KR20130011611A - Changeable gage length extensometer - Google Patents

Abstract

PURPOSE: A gauge length variable extensometer is provided to limit a rotational angle range of a movable bar by forming a limitation bar and a stop bar respectively in a fixing bar and the movable bar, thereby preventing damage to the movable bar caused by the movable bar rotated more than a set angle. CONSTITUTION: A gauge length variable extensometer(10) comprises a fixing bar(200), a movable bar(300), a pair of extension bars(400), and a pair of workpiece fixing units(500). One end portion of the fixing bar is fixed to a sensor unit(100). One end portion of the movable bar is joined to the sensor unit with a hinge. The other end portion of the movable bar is installed to be spaced from the fixing bar so that a distance between the other portion of the movable bar and the other end portion of the fixing bar is adjustable. The pair of the extension bars is installed in the other end portion of the movable bar and the other end portion of the fixing bar to be extended side respectively along a longitudinal direction to an outer. The pair of the workpiece fixing units is installed to be moved respectively along the longitudinal direction of the extension bars, thereby fixing the specimen.

Description

Gauge Distance Adjustable Extensometer {CHANGEABLE GAGE LENGTH EXTENSOMETER}

The present invention relates to a variable gauge range extender, and more particularly, the size of the specimen by allowing the position (marking distance, gauge length) of the portion substantially fixed to the specimen to be adjusted according to the size of the specimen. It also relates to a gauge length variable extensometer which makes it easy to carry out a tensile or compressive test of a specimen even if is changed.

In general, an extensometer is used to measure the change in the axial distance of a specimen in a tensile or compression test for the evaluation of material properties at room temperature and high temperature, and in the axial direction of the specimen for strain control during fatigue testing. It is used for the purpose of measuring a change of distance.

In other words, the extensometer is a sensor used to obtain the strength and strain of the specimen by measuring the degree of deformation of the specimen according to the gauge length of the specimen. Can be distinguished.

The dual contact extensometer uses strain gauge measurement. Specifically, both sides of the specimen are fixedly connected to the extensometer, and then the tensile or compression test is performed.

However, such a conventional extensometer is not easy to adjust the position of the part fixed to the two sides of the specimen reference specimen, for example, the size of the specimen is increased to increase the distance between the two sides of the reference region There was a difficult problem to apply.

An object of the present invention is to adjust the position (marking distance, Gage length) of the portion substantially fixed to the specimen according to the size of the specimen, thereby facilitating the tensile or compression test of the specimen even if the size of the specimen is changed It is to provide a gauge length variable extender that can be implemented.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

The object is, according to the present invention, to measure the change in the distance according to the tension or compression of the specimen, one end fixed to the sensor portion; A movable bar having one end hinged to the sensor unit and the other end spaced apart from the fixed bar such that a distance between the other end and the other end of the fixed bar is adjustable; A pair of extension bars installed to extend outwardly along the longitudinal direction of the specimen from the other end of the fixed bar and the movable bar; And a pair of test piece fixing extensometers installed on the extension bars so as to be movable in the longitudinal direction of the pair of extension bars, respectively, and a pair of specimen fixing parts for fixing the specimens.

Here, the extension bar may be screwed to be detachable to the other end of the fixed bar and the movable bar, respectively.

The specimen fixing portion, the movable piece is installed to be movable on the extension bar, the stop bolt is installed; A test piece connecting pin connected to the set measuring part of the test piece; And it may include a coupling piece for fixing the specimen connecting pin to the moving piece.

A limiting bar protruding from the other end of the fixed bar toward the movable bar and provided with a limiting slot; And protruding from the other end of the movable bar toward the fixed bar, when the movable bar is rotated more than a predetermined angle hook is formed so as to catch the side wall of the limiting slot so that the distance between the fixed bar and the other end of the movable bar It may further include a stop bar for limiting exceeding the set value.

According to the variable gauge range extender according to the present invention has the following technical effects.

First, by allowing the position of the part substantially fixed to the specimen to be adjusted according to the size of the specimen, even if the size of the specimen is changed, it is easy to perform a tension or compression test of the specimen having a variety of sizes regardless have.

