KR20140081308A - Horizontal type tension-compression tester - Google Patents

Abstract

The present invention relates to a horizontal tension-compression tester, including a test piece support unit for placing a test piece thereon; a static load applying unit for pressurizing and fixing the test piece placed on the test piece support unit in a vertical direction; a fixating unit for supporting both ends of the test piece placed on the test piece support unit; a dynamic load applying unit for applying tensile or compressing force onto the test piece placed on the test piece support unit; a temperature adjustment unit for controlling the temperature of the test piece placed on the test piece support unit to keep a predetermined temperature; and a control unit for detecting load or changing statuses of the test piece in accordance with the operation of the dynamic load applying unit to control the operations of the above components.

Description

[0001] HORIZONTAL TYPE TENSION-COMPRESSION TESTER [0002]

The present invention relates to a horizontal-type tensile compression testing apparatus, and more particularly, to a horizontal-type tensile compression testing apparatus capable of accurately and easily aligning a test piece by horizontally arranging the test piece, And a test apparatus.

The present invention was derived from the research carried out as part of the WPM (World Premier Materials) project of the Ministry of Knowledge Economy. [Title of Project: High Performance Plate Material, Project No. 10037929, Research Management Institution: Korea Industrial Technology Evaluation & Management Service]

Due to problems such as energy exhaustion and global warming, there is a growing demand for lightweight transportation equipment parts industry such as automobiles. The most significant way to develop lightweight components is to use lightweight metals.

This lightweight alloy material is a representative example of a magnesium alloy, and a magnesium alloy material is environmentally friendly and has a high specific strength.

In addition, as national interest and investment in magnesium alloys have increased, it is expected to improve price competitiveness and develop high-performance materials.

The magnesium alloy was mainly manufactured using die-casting.

However, recently, a stamping method using a magnesium alloy sheet has been actively studied. However, due to low formability and productivity at room temperature, a sheet material molding method is currently applied only to limited parts.

In addition, the core elements of maximizing the moldability of magnesium alloy sheets are the development of constitutive models and failure models, and the material properties of magnesium alloy sheets are much different from those of conventional metal sheets .

That is, if a conventional structural formula and a fracture model are used for part analysis using a magnesium alloy plate having characteristics different from those of conventional metal plate materials such as asymmetric stress-strain behavior due to twin deformation, There is a problem.

In addition to the magnesium in the above examples, the material properties of the metal material are often not exactly the same as those of the general formula and fracture model.

Accordingly, development of a structural equation and a fracture model for more accurate analysis of tensile-compressive behavior of various kinds of metal plates is required, and a test apparatus capable of obtaining more accurate test results under various conditions is required do.

However, since the conventional tensile-compression test apparatus has a structure in which the upper and lower ends of the specimen are arranged in the vertical direction and the tensile force and the compressive force are applied in the vertical direction, it is difficult to accurately align the specimen, Unexpected buckling phenomenon occurs in the test result and the reliability of the test result is deteriorated.

In addition, the conventional tensile-compression testing apparatus has no means to control the temperature of the specimen, and thus can not analyze the material characteristics under various temperature conditions in accordance with the actual use environment.

It is an object of the present invention to improve the above-mentioned conventional characteristics, and it is an object of the present invention to provide a method of aligning a specimen by horizontally arranging the specimen, And a tensile compression test apparatus.

Another object of the present invention is to provide a horizontally disposed tensile compression testing apparatus capable of uniformly maintaining a value of friction coefficient generated during tensile and compression tests of a specimen, .

The present invention has the following structure in order to achieve the above object.

The horizontal tensile compression testing apparatus of the present invention comprises: a specimen supporting unit on which a specimen is placed; A static load load unit for pressing and fixing the specimen placed on the specimen support unit in a vertical direction; A fixing unit for supporting both ends of the specimen placed on the specimen supporting unit; A dynamic load load unit operable to apply a tensile force or a compressive force to the specimen placed on the specimen support unit; A temperature control unit for controlling the temperature of the specimen placed on the specimen support unit to have a constant temperature; And a control unit for detecting a load and a change state from the specimen in accordance with the operation of the dynamic load load unit and controlling the operation of each of the structures.

And a guide unit for guiding the lifting and lowering of the static load load unit to the upper portion of the specimen supporting unit.

