KR20100094775A - Apparatus for thermal mechanical fatigue test with electric furnace and slider cooling unit - Google Patents

Abstract

PURPOSE: A slider cooler which makes rapid heating and cooling possible and a thermo-mechanic apparatus for testing fatigue with a furnace are provided to rapidly heat a test piece by maintaining the fixed temperature of the test piece during the test. CONSTITUTION: A slider cooler comprises a test holder(30), heating furnaces(20a,20b), a guide unit(42), an air blast cooling device(50) and a pneumatic cylinder(40). The heating furnace is fixed between a trial holder and a tester connection unit(32). The heating furnace is formed in order to protect a test piece(10) toward the center of the slider cooler. The heating furnace comprises an inlet hole(22) punched on the test piece. The guide unit is horizontally formed to the test piece. The air blast cooling device is carried by the guide unit to the test piece. The air blast cooling device comprises a spray hole(52) which cools the test piece. The pneumatic cylinder is integrated with one end of the air blast cooling device.

Description

Thermomechanical Fatigue Test Device with Slider Cooling Device and Furnace {APPARATUS FOR THERMAL MECHANICAL FATIGUE TEST WITH ELECTRIC FURNACE AND SLIDER COOLING UNIT}

The present invention relates to a thermomechanical fatigue test apparatus having a slider cooling apparatus and a furnace, and more particularly, to enable local rapid heating and rapid cooling of a specimen when performing a thermal mechanical fatigue (TFM) test. It relates to a thermomechanical fatigue test apparatus having a slider cooling apparatus and a furnace.

In general, a thermal barrier coating (TBC) is applied to the surface of the blades to protect the gas turbine blades operated at 1300 ° C or higher from a high temperature flame and to increase the operating temperature of the turbine.

In addition, since the gas turbine operates at a high speed of about 3600 rpm, it is subjected to centrifugal stress, and a lot of fatigue loads are generated as most of the gas turbines are operated under frequently changed operating and stopping conditions.

The TMF test is designed to consider the operating conditions of the gas turbine in actual operation. There are generally two test methods, in-phase and out-of-phase.

In-phase means a state of tensile stress during heating and a state of compressive stress during cooling, which is a phenomenon appearing at the outer edge of the blade.

The reversed phase is a compressive stress state at the time of heating and a tensile stress state at the time of cooling, and may be referred to as a stress history appearing around the cooling hole inside the blade.

Therefore, it is conventionally proposed to perform the TMF test by induction heating method by winding the induction coil 4 on the test piece 2 as shown in FIG. 1.

In the case of using the induction heating method, since the electromagnetic flux acts only on the base material and not on the coating part of the ceramic material, the coating part is heated by conduction from the base material.

In this case, the coating part temperature is lower than the temperature of the base metal, thereby causing a problem that is the opposite of the operating conditions under actual operation, and thus, a problem that the precision and reliability of the test results are greatly deteriorated is increasing.

Accordingly, the present invention has been made in view of the above-mentioned conventional problems, and an object thereof is a thermomechanical fatigue test having a slider cooling device and a furnace that enable local rapid heating and rapid cooling of a test piece when performing a TMF test. In providing a device.

The thermomechanical fatigue test apparatus having the slider cooling device and the furnace of the present invention as described above is formed to surround the test piece fixed between the test holder and the tester connection part in the center, and has a separation type having an entry hole punched toward the test piece. An air jet cooler having a heat generating furnace, a guide part formed horizontally toward the test piece in the inlet hole of the separate type heating furnace, a spray hole moved along the guide part toward the test piece, and cooling the test piece, and the air jet cooler It is provided with a pneumatic cylinder fixed to one end of the movement is formed to move along the guide portion.

The separate heating furnace is always on during the test to act to rapidly heat the specimen.

The air jet cooler has an elliptical shape such that an end in which the injection hole is formed surrounds the test piece.

According to the structure of Claim 1 of this invention, while forming so that a test piece may be enclosed, a cooling apparatus can be moved to a slide, and there exists an effect that rapid heating and rapid cooling of a test piece can be performed easily.