Second, by limiting the rotation angle range of the movable bar by forming a stop bar with a limit bar and a hook with a restriction slot on the fixed bar and the movable bar, respectively, to prevent the breakage of the sensor part by rotating the movable bar beyond the set angle. Can be.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing a gauge length variable extensometer according to an embodiment of the present invention.
2 is an exploded perspective view of FIG.
Figure 3 is a cross-sectional view showing a coupling relationship between the extension bar and the specimen fixing in the embodiment of the present invention.
4 to 6 are state diagrams illustrating a state in which the specimen is tested according to the size change of the specimen by using the variable gauge range extensometer according to the embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Preferred embodiments of the present invention are described with reference to the accompanying drawings so that the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention can be fully understood.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, in which the same reference numerals refer to the same components.

1 is a perspective view showing a gage distance variable extensometer according to an embodiment of the present invention, Figure 2 is an exploded perspective view of Figure 1, Figure 3 is a coupling relationship between the extension bar and the specimen fixing in the embodiment of the present invention 4 to 6 are state diagrams illustrating a state in which the specimen is tested according to the size change of the specimen using a variable gauge range extender according to an embodiment of the present invention.

As shown in these drawings, the gauge length variable extensometer (hereinafter, referred to as an 'extenometer') according to an exemplary embodiment of the present invention is a tensile test for measuring the strength and strain of the specimen. Or as a sensor for measuring the change in the axial distance between the marks of the specimen during the compression test, in this embodiment is applied as a contact extensometer for measuring the change in distance in direct contact with the specimen.

As shown in FIGS. 1 and 2, the extensometer 10 includes a fixed bar 200 having one end fixed to the sensor unit 100, one end hinged to the sensor unit 100, and the other end. The movable bar 300 is installed to be spaced apart from the fixed bar 200 so that the distance between the other end of the fixed bar 200 is adjustable. Strain gauges (not shown) are installed in the sensor unit 100 so as to be connected to one end of the fixed bar 200 and one end of the movable bar 300, respectively, and the sensor unit 100 is provided through a separate cable. It is connected to a display device (not shown). Such a display device (not shown) displays the strength and strain of the specimen according to the strain of the strain gauge of the sensor unit 100.

More specifically, the movable bar 300 is hinged in the direction of spaced apart and approach the fixed bar 200 on the plane formed with the fixed bar 200, the other end of the fixed bar 200 and the movable bar 300 The distance between the fixed bar 200 and one end of the movable bar 300 also changes according to the distance change between the strain bars, and the strain gauge (not shown) compresses and expands in the longitudinal direction corresponding to the distance change therebetween.

As shown in FIG. 1, FIG. 2 and FIG. 4, the present invention provides a fixed bar (1) to measure easily even when the size of the specimen (T) to be measured, in particular, the length of the specimen (T) changes. 200 and a pair of extension bars 400 installed on the other end of the movable bar 300 so as to extend outwards along the longitudinal direction of the specimen T, and the lengthwise direction of the pair of extension bars 400. It is installed on the extension bar 400 so as to be movable, respectively, and includes a pair of specimen fixing part 500 for fixing the specimen (T).

The pair of extension bars 400 are formed to extend to have a predetermined length or longer, and are preferably coupled to the other ends of the fixed bar 200 and the movable bar 300. For example, the extension bar 400 may be screwed to the other end of the fixed bar 200 and the movable bar 300, so that the measurer moves the extension bar 400 and the fixed bar 200 as necessary. It can be easily separated from the bar 300. However, the above-described coupling structure is not necessarily limited thereto, and the extension bar 400, the fixed bar 200, and the movable bar 300 may be coupled to each other by a hook locking structure.

On the other hand, the pair of extension bars 400 may be formed in the form of integrally connected to the fixed bar 200 and the movable bar 300, respectively, but separated for convenience of change in the length of the specimen (T) and measurement as described above It is preferred to be coupled as possible. At this time, when the pair of extension bars 400 are separated from the fixed bar 200 and the movable bar 300, respectively, the measuring portion of the test piece (T) at the other end of the fixed bar 200 and the movable bar 300 It may be provided with a separate specimen connecting pin to be described later to be connected to.