The sample supporting unit includes a supporting block mounted on an upper surface of the base, a conveying block provided on one side of the supporting block for moving in the direction of movement of the dynamic load applying unit, And an upper specimen fixing table provided on the lower specimen fixing table.

The lower specimen holder is further provided with first and second specimen holders for allowing the specimen to be pressed and fixed to the lower specimen holder by a fixing unit.

The lower specimen pedestal and the upper specimen pedestal are each formed of a pair, and each of the lower specimen pedestal and the upper specimen pedestal is provided so as to be attached to each other.

And the static load applying unit includes a pressing unit for pressing the specimen supporting unit, an extension unit extending over the pressing unit, first and second pressing shafts for vertically guiding the extension unit, A horizontal bar connected to the upper portion of the pressure shaft by a shaft fixing bracket, a balance weight provided at one side of the horizontal bar to maintain balance of the weight on both sides of the horizontal bar with respect to the fixed shaft, And a weight attached to the seat so as to generate a load applied to the sample supporting unit.

The dynamic load load unit may further include an extension shaft connected to the specimen support unit, a conveyance belt for fixing the extension shaft, a screw connected to the conveyance belt for horizontally moving the extension shaft, .

And, the fixed unit is composed of a pressure cylinder and a pressure fixing bar provided at the end portion of the pressure cylinder, and concave and convex are formed at the end portion of the pressure fixing bar.

Further, the guide unit includes a fixed plate for supporting the static load unit, a roller block fixed to the fixed plate, and a roller rotatably fixed to the roller block.

And the roller block is adjustably positionable on the upper surface of the fixed plate.

According to the present invention, it is possible to align the specimen precisely and easily by horizontally arranging the specimen, and it is possible to test under various temperature conditions by applying heat to the specimen.

Further, according to the present invention, the value of the friction coefficient generated in the tensile test and the compression test of the specimen can be uniformly maintained at all times, and the error of the obtained measurement result value can be minimized.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view showing a horizontally arranged tensile compression testing apparatus of the present invention. Fig.
Fig. 2 is a side view showing the horizontal placement type tensile compression testing apparatus shown in Fig. 1; Fig.
3 is a partial view showing a specimen supporting unit according to the horizontally arranged type tensile compression testing apparatus of the present invention.
4 is a partial perspective view showing an upper and a lower specimen fixing table according to the horizontal placement type tensile compression testing apparatus of the present invention.
5 is a partial perspective view showing a guide unit and a fixed unit according to the horizontal placement type tensile compression testing apparatus shown in Fig.
6 is a partial plan view showing a specimen support unit and an operation load load unit according to the horizontal placement type tensile compression testing apparatus of the present invention.
Fig. 7 to Fig. 10 are operation views showing an operation state according to the horizontally arranged type tensile compression testing apparatus of the present invention. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described below. The embodiments are provided to explain the present invention to a person having ordinary skill in the art to which the present invention belongs. Accordingly, the shape of each element shown in the drawings may be exaggerated to emphasize a clearer description.

The terms first, second, etc. may be used to describe various elements, but the elements should not be limited by terms. Terms are used only for the purpose of distinguishing one component from another.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

1 to 6, the horizontal tensile compression testing apparatus 100 of the present invention includes a specimen supporting unit 120 on which a specimen TP is mounted; A static load load unit 130 for pressing and fixing the specimen TP seated on the specimen support unit 120 in the vertical direction; A fixing unit 140 for supporting both ends of the specimen mounted on the specimen supporting unit 120; A dynamic load load unit (150) operable to apply tensile or compressive force to the specimen placed on the specimen support unit (120); A temperature control unit 180 for controlling the temperature of the specimen placed on the specimen support unit 120 to have a constant temperature; And a control unit (170) for detecting a load and a change state from the specimen in accordance with the operation of the dynamic load load unit (150) and controlling the operation of each structure.

Meanwhile, the horizontal tensile compression testing apparatus of the present invention is mounted on a base 110, and a control unit 170 for controlling the operation of each of the above-described configurations is formed in the base 110, A display 171 for displaying the operation of each of the components controlled by the display unit 170 is configured.

Here, the display 171 may be constituted by an analog gauge, a digital gauge may be constituted, or may be variously implemented by a touch screen method such that the user can operate the control by a touch method according to a work environment have.

