KR200492324Y1 - Apparatus for adding bending stress three-point and four-point - Google Patents

Abstract

The present design relates to a combined 3-point and 4-point bending stress application device, and more specifically, a 3-point or 4-point bending stress can be applied to the test specimen during the stress corrosion cracking test of the specimen through corrosion by corrosion gas and corrosion solution. It relates to a three-point and four-point combined bending stress application device.
The combined 3-point and 4-point bending stress adding device according to the present invention is a bending stress adding device, comprising: a test piece support 100 on which the test piece 400 is supported on the inside; A pressurizing means 200 which is coupled to the test piece support 100 so as to be elevating and adds a load to the test piece 400; And a stress converting means 300 detachably coupled to a lower portion of the pressing means 200.

Description

Apparatus for adding bending stress three-point and four-point}

The present design relates to a combined 3-point and 4-point bending stress application device, and more specifically, a 3-point or 4-point bending stress applied to the test specimen during the stress corrosion cracking test of the specimen through corrosion by corrosion gas and corrosion solution. It relates to a three-point and four-point combined bending stress application device.

In general, when metal materials such as carbon steel or stainless steel are exposed to a specific environment, stress corrosion cracking occurs.

In particular, metal materials used in various structures or facilities that are exposed to a wet acidic environment for a long period of time or subjected to tensile loads must have excellent corrosion resistance and tensile strength, and these metal materials must have corrosion solutions such as salt water and corrosion gases such as sulfur gas. The stress corrosion cracking test is carried out under the test conditions by to determine whether it is suitable for use.

In the conventional stress corrosion cracking test, a motor capable of rotating and shifting was used as a device that applies a load to induce cracking of the test piece. That is, a load was added by converting the rotational motion of the motor into a linear motion, or a hydraulic pump was operated using a motor and a load was added using the hydraulic pressure generated by the hydraulic pump.

However, the stress applying device using the power by the motor has a problem that the components are complicated, and as a result, expensive manufacturing cost is required.

An example of a technique for solving this problem is disclosed in Document 1 below.

In Patent Document 1, in a four-point constant stress applying device for testing the occurrence of cracks by applying a load to the test piece, a support for fixing the test piece; A pressing member applying a load in contact with the test piece; A dial gauge that is in contact with the lower portion of the test piece and measures the degree of warpage of the test piece by the load of the pressing member; And a pedestal for supporting the dial gauge, wherein the pressing member is provided with a screw bolt penetrating the support in a center to apply a load to the test piece by rotation of the screw bolt. Point is disclosed for a constant stress application device.

However, the conventional technique as described above is to add a four-point bending stress to the test piece during the stress corrosion cracking test, the range of application is limited, so in order to add the three-point bending stress, a three-point bending stress adding device must be separately manufactured. There was a problem.

Republic of Korea Utility Model Publication No. 20-0338691 (registered on Jan. 5, 2004)

The present invention was devised to solve the above-described problems, and by attaching and detaching the stress conversion means to the lower portion of the pressing means, it is possible to provide 3-point and 4-point bending stress to the test piece through one device. An object of the present invention is to provide a device for adding a bending stress for both three and four points.

In order to achieve the above object, the three-point and four-point combined bending stress adding device according to the present invention comprises: a test piece support 100 on which the test piece 400 is supported on the inside of the bending stress adding device; A pressurizing means 200 which is coupled to the test piece support 100 so as to be elevating and adds a load to the test piece 400; And a stress converting means 300 detachably coupled to a lower portion of the pressing means 200.

In addition, the test piece support 100 includes a support holder 110 having a lower portion open and protruding portions 111 extending inward from both sides of the lower portion; It characterized in that it comprises a; non-conductor 120 respectively installed on the upper portion of the protrusion 111.

In addition, the pressing means 200 is disposed on the inner side of the test piece support 100, a pressing block 210 in which a non-conductor 211 is installed on both sides of the lower side, respectively; It characterized in that it includes; a bolt 220 penetrating the upper portion of the test piece support 100, the lower end is fixed to the pressure block 210.

In addition, the pressing means 200 is fixed to each of the upper both sides of the pressing block 210, characterized in that it comprises a guide pin 230 passing through the upper portion of the test piece support (100).

In addition, a guide groove 212 having a'TT' shape in cross section is formed at a lower portion of the pressure block 210 so that the stress conversion means 300 is coupled.

In addition, the stress conversion means 300 includes a guide rail 310 slidably coupled to the guide groove 212 of the pressure block 210; And a pressing protrusion 320 integrally protruding from the lower portion of the guide rail 310 and having a rounded lower end thereof.

As described above, the combined 3-point and 4-point bending stress adding device according to the present invention provides 3-point and 4-point bending stress to the test piece by the stress conversion means detachably coupled to the lower portion of the pressing means, While greatly improving the manufacturing cost of the device has the effect of reducing.

