KR101439751B1 - Apparatus for erosion-corrosion test in aqueous slurry environment - Google Patents

Abstract

A device to perform a corrosion and wear test in a slurry comprises: a chamber in which slurry is stored; and a driving part capable of rubbing a test piece mounted to measure the corrosion and wear of the test piece caused by the slurry with the slurry by rotating the test piece in the slurry of the chamber, and adjusting an angle collided with the slurry particles. The present invention rubs the test piece with the slurry by rotating the test piece in the slurry of the chamber, and enables to control the angle collided with the slurry particles since one surface of the test piece forms a preset angle to the tangential direction of a concentric rotation circle in a rotational direction in accordance to the test conditions. Also, the present invention can prevent the edge of the test piece from being eccentrically corroded and worn since a fixing holder holds the test piece in a state of surrounding the edge of the test piece. Moreover, the present invention can control the slurry of the chamber to be at a set temperature while having a preset oxygen concentration in the corrosion, and wear test conditions using a temperature control part and a gas control part. Accordingly, the present invention can accurately and easily measure the corrosion and wear characteristics of the materials in a slurry environment in which an abrasive is mixed with fluid.

Description

[0001] Apparatus for erosion-corrosion test in aqueous slurry environment [

The present invention relates to a slurry corrosion wear tester, and more particularly, to a slurry corrosion wear tester for measuring corrosion and wear characteristics of a material under a slurry environment.

A variety of materials used in industrial environments are subject to corrosion or abrasion, or corrosion and abrasion at the same time, shortening the life of the material. Particularly, in the environment where corrosion and abrasion are present at the same time, corrosion and wear are mutually influenced to shorten the life of the material.

In this environment, evaluation of corrosion wear characteristics of materials is required for application of new steel, but it is difficult to evaluate characteristics of materials without applying to actual environment. In order to evaluate the corrosive wear characteristics of materials by simulating the actual environment, it is necessary to apply a test method that quantitatively evaluates the actual environment in accordance with the situation.

Methods designed to evaluate the erosion resistance of a material against conventional wear or corrosion include methods of evaluating abrasion resistance by flowing sand between a rotating rubber wheel and a specimen, sanding the specimen with a fixed angle, A method of evaluating the corrosion resistance of a material electrochemically, and the like.

However, since each of the above test methods does not use a slurry in which water and a wear material are mixed, there is a limit to evaluate simple wear and corrosion of the material. In order to overcome these disadvantages, a method of evaluating corrosion resistance by transferring a slurry simulating a real environment is applied to a laboratory pipe loop in the form of a small diameter pipe, but the equipment is expensive Furthermore, since the control is not easy, it is difficult to evaluate corrosion wear characteristics of various materials in the experimental results.

The conventional techniques proposed for evaluating the wear characteristics of a material in an environment containing moisture are mostly methods for evaluating the erosion resistance of the material in each representative environment and it is impossible to simulate various operating environments in a slurry environment.

As one example, the following techniques have been proposed so far.

Korean Patent Laid-Open Publication No. 2006-0011055 discloses that by injecting a mixed two-phase (vapor + liquid) fluid of steam and water into a test chamber through a steam generator under a high-temperature and high-pressure environment such as a steam generator of a nuclear power plant, And a test evaluation of the mechanical properties such as abrasion by the action can be performed in a steam / water mixed environment.

However, the method proposed in Korean Patent Publication No. 2006-0011055 is a technique for evaluating the abrasion resistance of a material in a high-temperature and high-pressure environment in which gas and solid exist, The corrosion wear characteristics of the material can not be evaluated.

An example of an apparatus for evaluating corrosion wear characteristics of a material is disclosed in Korean Utility Model Publication No. 91-12274, which is a method of artificially applying a potential to a rotating disk specimen loaded in an aqueous solution to evaluate corrosion wear characteristics to be.

However, since the method proposed in Korean Utility Model Publication No. 91-12274 uses a rotating disc specimen, it can not control the collision angle of particles with respect to the specimen and can not control the oxygen concentration or the use temperature. have.

The present invention has been made to solve the above problems and provides a slurry corrosion wear test apparatus configured to accurately and easily measure corrosion and wear characteristics of a material in a slurry environment in which a wear material is mixed with a fluid It has its purpose.

According to an aspect of the present invention, there is provided a slurry corrosion wear tester comprising: a chamber in which slurry is received; And a driving unit that rotates the test piece mounted to measure corrosion wear of the test piece by the slurry in the slurry in the chamber to adjust the angle of collision with the slurry.