In addition, a plurality of wheels are formed under the base to selectively use the position of the present invention.

The specimen supporting unit 120 includes a pair of lower specimen fixing rods 121 and 122 on which the specimen TP is mounted and a pair of upper specimen fixing rods 121 and 122 provided on the lower specimen fixing rods 121 and 122 to press- First and second specimen pedestals 123 and 124 extending in opposite directions to one side of each of the pair of lower specimen fixtures 121 and 122 and a support block 122 for fixing the first specimen pedestal 123 to the upper surface of the base And a transfer block 128 movably fixing the second specimen pedestal 124 on the upper surface of the base 110. The lower specimen fixture 121 and the upper specimen fixture 125 And the lower specimen holder 122 and the upper specimen holder 126 are connected to the transport block and are moved according to the operation of the dynamic load load unit.

That is, one side of the specimen supporting unit 120 is fixed to the upper and lower supporting brackets 121 and 125 while being fixed between the upper and lower supporting brackets 121, 122, 125 and 126, and the other side is fixed to the upper and lower supporting brackets 122, 126) to transmit tensile or compressive forces to the specimen.

In addition, the upper and lower supports 121, 122, 125 and 126 are formed such that the binding pieces 121a, 122a, 125a and 126a and the grooves 121b, 122b, 125b and 126b are staggered in the mutually facing directions, So that the specimen can be pressed and fixed.

A temperature adjusting unit 180 for raising the temperature of the specimen PT is provided under the specimen support 120. The temperature adjusting unit 180 includes a heating line and a cooling line .

The heating line and the cooling line are individually operated according to the temperature of the specimen and the specimen can maintain a desired temperature at all times. For example, if the temperature of the specimen rises by more than 100 degrees after heating through the heating line to maintain the temperature of the specimen at 100 degrees, the temperature is maintained by operating the cooling line through the control unit to lower the temperature to 100 degrees .

The static load load unit 130 includes a pressing band 131 for vertically pressing the upper specimen fixing bars 125 and 126 of the specimen supporting unit 120 and an extension band 132 for fixing the pressing band 131, First and second pressing shafts 134 and 135 extending upward in the supporting bracket 133 and guided to the guide plate 135a, A shaft fixing bracket 137 extending to an upper portion of a support bracket for supporting an upper portion of the first and second pressing shafts 134 and 135 to transmit a pressing force and a shaft fixing bracket 137 rotatably connected to the shaft fixing bracket 137 by a fixing shaft 138b A support block 136 rotatably supporting the horizontal bar 138 in a state of being fixed to the upper portion of the support bracket by a rotation shaft 138a, And a vertical bar 138c provided on the other side of the horizontal bar 138 provided with the counterbalance 138c. Consists of a link (138e) and the seat link for (138d) is (138e) is connected to the lower weight (128f) is seated is installed.

That is, the static load load unit 130 makes use of the weight 138d, which is transmitted to the pressing table 131, by the force transmitted to the specimen when a tensile force or a compressive force is generated in the dynamic load load unit, So that the load can be uniformly generated, thereby preventing unevenness in the measured value of the specimen.

For example, when a load generated from a static load unit is 100 kg, even if a load generated from a dynamic load unit is transmitted through a specimen, a load for pressing the specimen at all times can be maintained at 100 kg. Even if the specimen is tensioned or compressed, There is no change, and it becomes possible to uniformly obtain measured values by tensile or compressive force.

The fixed unit 140 is disposed on the specimen support unit 120 and fixed to the support block 127 and the transfer block 128 of the specimen support unit by blocks 143a and 143b, A pair of pressing and fixing bars 141 for fixing both ends of the test piece PT fixedly secured to the unit 120 and a pressing cylinder 142 for moving the pressing and fixing bar 141 up and down. Unevenness is formed on the lower surface of the pressure fixing bar 141 to increase the pressing force of the specimen when the specimen is pressed, thereby preventing the specimen from flowing. The pressing cylinder 142 operates by the hydraulic method.

That is, the fixing unit 140 is configured to fix both ends of the specimen fixed between the upper specimen holder and the lower specimen holder of the specimen supporting unit, and one of the pair of fixing units is connected to the supporting block to fix the specimen And the other is connected to the conveying block so as to move together with the test piece fixed in the moving direction of the conveying block, so that the test piece can transmit a uniform tension or compressive force in a fixed state.