According to the configuration of claim 2 of the present invention, since the test piece is always kept on during the test by using the furnace, there is an effect that the test piece can be quickly heated without a time lag.

According to the configuration of claim 3 of the present invention, since the end portion formed with the injection hole of the air jet cooler is formed in an elliptical shape, there is an effect that it can be rapidly cooled rapidly while the test piece is wrapped.

With reference to the accompanying drawings, a thermomechanical fatigue test apparatus having a slider cooling apparatus and a furnace of the present invention as described above will be described in detail below.

FIG. 2 is a view showing a partial separation state of the thermomechanical fatigue test apparatus having the slider cooling apparatus and the furnace of the present invention, and FIG. 3 is a partial cross-sectional state of the thermomechanical fatigue testing apparatus having the slider cooling apparatus and the furnace of the present invention. It is a figure which shows.

In the thermomechanical fatigue test apparatus having the slider cooling apparatus and the furnace of the present invention, the separate type heat generating furnaces 20a and 20b, as shown in Fig. 2, have an inlet hole 22 on the outer circumferential side in the thickness direction. Perforated

The test piece 10 is positioned between the central sides of the separate heating furnaces 20a and 20b.

The test piece 10 has an upper end and a lower end fixed to the test holder 30 located on the upper side and the tester connection part 32 located on the lower side.

At this time, when the separation type heating furnace 20a, 20b is wrapped around the outer circumference of the test piece 10 and fixed, it is fixed at a predetermined interval without being in contact with each other. Accordingly, since the separation type heating furnaces 20a and 20b, which surround and fix the test piece 10, are spaced apart from each other, the experimental state can be confirmed therebetween.

Of course, as described above, the separation type heating furnaces 20a and 20b are spaced apart from each other by a predetermined interval, but after they are formed to be in contact with each other, a hole for observing the inside can be formed in the parts to be contacted. Not to mention that.

Since the separate heating furnaces 20a and 20b are heated in a convection manner using a heating element (not shown), uniform heating is possible throughout the longitudinal direction of the test piece 10, The likelihood of a temperature gradient occurring is significantly reduced.

When the test piece 10 is fixed between the pair of heat generating furnaces 20a and 20b as described above, the test piece is vertically erected in the inlet hole 22 formed on the heat generating furnaces 20a and 20b. The horizontal guide portion 42 is fixedly formed at right angles with the 10.

On the guide portion 42 formed on the inlet hole 22 of the heating furnaces 20a and 20b, the heating unit 20 slides toward the test piece 10 positioned at the center of the heating furnaces 20a and 20b and moves to the center side. An air jet cooler 50 is mounted.

The air jet cooler 50 slides along the longitudinal direction of the guide part 42 automatically by the pneumatic cylinder 40 mounted at one end of the guide part 42 to the central side where the test piece 10 is located. Is moved.

At this time, the air jet cooler 50 mounted on the left and right sides of the heat generating furnaces 20a and 20b toward the center of the test piece 10 is operated to move toward the center along the guide part 42 at the same time.

Therefore, when the pneumatic cylinder 40 fixed to the end side of the guide portion 42 is operated, the air jet cooler 50 located on the left and right sides of the test piece 10 is separated heating along the guide portion 42 While passing through the inlet holes 22 of the furnaces 20a and 20b, it is moved toward the center side toward the test piece 10 fixed to the center of the shaft.

As such, the injection hole 52 formed at the end of the air jet cooler 50 moved along the guide part 42 to the center of the test piece 10 by the pneumatic cylinder 40 to the outer periphery of the test piece 10. After moving, it stops.

The pneumatic cylinder 40 for moving the air jet cooler 50 is mounted on the end side of the guide portion 42, and is located outside the separate type heating furnaces 20a and 20b.

Accordingly, the air used in the pneumatic cylinder 40 is prevented from rising due to the heat generated in the separate heat generating furnaces 20a and 20b.

Since the end in which the injection hole 52 of the air jet cooler 50 is formed is formed in a semi-elliptic shape, when the ends of the air jet coolers 50 positioned on both left and right sides contact each other, the test piece as shown in FIG. 3. It stops by wrapping (10).

