 is not kept constant. As a result, the back pressure applied to the wedge unit is changed by the head of the bubble removing tank 50 so that the pressure of the contact medium supplied to the wedge unit and The flow rate is not kept constant, and as a result, the stability of the ultrasonic signal is impaired.

Therefore, in the present invention, by installing a differential pressure switch (not shown) in front and rear of the filter 20, opening and closing of the first and second valves 40 and 60 according to the pressure before and after the filter 20 detected by the differential pressure switch. By controlling the amount in conjunction with the differential pressure switch to maintain the height of the contact medium stored in the bubble removing tank 50 at a constant height at all times.

The contact medium introduced into the reservoir 30 is supplied to the bubble removing tank 50 located downstream of the reservoir 30 in a state where the flow rate is controlled through the first valve 40 and the second valve 60. do.

The bubble removing tank 50 is provided with an inlet 51 and an outlet 52, respectively, and the inlet 51 is a bubble removing tank 50 so that the outlet 52 is located at a relatively lower position than the inlet 51. ) Is installed at the upper side, the outlet 52 is installed at the lower side in the bubble removing tank 50, whereby bubbles that may be present in the contact medium is easily raised to the upper surface of the bubble removing tank 50 is removed, As a result, bubbles are hardly present in the contact medium supplied to the wedge unit 1 through the outlet 52.

In the above, the differential pressure switch is installed at the front and rear ends of the filter 20 and the opening and closing of the first and second valves 40 and 60 is controlled according to the pressure before and after the filter 20 detected by the differential pressure switch. Although the water level of the contact medium stored in the 50 has been described to be maintained at a constant height, the level switch 31 for detecting the level of the contact medium in the bubble removing tank 50 as shown in FIG. And controlling the opening and closing of the first and second valves 40 and 60 in conjunction with the signal of the level switch 31 to maintain the level of the contact medium of the bubble removing tank 50 constant. .

The pair of filters 20, the reservoir 30, the bubble removing tank 50, and the first and second valves 40 and 60 are connected to each other by a pipe 10, and the outlet of the bubble removing tank 50 is connected to each other. Is again connected to the wedge unit by the pipe 10 is injected to the surface of the subject by the injector.

As described above, the present invention is to maintain the flow rate and pressure of the contact medium supplied to the wedge unit at the same time by inspecting the damage in the product or the material by the ultrasonic flaw detection, while supplying the foreign matter and bubbles are removed The accuracy and reliability of the test can be ensured.

10: piping 20: filter
30: reservoir 31: water level sensor
40: first valve 50: bubble removing tank
51: inlet port 52: outlet port
60: second valve

Claims (5)

In the contact medium processing apparatus for supplying the processing of the contact medium to the wedge unit (1) used when inspecting the damage in the product or material by ultrasonic flaw detection,
A filter 20 for removing foreign substances in the contact medium;
A storage tank 30 positioned downstream of the filter 20 to store the contact medium passing through the filter 20;
A bubble removing tank (50) installed downstream of the reservoir (30) to remove bubbles from the contact medium supplied from the reservoir (30);
First and second valves 40 installed at inlets and outlets of the reservoir 30 and controlled to be opened and closed to maintain a constant level of the bubble removing tank 50;
The filter 20, the storage tank 30, the bubble removing tank 50 and the first and second valves (40, 60) made of a pipe 10 for connecting,
A differential pressure switch is provided at an inlet and an outlet of the filter 20, and opens and closes the first and second valves 40 and 60 by interlocking with the differential pressure switch according to the pressure before and after the filter 20 detected by the differential pressure switch. The amount is controlled so that the level of the contact medium stored in the bubble removing tank 50 is always maintained at a constant height,
Each of the bubble removing tank 50 is provided with an inlet 51 and an outlet 52, respectively, wherein the outlet 52 is formed at a position relatively lower than the position of the inlet 51. Experimental contact media processing device.
delete delete delete The method according to claim 1,
The filter rotor is characterized in that the pair consisting of a turbine rotor ultrasonic flaw detection apparatus, characterized in that a pair.

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