As shown in FIG. 3, the specimen fixing part 500 is installed to be movable on the extension bar 400, and the movable piece 510 on which the stop bolt 511 is installed, and the set measurement portion of the specimen T. It includes a specimen connecting pin 520 and a coupling piece 530 for fixing the specimen connecting pin 520 to the moving piece 510.

First, a through hole 512 is formed in the moving piece 510 so that the extension bar 400 is inserted therethrough, and the cross-sectional shape of the through hole 512 corresponds to the cross-sectional shape of the extension bar 400. For example, in the present embodiment, the extension bar 400 is formed to have a substantially rectangular cross-sectional shape, and the through hole 512 is formed in a quadrangular shape to correspond thereto. On the contrary, if the cross-sectional shape of the extension bar 400 is circular, the contact area between the end of the stop bolt 511 and the surface of the extension bar 400, which will be described later, is reduced than in the case described above, and the sliding piece is moved by sliding contact. A phenomenon in which 510 rotates along the circumferential direction of the extension bar 400 may occur. Accordingly, the extension bar 400 is more preferably formed to have a polygonal cross-sectional shape such as triangular, square, pentagonal, etc., which may have sufficient mutual contact area with the end of the stop bolt 511.

As shown in FIG. 3, in this embodiment, a separate bolt fastening hole 513 for inserting the stop bolt 511 is formed in the moving piece 510, and the measurer separates the stop bolt 511. After the slide piece 510 is moved to an appropriate position along the longitudinal direction of the extension bar 400, the stop bolt 511 may be fastened to limit the movement of the movable piece 510. Specifically, when the stop bolt 511 is fastened to the bolt fastening hole 513 of the moving piece 510, the end of the stop bolt 511 presses the surface of the extension bar 400 more than a predetermined time. It is possible to limit the movement of the slide 510 along the extension bar 400.

As shown in FIGS. 3 to 6, the test piece connecting pin 520 is substantially connected to the set measuring part of the test piece T. In other words, the test piece connecting part of the test piece T is fixed. In this embodiment, the specimen connecting pin 520 is formed in a roughly hook shape, the measurer can be fixedly connected to both sides of the specimen connecting pin 520 and the specimen (T) by using a rubber band, wire, etc. have. Therefore, as the distance between the two measurement reference sites in the axial direction of the specimen T during the tensile or compression test of the specimen T changes, the distance between the specimen connecting pins 520 on both sides also changes.

As shown in FIG. 3, the coupling piece 530 fixes the specimen connection pin 520 to the moving piece 510, and the coupling piece 530 has a first fixing bolt fastening hole 531 formed therein. The moving piece 510 is provided with a second fixing bolt fastening hole 514 at a position corresponding to the first fixing bolt fastening hole 531. Specifically, in order to fix the specimen connecting pin 520 in this embodiment, the specimen connecting pin (between the moving piece 510 and the coupling piece 530 in a state in which the coupling piece 530 is separated from the moving piece 510) After placing 520, the fixing bolt 532 may be inserted into and fastened to the first and second fixing bolt fastening holes 531 and 514. At this time, the test piece connecting pin 520 may be fixed between the moving piece 510 and the coupling piece 530 by fastening the fixing bolt 532.

However, the present invention is not limited thereto, and the test piece connecting pin 520 may be integrally formed with the moving piece 510 or may be integrally formed with the coupling piece 530. In the former case, the configuration of the coupling piece 530 may be omitted.

In the present invention, when the size of the specimen (T) is changed to cause the need to adjust the distance between the two reference measurement site on the specimen (T) occurs, the coupling position of the specimen fixing part 500 with respect to the extension bar 400 By appropriately adjusting the size (particularly the length) of the specimen (T), even if the increase or decrease by a certain amount there is an advantage that can be easily carried out a tensile or compression test.