The dynamic load load unit 150 includes an extension shaft 157 connected to the transport block 128 of the specimen support unit 120 and an extension shaft 157 extending along the guide rail LM A horizontal moving table 156, a screw 154 connected to the feed table 156 to horizontally move the feed table 156, a housing 155 on which the feed table and screw are installed, A driven shaft 153 which is rotatably connected through one side of the housing 155 to rotate the screw 154 and a pulley 152 coupled to the driven shaft 153 and the motor, A belt 152a for connecting the poly 152a and a motor 151 for generating a rotational force on the driven shaft 153. [

That is, the dynamic load load unit 150 controls the rotation direction of the motor through the control unit so that the moving direction of the conveying block connected in accordance with the rotating direction is varied to generate tension or compression force on the specimen.

The guide unit 160 includes a fixed plate 161 disposed on the fixed unit 140 and fixed to a support 139 of the static load unit 130, And a roller 163 rotatably coupled to the roller block 162. The roller block 162 is movable in a horizontal direction with respect to the fixed plate 161 Thereby allowing the roller 163 to adjust the pressing force of the extension bar 132 and maintain the straightness of the extension bar 132 in the vertical direction.

That is, by maintaining the vertical direction of the pressing member 131 through the guide unit 160, the pressing force of the pressing member can be uniformly maintained.

The control unit 170 includes a controller for controlling the driving of the motor and the hydraulic system for the operation of the dynamic load load unit 150 and the static load load unit 130, a display 171 for indicating the operation state of each operation unit, Etc., and may have a separate controller and a display device, a PC-based input / output device, or both.

In addition, the control unit 170 may have previously stored data necessary for tension or compression test of the specimen, and may have a storage space for storing tension or compression test data of the specimen as necessary.

The control unit 170 may be provided with an interface connected to the outside, or may be controlled through an external PC through an interface.

According to the present invention, first, the base 110 is formed using a plate or the like. In this case, the base 110 is provided with a wheel so as to be movable, and the inside of the base 110 is configured to have a predetermined space to install the control unit.

Thereafter, a motor 151 is installed in the base 110 and a housing 155 is installed on the upper surface of the base so as to be positioned above the motor 151.

In this state, a pair of screws 154 are installed using a bearing so that the housing 155 passes through in the horizontal direction, and a driven shaft 153 connected to the end of the screw 154 is installed. And a belt 152a surrounding the pulley 152 is connected after the pulley 152 is coupled to the driven shafts 153 and the motor so that the screw can be operated according to driving of the motor.

Next, a pair of guide rails LM are installed horizontally to penetrate the housing 155, and the conveying table 156 is coupled to the screw 154 in a state of being mounted on the guide rail LM. And is coupled to the extension shaft 157 so as to penetrate the housing 155 in a state of being coupled to one side of the feed belt 156 (left direction in the drawing).

The extension shaft 157 thus engaged is inserted or pulled out to the housing side in accordance with the rotation direction of the screw.

Next, the transfer block 128 is coupled to the end of the extended extension shaft 157 and guided in a state in which the guide rail LM is mounted thereon, and the transfer block 128 is vertically extended And the pressure cylinder 142 is fixed to the block 143a after the block 143a is installed. Here, the pressurizing cylinder 142 is provided with a pressing fixture 141 having a concavo-convex shape.

Next, one side of the second specimen pedestal 124 of the lower specimen holder 122 is fixed to the conveyance block 128 via the block 143a fixed to the conveyance block 128. At this time, the binding piece and the groove formed on the lower specimen holder 122 are directed to the opposite direction of the transfer block.

Next, a temperature control unit 180 is installed on the lower part of the lower specimen fixing table 122 to support the lower specimen fixing tables 121 and 122 after striking another lower specimen fixing table 121 so as to be staggeredly coupled to the binding specimen fixing table 122 do.

Next, a support block 127 is installed so that one side of the lower specimen fixing table 121 is fixed to the base 110.

Next, a block 143b is installed so as to extend in a vertical direction while being fixed to one side of the support block 127, and a pressurizing cylinder is installed in the block 143b. Here, the same fixed unit 140 is provided in each of the blocks 143a and 143b.