At this time, the driving unit includes: a rotating plate on which the test piece is mounted; A driving motor connected to a power transmitting shaft extending upward from the rotating plate to rotate the rotating plate; And a fixing jig provided on the rotating plate while fixing the test piece, wherein an installation angle of the rotating plate is adjusted so that a collision angle of slurry particles with respect to a surface of the test piece is adjusted when the rotating plate is rotated.

Also, the driving unit may include a fixing holder having a fixing bolt for pressing the test piece with a coupling groove formed therein for receiving the test piece to hold the test piece while surrounding the rim of the test piece, and a fixing holder coupled to the fixing jig. As shown in FIG.

In addition, it is preferable that the depth of the fastening groove is formed so as to protrude from the fastening groove when the test piece is inserted into the fastening groove.

The driving unit may further include a motor controller for sensing and controlling the rotational speed of the driving motor.

According to another aspect of the present invention, there is provided a temperature sensor comprising: a temperature sensor mounted in the chamber for measuring a temperature of the slurry; A heating coil and a water-cooling jacket built in the chamber; And a temperature controller electrically connected to the temperature sensor, the heating coil, and the water-cooling jacket, respectively, for controlling the temperature of the slurry in the chamber.

The present invention also provides an oxygen concentration sensor mounted in the chamber for measuring the oxygen concentration of the slurry; A flow controller for controlling a flow rate of oxygen and nitrogen supplied to the transfer line extending into the chamber while the oxygen supply line and the nitrogen supply line are connected to each other; And a gas controller electrically connected to the oxygen concentration sensor and the flow rate controller, respectively, for controlling the gas concentration of the slurry in the chamber.

Further, the present invention may further include a side baffle and a lower baffle, respectively, formed on a side surface and a bottom surface of the chamber so as to block the rotation of the slurry by rotation of the driving unit.

In addition, the present invention may further include a cover mounted on the upper portion of the chamber to block inflow of outside air and moisture into the chamber.

The slurry corrosion wear tester according to the present invention is characterized in that the test piece is rotated in the slurry in the chamber to frictionally slurry the slurry on one side of the test piece in the rotational direction with respect to the tangential direction of the rotary concentric circle, So that the angle of collision with the slurry particles can be adjusted. Also, since the fixing holder is configured to hold the test piece while surrounding the rim of the test piece, it is possible to prevent the corrosion wear from being concentrated on the rim of the test piece.

Further, the present invention can control the slurry in the chamber to be the set temperature and oxygen concentration under the corrosion wear test condition of the test piece by the temperature control unit and the gas control unit.

Accordingly, it is possible to accurately and easily measure the corrosion and abrasion characteristics of the material in a slurry environment in which the wear material is mixed with the fluid.

1 is a schematic view showing a slurry corrosion wear test apparatus according to a preferred embodiment of the present invention.
Fig. 2 is a bottom view showing the lower part of the rotating plate in the slurry corrosion wear test apparatus of Fig. 1;
Fig. 3 is a perspective view showing that the test piece is held by the fixing holder in Fig. 2;

The slurry corrosion wear test apparatus of the present invention is a device for testing corrosion resistance and abrasion characteristics of a material in a slurry environment in which a wear material is mixed with a fluid by rotating the test piece in a slurry in a chamber to frictionally contact the slurry The edge of the test piece is wrapped around the edge of the test piece so that the angle of collision with the slurry particles can be adjusted to meet the condition and corrosion wear is prevented from being generated in the edge of the test piece in a concentrated manner. A temperature control unit and a gas control unit that can control the temperature and the oxygen concentration to be set to a predetermined temperature and an oxygen concentration.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic view showing a slurry corrosion wear test apparatus according to a preferred embodiment of the present invention, FIG. 2 is a bottom view showing a lower part of a rotary plate in the slurry corrosion wear test apparatus of FIG. 1, And is held by the fixed holder.

Referring to the drawings, the present invention includes a chamber 10 in which a slurry 1 is accommodated, and a driving unit for rotating the test piece 2 in the slurry 1 in the chamber 10.

The slurry (1) is, for example, an oil sand, seawater, water mixed with minerals, and the like. The chamber 10 in which the slurry 1 is accommodated has an open structure with the top opened before the slurry 1 is drawn into the chamber 10 through the open top before the corrosion wear test.