When the end portion of the air jet cooler 50 surrounds the test piece 10 as described above, the test piece 10 is rapidly cooled by supplying cooling air through the injection hole 52 formed at the end of the air jet cooler 50.

In addition, a plurality of injection holes 52 of the air jet cooler 50 are formed along the longitudinal direction of the test piece 10 to uniformly supply cooling air to the entire test piece 10 so that a temperature gradient does not occur. Cool down quickly.

At this time, while cooling the test piece 10 located in the inner center of the separate heating furnaces 20a and 20b by the air spray cooler 50, the separate heating furnace is kept on without lowering the temperature and continuously generates heat. However, it does not affect the test piece (10). That is, the test piece 10 has an end portion of the air spray cooler 50 having an elliptical shape, and the ends of the air spray cooler 50 moved from both sides with respect to the test piece 10 abut against each other. Is cooled in a wrapped state in a round pipe form, so that the temperature continuously generated in the separate heating furnaces 20a and 20b does not reach the test piece 10.

When the cooling air is injected through the injection hole 52 of the air jet cooler 50, and when the test piece 10 is heated again, the movement of the air jet cooler 50 is pulled by operating the pneumatic cylinder 40. Sliding along the guide portion 42 and returning to the original position, the ends of the air jet cooler 50 surrounding the test piece 10 are released while opening to both sides.

As described above, the end of the air jet cooler 50 surrounds the test piece 10. When released, the test piece 10 is returned to a high temperature due to the heat that is continuously generated in the separate type heating furnaces 20a and 20b. The test piece 10 can be heated rapidly without instantaneous heating. That is, since the heat generation is maintained by turning the power to the separate type heating furnaces 20a and 20b on, the heat generation is stopped due to the power off, and the test piece 10 is cooled. This eliminates the time lag required to raise the specimen to its original heating temperature, enabling rapid heating.

As described above, the air jet cooler 50 is slidably moved using the air jet cooler 50 and the separate heating furnaces 20a and 20b to perform rapid cooling and rapid heating.

In addition, since the present invention only needs to move the air jet cooler 50 along the guide portion 42, rapid heating by the exothermic furnaces 20a and 20b is automatically controlled after the rapid cooling control.

In addition, by the rapid cooling and heating method according to the configuration of the present invention, the disadvantages caused by the conventional induction heating is eliminated, it is possible to test with high precision and reliability even for the test piece subjected to heat shield coating such as ceramic material.

1 is a view showing a conventional test apparatus.

2 is a view showing a part of a separation state of the thermomechanical fatigue test apparatus having a slider cooling apparatus and a furnace of the present invention,

3 shows a partial cross-sectional view of a thermomechanical fatigue test apparatus having a slider cooling apparatus and a furnace of the present invention.

Description of simple symbols for the main parts of the drawings

10: test piece 20a, 20b: separate heating furnace

22: entry hole 30: test holder

32: connection part 40: pneumatic cylinder

42: guide portion 50: air jet cooler

Claims (3)

The split type heating furnace 20a having a center of the test piece 10 fixed between the test holder 30 and the tester connection part 32 and having an inlet hole 22 bored toward the test piece 10. , 20b, A guide part 42 formed horizontally toward the test piece 10 in the inlet hole 22 of the separate type heating furnaces 20a and 20b, An air jet cooler 50 which is moved along the guide part 42 toward the test piece and has a spray hole 52 to cool the test piece 10, Thermodynamic fatigue test apparatus having a slider cooling device and a furnace, characterized in that the pneumatic cylinder (40) formed integrally fixed to one end of the air jet cooler (50) to move along the guide portion (42).  2. The thermomechanical fatigue testing apparatus according to claim 1, wherein the separate heating furnaces (20a) and (20b) are always turned on during the test to rapidly heat the specimen. According to claim 1, wherein the air jet cooler 50 is a thermo-system fatigue testing apparatus having a slide cooling device and a furnace characterized in that the elliptical shape so that the end formed with the injection hole 52 surrounds the test piece (10). .

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