In this state, the upper specimen fixture 125 is detachably mounted on the lower specimen fixture 121 fixed to the support block 127 and the upper specimen fixture 125 is fixed on the lower specimen fixture 122 fixed to the transfer block 128 The upper specimen holder 126 is detachably placed. At this time, the upper specimen fixture (125, 126) is bound in the same manner as the lower specimen fixture.

In the specimen supporting unit thus installed, the center portion of the specimen is supported by the upper and lower fixing members while the upper and lower fixing members are positioned between the supporting block and the transfer block, and both ends are fixed by the pair of fixing units, So that it can be fixed uniformly as a whole.

Next, four supports 139 are installed along the perimeter of the specimen supporting unit 120, and then the fixing plate 161 is coupled to the fixing table 139 so as to surround the fixing unit 140 .

Thereafter, a roller block 162 provided with a roller 163 is positioned and fixed on the upper surface of the fixing plate 161.

Next, a pair of guide plates 135a are installed to be positioned on the guide unit, a first pressing shaft 135 passing through the center of the guide plate 135a is inserted, and the first pressing shaft 135 is inserted, Four second pressing shafts 134 are provided around the first pressing shaft 134 and the second pressing shaft 134 to allow uniform load transfer through the first pressing shaft and the second pressing shaft.

Next, the upper and lower ends of the first and second pressing shafts are fastened using the support bracket 133, and then the shaft fixing bracket 137 is installed so as to extend in the vertical direction at the center of the upper surface of the upper support bracket.

Next, a horizontal bar 138 is rotatably installed on the upper end of the fixing bracket 127 using a fixing shaft 138b, and then the supporting block 136 is engaged with the upper guide plate 135a.

Thereafter, the horizontal bar 138 is coupled to the support block 136 using a rotation shaft 138a so as to be rotatable with respect to the support block 136, and a counterweight 138c having a predetermined weight is coupled to one end of the horizontal bar 138.

Next, a link 138e having a predetermined length in the vertical direction is extended to the other end of the horizontal bar 138 on which the balance weight 138c is installed, and then a seating plate 138d in the form of a plate is coupled to the end of the link 138e So that the weight 138f can be seated on the seating table 138d.

 The weight of the counterbalance 138c is determined by the weight of one side of the horizontal bar 138 divided by the fixed shaft 138b and the weight of the link 138e and the seat 138d provided at the end of the horizontal bar 138 The length of the horizontal bar 138 may be adjusted by controlling the length of the horizontal bar 138 in order to maintain the bacterium.

The static load unit thus combined can set a load to be transmitted to the pressurizing unit through the weight of the weight mounted on the mounting table. Since the load to be transmitted is always constant, the uniform load of the specimen supporting unit It is possible to keep the measured values to be obtained uniformly at all times even if tensile or compressive force is generated in the dynamic load-bearing unit.

Hereinafter, an operation state of the present invention will be described with reference to the accompanying drawings.

Referring to FIGS. 7 and 8, the pair of upper specimen fixing bars 125 and 126 are removed from the pair of lower specimen fixing bars 121 and 122, and the specimen PT is placed on the upper surface of the lower specimen fixing bars 121 and 122. Thereafter, the upper specimen strips 125 and 126, which have been removed so that the upper surface of the specimen PT is pressed and fixed, are engaged with the lower specimen strips 121 and 122, respectively.

At this time, the test piece PT is supported by the first and second test piece holders 123 and 123 formed on the pair of lower test piece holders 121 and 122, both ends of which are bound by the upper and lower test piece holders 125 and 126 and the lower test piece holders 121 and 122, And is seated in the state exposed to the pedestal 124.

Next, a weight 138f is placed on the seat cushion 138d by a load to be applied, and the pressing cushion 131 positioned above the upper specimen cushions 125 and 126 is guided by the guide unit 160 So that the upper specimen fixing members 125 and 126 are pressed and supported.

Next, the pressing cylinder 142 of the fixed unit 140 positioned above the specimen supporting unit 120 is operated to lower the pressure fixing bar 141 to expose the first and second specimen supports 123 and 124 The upper surface of the specimen (PT) is pressed and fixed.

At this time, the specimen supporting unit 120 may be heated to have a predetermined temperature through the temperature adjusting unit 180 installed at the lower part.

That is, it can be selectively applied according to the test conditions of specimen because it is heated under test or tested at room temperature.