As shown in FIGS. 1 and 2, the extensometer 10 according to the present exemplary embodiment includes a limiting bar 210 protruding from one side of the other end of the fixed bar 200 toward the movable bar 300. And a stop bar 310 which protrudes from the other end surface of the movable bar 300 toward the fixed bar 200 and prevents further rotation when the movable bar 300 rotates by a predetermined angle. do.

Specifically, the limiting bar 210 is formed with a limiting slot 211 penetrated in the thickness direction to have a predetermined length, the stop bar 310, the limiting slot 211 when the movable bar 300 rotates for a predetermined distance or more. The hook 311 is formed so that it may be caught by the side wall.

If the hook 311 and the restriction slot 211 structure is not provided, the movable bar 300 may be hinged in excess of an appropriate limit, in which case one end of the movable bar 300 and the fixed bar 200 may be rotated. Strain gauges (not shown) connected to each other may be damaged.

That is, the present invention through the hook 311 and the limiting slot 211, in particular during the tensile test of the specimen (T) the specimen (T) is tensioned more than necessary to the other of the fixed bar 200 and the movable bar 300 It is possible to further prevent the breakage of the sensor unit 100 from occurring by limiting the distance between the ends beyond the set value.

Hereinafter, an operation relationship of the gauge length variable extensometer according to the present embodiment will be described with reference to FIGS. 4 to 6.

First, as shown in FIG. 4, when the distance between the two measurement reference portions of the specimen T is A, the two moving pieces 510 are moved along the extension bar 400 to an appropriate position so as to correspond thereto. Thereafter, the stop bolt 511 is fastened to fix the moving piece 510 to the extension bar 400. Subsequently, both sides of the specimen connecting pin 520 and the two sides of the specimen (T) measuring reference part is fixedly connected using a rubber band or a wire, and then a tensile or compression test of the specimen (T) is performed.

Next, as shown in Figs. 5 and 6, when the size of the specimen (T) fluctuates so that the distance between the two measurement reference portions of the specimen (T) fluctuates by B and C, the moving piece 510 is similarly supported. After the movement, the tensile or compression test is performed as described above.

The embodiments and drawings attached to this specification are merely to clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. Modifications that can be made and specific embodiments will be apparent that both are included in the scope of the invention.

10: extensometer 100: sensor unit
200: fixed bar 210: limited bar
211: limit slot 300: movable bar
310: stop bar 311: hook
400: extension bar 500: test piece
510: moving piece 511: stop bolt
520: connecting pin 530: coupling piece
T: Psalm

Claims (4)

As measuring the change in distance according to the tension or compression of the specimen,
A fixed bar having one end fixed to the sensor unit;
A movable bar having one end hinged to the sensor unit and the other end spaced apart from the fixed bar such that a distance between the other end and the other end of the fixed bar is adjustable;
A pair of extension bars installed to extend outwardly along the longitudinal direction of the specimen from the other end of the fixed bar and the movable bar; And
The gauge length variable extensometer, characterized in that it is installed on the extension bar so as to be movable along the length of the pair of extension bars, respectively, and a pair of specimen fixing portion for fixing the specimen. The method of claim 1,
The extension bar is a gauge length variable extensometer, characterized in that the screw coupled to each other detachable to the other end of the fixed bar and the movable bar. The method of claim 1,
The specimen fixing section,
A moving piece installed to be movable on the extension bar and having a stop bolt installed thereon;
A test piece connecting pin connected to the set measuring part of the test piece; And
A gauge range variable extensometer, characterized in that it comprises a coupling piece for fixing the specimen connecting pin to the moving piece. The method of claim 1,
A limiting bar protruding from the other end of the fixed bar toward the movable bar and provided with a limiting slot; And
Protruding from the other end of the movable bar toward the fixed bar, when the movable bar is rotated more than a predetermined angle, a hook is formed to be caught on the side wall of the limiting slot so that the distance between the fixed bar and the other end of the movable bar is set. The gauge range variable extensometer, further comprising a stop bar for limiting exceeding the numerical value.

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