A cover 11 is mounted on the upper portion of the chamber 10. The cover 11 blocks the inflow of external air and moisture into the chamber 10. That is, when the slurry 1 is drawn into the chamber 10 through the open upper portion of the chamber 10, a cover (not shown) is formed on the chamber 10 to prevent external air and moisture from entering the chamber 10 during the test. (11) is mounted.

The driving unit has a function of rotating the mounted test piece 2 with the slurry 1 in the chamber 10 to rub against the slurry 1 so as to measure corrosion wear of the test piece 2 by the slurry 1 . At this time, the driving unit is configured to adjust the collision angle of the test piece 2 with the particles of the slurry (1).

Specifically, the driving unit may include a rotating plate 21 on which the test piece 2 is mounted, a driving motor 23 for rotating the rotating plate 21, and a fixing jig 26 provided on the rotating plate 21 have.

The test piece 2 is mounted on the lower portion of the rotary plate 21 and rotated so that the test piece 2 can be rotated with the slurry 1 while rotating.

At this time, when the chamber 10 has a cylindrical shape similar to that of the tube, the rotary plate 21 can take a disc-shaped structure corresponding to the shape of the chamber 10.

The drive motor 23 is configured to rotate the rotary plate 21. The drive motor 23 is connected to the power transmission shaft 22 extending upward from the rotary plate 21 so as to be interlocked with the rotary plate 21. [ At this time, the lower portion of the drive motor 23 can be coupled to the upper portion of the power transmission shaft 22 and the attachment / detachment portion 24, which is a detachable structure such as a flange.

The motor controller MC may be electrically connected to the driving motor 23. The motor controller MC has a function of sensing and controlling the rotational speed of the driving motor 23. [

Thus, the speed of collision of the test piece 2 with respect to the slurry 1 is adjusted while maintaining a proper speed for the test.

In addition, the fixing jig 26 is installed on the rotary plate 21 and is configured to fix the test piece 2.

The angle of the fixing jig 26 with respect to the rotary plate 21 can be adjusted so that the angle of collision of the slurry particles 1 with respect to one surface of the test piece 2 is adjusted when the rotary plate 21 is rotated.

The test piece 2 generally has a plate-like shape with a predetermined thickness and is arranged in a manner of being aligned with one side in the width direction of the test piece 2 with respect to the tangential line T direction of the rotation concentric circle formed by rotating the rotary plate 21 , The particles of the slurry (1) hardly collide with the one surface of the test piece (2).

2, in order that the exposed surface 2a of the test piece 2 held on the fixed holder 27 with respect to the slurry 1 is rotated together with the rotating plate 21 to collide with the particles of the slurry 1 (The circumferential direction of the rotary plate 21 in the case of the disk-shaped rotary plate 21), the particles of the slurry 1 hardly collide with the particles of the slurry 1 .

The fixing jig 26 is placed on the test piece 2 so as not to face the opposite direction of the rotation direction of the exposed surface 2a of the test piece 2 and to not be arranged in parallel with the tangential direction T of the rotation concentric circle, Can be fixed.

Further, the fixing jig 26 may be configured such that one side of the test piece 2 can be set at a setting angle corresponding to a desired test condition in the rotation direction with reference to the tangential line T direction of the rotation concentric circle. 26) can be configured to control the angle of impact of the slurry (1) particles on the test piece (2).

The fixing jig 26 includes a fixed body 26a to be mounted on a lower surface of the rotary plate 21 although not shown in detail and a fixed body 26a rotatably coupled to the lower portion of the fixed body 26a, And a rotating body 26b to which the rotating body 2 is fixed. At this time, the fastening structure of the rotary body 26b with respect to the fixed body 26a is not limited to the present invention, and any conventional rotary fastening structure may be utilized.

That is, in the fastening structure of the fixed body 26a and the rotary body 26b, the rotary body 26b is fixed to the fixed body 26a while being rotatable, rotated at a predetermined angle and fixed in position But is not limited by the present invention.

Meanwhile, the driving unit may further include a fixing holder 27 for holding the test piece 2 while being fastened to the fixing jig 26 described above.

The fixing holder 27 is configured to hold the test piece 2 and to surround the edge of the test piece 2 so that the edge portion and the vertex of the test piece 2 are generated in an erratic manner in the corrosion wear of the test piece 2 And the like.