Also, when the test is performed at a temperature lower than room temperature, it is also possible to operate the test piece at a temperature lower than room temperature by operating only the cooling line in the temperature control unit.

9, a dynamic loading unit 150 connected to the sample supporting unit 120 is operated in a state of being fixed to the sample supporting unit 120 to apply tensile or compressive force to the sample PT To stretch or compress the specimen.

At this time, when the specimen (PT) generates a constant frictional force between the upper specimen holder and the lower specimen holder due to the load applied from the static load unit, the tension and compression process are performed. Since the coefficient will have a large effect on the measured value, the frictional force must be kept constant at all times.

That is, the tensile or compressive force applied to the specimen PT causes the specimen to be tensioned and compressed, and the thickness T varies. In the past, a load transferred from the pressing force pressing the specimen due to the changed thickness As a result, the measurement value through the specimen changes, which makes it difficult to accurately measure the specimen. However, even if the thickness of the specimen changes due to the weight, the load is constantly transferred to the specimen The change of the frictional force is minimized, and the test measurement value of the specimen can be stably obtained.

For example, even if the load P applied from the static load unit changes from the thickness "T" to the thickness "T1" of the specimen PT as shown in FIG. 10, the load P does not change uniformly, It is possible to uniformly measure the tensile compression test value due to the constant occurrence of the frictional force according to the thickness variation.

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 will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. There is no doubt that it is within.

100: Test apparatus 110: Base
120: specimen support unit 130: static load unit
140: fixed unit 150: dynamic load unit
160: guide unit 170: control unit
180: Temperature control unit

Claims (10)

A specimen support unit on which the specimen is seated;
A static load load unit for pressing and fixing the specimen placed on the specimen support unit in a vertical direction;
A fixing unit for supporting both ends of the specimen placed on the specimen supporting unit;
A dynamic load load unit operable to apply a tensile force or a compressive force to the specimen placed on the specimen support unit;
A temperature control unit for controlling the temperature of the specimen placed on the specimen support unit to have a constant temperature; And
And a control unit for detecting a load and a change state from the specimen in accordance with the operation of the dynamic load load unit and controlling the operation of each of the structures. The method according to claim 1,
And a guide unit for guiding the lifting and lowering of the static load load unit to the upper portion of the specimen supporting unit. 3. The method of claim 2,
The specimen supporting unit includes a supporting block mounted on an upper surface of the base, a transport block provided on one side of the supporting block for moving in a moving direction of the dynamic load loading unit, and a transport block disposed between the supporting block and the transport block, A lower specimen fixing table, and an upper specimen fixing table provided above the lower specimen fixing table. The method of claim 3,
Wherein the lower specimen holder is further formed with first and second specimen holders for allowing the specimen to be pressed and fixed to the lower specimen holder by a fixing unit. The method of claim 3,
Wherein the lower specimen holder and the upper specimen holder are each formed of a pair and each of the lower specimen holder and the upper specimen holder is provided to be engaged with each other. The method according to claim 1,
Wherein the static load applying unit comprises a pressing unit for pressing the specimen supporting unit, an extension unit extending to the upper portion of the pressing unit, first and second pressing shafts for vertically guiding the extension unit, A horizontal bar connected to an upper portion of the shaft by an axial fixing bracket, a balance weight provided at one side of the horizontal bar to maintain balance of the weight on both sides of the horizontal bar with respect to the fixed shaft and a seat placed on the other side of the balance weight, And a weight attached to the seat so as to generate a load applied to the sample supporting unit. The method according to claim 1,
Wherein the dynamic load load unit comprises an extension shaft connected to the specimen support unit, a conveyance belt for fixing the extension shaft, a screw connected to the conveyance belt for horizontally moving the extension shaft, and a motor for operating the screw Wherein the tensile compression test apparatus is a horizontal type tensile compression testing apparatus. 5. The method of claim 4,
Wherein the fixing unit is composed of a pressure cylinder and a pressure fixing bar provided at the end portion of the pressure cylinder, and a concavity and convexity are formed at the end portion of the pressure fixing bar. 3. The method of claim 2,
Wherein the guide unit comprises a fixed plate for supporting the static load unit, a roller block fixed to the fixed plate, and a roller rotatably fixed to the roller block. . 11. The method of claim 10,
Wherein the roller block is adjustable in position on the upper surface of the fixed plate.

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