1 is a perspective view showing a combined 3-point and 4-point bending stress adding device according to the present invention.
Figure 2 is a front view showing a combined 3-point and 4-point bending stress adding device according to the present invention.
Figure 3 is a state diagram showing a three-point and four-point combined bending stress addition device according to the present invention.
Figure 4 is a view showing a three-point bending stress addition state of the combined 3-point and 4-point bending stress adding device according to the present invention.
Figure 5 is a view showing a state of adding a four-point bending stress of the combined 3-point and 4-point bending stress adding device according to the present invention.

Hereinafter, in order to describe in detail enough that a person of ordinary skill in the art can easily implement the present invention, the most preferred embodiment of the present invention will be described in detail.

As shown in Figures 1 and 2, the three-point and four-point combined bending stress adding device according to the present invention is a test piece support 100 on which the test piece 400 is supported inside; A pressurizing means 200 which is coupled to the test piece support 100 so as to be elevating and adds a load to the test piece 400; And a stress converting means 300 detachably coupled to the lower portion of the pressing means 200.

The three-point and four-point combined bending stress adding device configured as described above allows the test piece 400 to be supported over the non-conductor 120 of the test piece support 100, and pressurizing means 200 until a pre-calculated displacement is reached. Rotate the bolt 220 of. With the rotation of the bolt 220, the pressing block 210 descends to press the test piece, so that a load is applied to the test piece 400. In this way, the bending stress adding device including the test piece support 100 to which the load is applied to the test piece 400 is immersed in the test tank of the stress corrosion cracking test apparatus filled with corrosion gas and corrosion solution as shown in FIG. 3.

The present invention provides a combined 3-point and 4-point bending stress adding device capable of applying 3-point or 4-point bending stress to the test specimen during stress corrosion cracking test of the specimen through corrosion by corrosion gas and corrosion solution.

Conventionally, a three-point bending stress applying device or a four-point bending stress applying device has been disclosed, but it is possible to add only a three-point bending stress or a four-point bending stress, respectively. Therefore, the application range is limited, and thus there is a problem in that a bending stress adding device must be separately manufactured to provide different bending stress.

In order to solve this, in the present invention, the stress converting means 300 is detachably coupled to the lower portion of the pressing means 200, thereby providing 3-point and 4-point bending stress to the test piece through one device. Due to this, it is possible to greatly improve the operability of the device while reducing the manufacturing cost of the device.

The test piece support 100 and the pressing means 200 are formed of a metal material.

For the stress corrosion cracking test, the test piece support 100 and the pressing means 200 are immersed in a test tank filled with a corrosion gas and a corrosion solution for a long period of time. This process can corrode the metal. To prevent this, the test piece support and the pressing means are formed of a material having corrosion resistance (corrosion resistance), and it is preferable that it is formed of stainless steel. This is to prevent corrosion by corrosive gases and corrosion solutions.

The surface of the test piece support 100 and the pressing means 200 forms a coating layer.

As another embodiment of the present invention, the outer surface of the test piece support 100 and the pressing means 200 may be coated. Teflon, which is a fluororesin, may be used as the coating layer, and may be substituted with a material that exhibits the same purpose and effect.

The test piece support 100 includes a support holder 110 having an open lower portion and a protrusion 111 extending inward from both sides of the lower portion; And a non-conductor 120 installed on each of the protrusions 111.

During the stress corrosion cracking test, in order to apply bending stress to the test piece, which is a metal material, the test piece 400 must be stably supported. To this end, the test piece is positioned above the protrusion 111 of the support holder 110. At this time, the non-conductor 120 comes into contact with the test piece, which eliminates the effect on conduction during the stress corrosion cracking test so that more precise measurement can be performed.

The pressing means 200 is disposed on the inside of the test piece support 100, a pressing block 210 in which a non-conductor 211 is installed on both sides of the lower side, respectively; Includes; a bolt 220 that penetrates the upper part of the test piece support 100 and has a lower end fixed to the pressure block 210.

In the stress corrosion cracking test, a load is applied to the test piece 400 to induce cracking of the test piece. To this end, the pressure block 210 is to add a load in contact with the test piece, and is operated up and down according to the rotational operation of the bolt 220.

The non-conductor 211, like the non-conductor 120 installed in the test piece support 100, serves to eliminate the effect on conduction during a stress corrosion cracking test, thereby enabling more precise measurement.

The bolt 220 raises and lowers the pressure block so that the pressure block 210 applies a load to the test piece 400, and by the rotation of the bolt 220, the pressure block 210 descends toward the test piece to load the test piece. Is applied.

The pressing means 200 are fixed to both upper sides of the pressing block 210, respectively, and include a guide pin 230 passing through the upper portion of the test piece support 100.

When the bolt 220 rotates, the pressing block 210 rotates interlockingly. To prevent this, two guide pins 230 are vertically spaced apart from the top of the pressing block 210, and rotation of the pressing block 210 is prevented by the guide pins 230.