The test piece 2 collides with the particles of the slurry 1 while being rotated by the rotating plate 21 in a state where the test piece 2 is immersed in the slurry 1 in the chamber 10. In this case, Corrosion wear is concentrated on the rim of the test piece 2 because the particles have a relatively high flow velocity at the rim portion of the test piece 2.

In order to prevent concentration of corrosion wear on the rim of the test piece 2 in this manner, the fixing holder 27 may be formed to surround the rim of the test piece 2, The surface of the test piece 2 is covered with the other surface of the test piece 2 so that only one surface of the test piece 2 can be exposed to the slurry 1.

The fixing holder 27 may include a fixing bolt 27b for fixing the test piece 2 by forming a coupling groove 27a into which the test piece 2 is inserted as shown in FIG. have.

At this time, the fastening groove 27a has a depth 27c at which the test piece 2 does not protrude from the fastening groove 27a when the test piece 2 is inserted into the fastening groove 27a. That is, the particles of the slurry 1 to be flowed do not have a relatively high flow rate at the edge of the test piece 2.

It is preferable that the fastening groove 27a has a size larger than that of the test piece 2 so that the test piece 2 can be pulled in smoothly while corresponding to the test pieces 2 having various sizes that can be used. The position of the test piece 2 pulled into the groove 27a can be fixed by a pressing member or an engaging member such as the fixing bolt 27b.

Further, the fixing holder 27 is not limited to the present invention but may be any structure as long as it surrounds the rim of the test piece 2 as a structure for preventing corrosion wear concentration on the rim of the test piece 2 Of course it is.

For reference, when the weight loss of the test piece 2 is compared with the case where the fixing holder 27 is not used and the case where the fixing holder 27 is used in the corrosion wear test of the test piece 2 as shown in the following Table 1, According to the difference is about 10 times.

Weight loss (g)
Standard Deviation
When the fixed holder 27 is not used
0.025
0.037
0.019
0.025
0.024 6.6 * 10 ^-4
When the fixed holder 27 is used
0.022
0.023
0.023
0.024
0.022 8.3 * 10 ^-5

Meanwhile, the present invention may further include a temperature controller and a gas controller for controlling the slurry 1 in the chamber 10 to have a predetermined temperature and oxygen concentration under the corrosion wear test condition of the test piece 2.

Specifically, the temperature control unit includes a temperature sensor 31 mounted in the chamber 10 for measuring the temperature of the slurry 1, a heating coil 32 and a water-cooling jacket 33 built in the chamber 10, A temperature controller TC may be provided which is electrically connected to the temperature sensor 31, the heating coil 32 and the water-cooling jacket 33 to control the temperature of the slurry 1 in the chamber 10, respectively.

At this time, the heating coil (32) and the water-cooling jacket (33) can be arranged to be wound in the side wall of the chamber (10) A temperature control function can be performed in the case of maintaining the temperature in the chamber 10 raised by the temperature sensor 31 at a predetermined test temperature or the like by receiving the temperature in the chamber 10 from the temperature sensor 31 and controlling the heating coil 32 or water- The jacket 33 can be operated.

The gas control unit includes an oxygen concentration sensor 41 mounted in the chamber 10 for measuring the oxygen concentration of the slurry 1, a flow rate controller 42 for controlling the flow rate of the supplied oxygen and nitrogen, And a gas controller (GC) electrically connected to the flow rate controller (41) and the flow rate controller (42), respectively.

The flow rate regulator 42 is mounted on the transfer line 45 extending into the chamber 10 while the oxygen supply line 43 and the nitrogen supply line 44 are connected to each other, And the nitrogen supply line 44, respectively.

The gas controller GC is electrically connected to the oxygen concentration sensor 41 and the flow rate regulator 42 and controls the flow rate regulator 42 based on the oxygen concentration measurement value sensed from the oxygen concentration sensor 41 The gas concentration of the slurry 1 in the chamber 10 can be controlled.

At this time, oxygen is a main factor for corroding the test piece (2), and another inert gas may be utilized instead of nitrogen.

Reference numeral 46 in Fig. 1 denotes a gas inlet port connected to the transfer line 45, and reference numeral 47 denotes a gas outlet port.

Further, the present invention may further include side baffles 51 and a lower baffle 52 formed on the side surface and the bottom surface of the chamber 10, respectively, to block the rotation of the slurry 1 by rotation of the driving portion .

The side baffle 51 and the lower baffle 52 each have a structure protruding from the side surface and the bottom surface of the chamber 10 toward the center of the chamber 10 by a predetermined amount. The slurry 1 to be flowed can be blocked by the side baffle 51 and the lower baffle 52.