A guide groove 212 having a'TT' shape in cross section is formed at a lower portion of the pressure block 210 so that the stress conversion means 300 is coupled.

Typically, a three-point bending stress application device or a four-point bending stress application device is applied to the stress corrosion cracking test as necessary. Accordingly, the present invention can easily convert the 3-point bending stress or 4-point bending stress applied to the test piece through one device. To this end, the stress conversion means 300 is slidably coupled to the guide groove 212 formed under the pressure block 210. In this case, the stress converting means may be prevented from being separated from the outside during the sliding movement process by the guide groove having a'TT' shape. Accordingly, the stress conversion means can easily contact the test piece, and can be quickly converted into three-point bending stress.

In the present invention, a friction material may be attached to the inner surface of the guide groove 212.

This may cause wear of the stress converting means due to repeated reciprocating motion of the stress converting means 300, and replacement timing of parts may occur quickly due to the wear of the stress converting means. Therefore, a separate friction material is attached to the inside of the guide groove. Teflon may be used as the friction material, and may be substituted with a material that exhibits the same purpose and effect.

The stress conversion means 300 includes a guide rail 310 slidably coupled to the guide groove 212 of the pressure block 210; And a pressing protrusion 320 integrally protruding from the lower portion of the guide rail 310 and having a rounded lower end thereof.

The stress conversion means 300 is made of a non-conductor to eliminate the effect on conduction during the stress corrosion cracking test. The guide rail 310 is formed in a shape and size corresponding to the guide groove 212. The pressing protrusion 320 is designed so that it does not contact the pressing block when the height protruding from the pressing block 210 is bent at the maximum bending displacement (about 2 mm) of the test piece. In particular, it is preferable that the rounding portion of the pressing protrusion 320 is formed with a curvature corresponding to the curvature of the non-conductor 211 installed under the pressing block 210.

According to the present invention, depending on whether the stress conversion means 300 is attached or detached, a 3-point or 4-point bending stress may be applied to the test piece.

As shown in Figure 4, the three-point bending stress is the portion (D, E) in contact with the non-conductor 120 installed on the protrusions 111 on both sides of the test piece 400 and the test piece support 100, the It means a portion (A) in contact with the stress conversion means 300 coupled to the lower portion of the pressure block 210. This three-point bending stress can be applied in a state in which the stress converting means 300 is coupled to the guide groove 212 of the pressure block 210.

As shown in Figure 5, the four-point bending stress is the portion (D, E) in contact with the non-conductor 120 installed on the protrusions 111 on both sides of the test piece 400 and the test piece support 100, the It means a portion (B, C) in contact with the non-conductor 211 installed on both sides of the lower portion of the pressing block 210. This four-point bending stress can be applied in a state where the stress conversion means 300 is completely separated from the guide groove 212 of the pressure block 210.

Although the present invention has been described based on a preferred embodiment with reference to the accompanying drawings, it is apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the present invention from this description. Accordingly, the scope of the present invention should be interpreted by the claims described to include examples of such many modifications.

100: test piece support 110: support holder
111: protrusion 120: non-conductor
200: pressing means 210: pressing block
211: non-conductor 212: guide groove
220: bolt 230: guide pin
300: stress conversion means 310: guide rail
320: pressure protrusion 400: test piece

Claims (6)

In the bending stress application device,
Test piece support 100 on which the test piece 400 is supported on the inside;
A pressurizing means 200 which is coupled to the test piece support 100 so as to be elevating and adds a load to the test piece 400; And
Includes; stress conversion means 300 detachably coupled to the lower portion of the pressing means 200,
The pressing means 200 is disposed on the inside of the test piece support 100, a pressing block 210 in which a non-conductor 211 is installed on both sides of the lower side, respectively; Includes; a bolt 220 that penetrates the upper portion of the test piece support 100 and has a lower end fixed to the pressure block 210,
A guide groove 212 having a'TT' shape in cross section is formed at the lower portion of the pressure block 210 so that the stress conversion means 300 is coupled,
The stress conversion means 300 includes a guide rail 310 slidably coupled to the guide groove 212 of the pressure block 210; Three-point and four-point combined bending stress adding device comprising; a pressing protrusion 320 formed integrally protruding from the lower portion of the guide rail 310 and having a rounded lower end.
The method according to claim 1,
The test piece support 100 includes a support holder 110 having an open lower portion and a protrusion 111 extending inward from both sides of the lower portion;
Non-conductor 120 respectively installed on the upper portion of the protrusion 111; 3-point and 4-point combined bending stress adding device comprising a.
delete The method according to claim 1,
The pressing means 200 are fixed to both sides of the upper side of the pressing block 210, respectively, and a three-point and four-point combined bending, characterized in that it comprises a guide pin 230 penetrating the upper portion of the test piece support (100) Stress applicator.
delete delete

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