The test piece 2 is rotated in the slurry 1 in the chamber 10 to rub against the slurry 1 so that one surface of the test piece 2 faces the tangential line T direction of the rotation concentric circle The angle of collision with the particles of the slurry 1 can be adjusted and the fixing holder 27 can hold the test piece 2 while keeping the distance between the test piece 2 and the test piece 2. [ It is possible to prevent corrosion wear from being generated on the edge of the test piece 2 in a concentrated manner.

Further, the present invention can control the slurry (1) in the chamber (10) to have the set temperature and oxygen concentration under the corrosion wear test condition of the test piece (2) by the temperature control section and the gas control section.

This makes it possible to accurately and easily measure the corrosion and wear characteristics of the material in a slurry environment in which the wear material is mixed with the fluid.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

1: Sludge 2: Test piece
2a: exposed surface 10: chamber
11: cover 21: spindle
22: Power transmission shaft 23: Driving motor
24: detachable part MC: motor controller
26: Fixing jig 26a: Fixing body
26b: rotating body 27: fixed holder
27a: fastening groove 27b: fastening bolt
27c: Depth T: Tangent
31: temperature sensor 32: heating coil
33: Water-cooled jacket TC: Temperature controller
41: oxygen concentration sensor 42: flow rate regulator
43: oxygen supply line 44: nitrogen supply line
45: transfer line 46: gas inlet
47: Gas exhaust GC: Gas controller
51: Side baffle 52: Lower baffle

Claims (9)

A chamber 10 in which the slurry 1 is received; The test piece 2 is rotated in the slurry 1 in the chamber 10 to rub against the slurry 1 so as to measure the corrosion wear of the test piece 2 by the slurry 1, And a driving unit capable of adjusting a collision angle,
The driving unit includes: a rotating plate (21) on which the test piece (2) is mounted; A driving motor 23 connected to the power transmitting shaft 22 extending upward from the rotating plate 21 to rotate the rotating plate 21; And the rotating plate 21 is installed on the rotating plate 21 while the test piece 2 is fixed and the rotation angle of the rotating plate 21 is adjusted so that the angle of collision of the particles of the slurry 1 on one surface of the test piece 2, The fixing jig 26 includes a fixed body 26a provided on the rotary plate 21, And a rotating body 26b to which the test piece 2 is fixed and which is fixed to the fixed body 26a and is rotatable and fixed after being rotated,
The driving unit includes a fastening groove 27a through which the test piece 2 is inserted to hold the test piece 2 while enclosing the rim of the test piece 2, (27b), and a fixing holder (27) fastened to the fixing jig (26)
The depth 27c of the coupling groove 27a is formed such that the test piece 2 is not projected outward from the coupling groove 27a when the test piece 2 is inserted into the coupling groove 27a,
And a side baffle (51) and a lower baffle (52) respectively formed on a side surface and a bottom surface of the chamber (10) so as to block the rotation of the slurry (1) Slurry corrosion wear test equipment.
delete delete delete The method according to claim 1,
The driving unit includes:
A motor controller (MC) for sensing and controlling the rotational speed of the drive motor (23);
Wherein the slurry corrosion wear test apparatus further comprises:
The method according to claim 1,
A temperature sensor (31) mounted on the chamber (10) and measuring the temperature of the slurry (1);
A heating coil 32 and a water-cooling jacket 33 built in the chamber 10; And
A temperature controller (TC) electrically connected to the temperature sensor (31), the heating coil (32), and the water cooling jacket (33) to control the temperature of the slurry (1) in the chamber (10);
The slurry corrosion wear test apparatus according to claim 1,
The method according to claim 1,
An oxygen concentration sensor (41) mounted on the chamber (10) for measuring the oxygen concentration of the slurry (1);
A flow controller 42 for controlling the flow rate of oxygen and nitrogen supplied to the transfer line 45 extending into the chamber 10 while the oxygen supply line 43 and the nitrogen supply line 44 are connected to each other; And
A gas controller GC electrically connected to the oxygen concentration sensor 41 and the flow rate controller 42 to control the gas concentration of the slurry 1 in the chamber 10;
And a gas control unit including the gas control unit.
delete 8. The method according to any one of claims 1 to 7,
A cover (11) mounted on the chamber (10) to block the entry of outside air and moisture into the chamber (10);
Further comprising a slurry corrosion wear tester.

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