JP2003083857A - Creep testing machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a creep testing machine allowing a person to precisely know the point of time a test piece is actually loaded to a test piece and obtain precise data even for a material having a deforming characteristic sensitive to the loading of a resin or the like. SOLUTION: This creep testing machine for loading the test piece W and measuring the time-lapse deformation quantity caused in the test piece W comprises a load measuring instrument 14 for measuring the load applied to the test piece W side; and a displacement measuring instrument 15 for measuring the displacement caused on the test piece side, so that the load applied to the test piece W side and the displacement caused on the test piece W side during test are measured with the lapse of time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a creep tester for testing the creep property of a material, and more particularly to a creep tester effective for a material having a deformation property sensitive to a load such as a resin.

[0002]

2. Description of the Related Art In a creep test, a constant load is continuously applied to a test piece, and the deformation that occurs in the test piece is detected over time, so that the long-term deformation characteristics and rupture characteristics of a material against a continuous load are applied. Has been used to obtain. Particularly in the old days, a creep test is often performed on a metal material or the like, and the deformation gradually progresses over a long period of time, so that the time precision is not so much required for the measurement accuracy. On the other hand, in recent years, as the adoption of high-performance resin parts in, for example, automobile parts has expanded, dimensional accuracy, strength characteristics, deformation characteristics, etc. of resins used in such high-performance resin parts have become severely required. Came. As a result, strict data has come to be required even when a creep test is performed on a complex resin that is more sensitive to deformation than a metal material or the like due to load. Further, since the development of such high-performance resin parts as described above requires a great deal of cost and development time, by computer assisted technology, so-called CAE, for example, by predicting the thermal deformation amount of the resin parts in a high temperature environment, Efforts have been made to reduce the development period and the development cost. In order to improve the prediction accuracy of the thermal deformation of the resin part by CAE, it is necessary to accurately predict the creep deformation amount of the resin part, and the resin which should be the basic data for the accurate prediction. Accurate data from material creep testing has been needed.

[0003]

However, in many conventional creep testers, even if a displacement measuring instrument for measuring the amount of deformation of the test piece is installed, a load measuring instrument for measuring the load actually applied to the test piece side. Since many are not provided as unnecessary, it is not possible to accurately detect when the load application means such as a weight is actually applied to the test piece. Further, in the conventional creep tester, after setting the test piece with a chuck or the like, placing it in a high temperature atmosphere or the like to control the temperature, and then applying a load by a load applying means such as a weight to start the test. It is common. However, in these conventional testers, when the test piece is set with a jig such as a chuck, the load of the jig acts on the test piece, so that it seems that the resin has deformation characteristics sensitive to small loads. However, with such materials, there is a problem that an accurate test cannot be performed because the deformation of the material is started. Furthermore, in the case of a metallic material, even if the starting time when the load is actually applied to the test piece is somewhat unclear, elastic deformation occurs first, and then creep deformation, etc. Although it is possible to set the starting point of creep deformation at any time, in the case of resin material, when tensile or compressive stress acts, elastic deformation, viscoelastic deformation, and creep deformation are superimposed from the beginning. Therefore, there is a problem that the creep test cannot be accurately performed unless the start time point when the load is actually applied to the test piece is accurately obtained. In order to accurately separate elastic deformation, viscoelastic deformation, and creep deformation that are superposed on the resin material, perform a load / unload test and accurately measure the change in load and the change in deformation at that time. However, there is no conventional creep tester that can accurately measure both such load and displacement.

Therefore, the present invention solves the above-mentioned problems in the conventional creep testing machine, can accurately know the time when the load is actually applied to the test piece, and deforms sensitive to the load such as resin. It is an object to provide a creep testing machine that can obtain accurate data even for materials having characteristics.

[0005]

The creep testing machine of the present invention for solving the above-mentioned problems is a creep testing machine for applying a load to a test piece and measuring the amount of time-dependent deformation of the test piece. A weight that is a constant load is used as a load applying means, and a load measuring device that measures the applied load on the test piece side and a displacement measuring device that measures the displacement generated on the test piece side are added to the test piece side during the test. The first feature is that the applied load and the displacement generated on the test piece side are measured with time. In addition to the first feature, the creep testing machine of the present invention sets the test piece so that no load is applied, and first starts measurement of the load applied to the test piece side by the load measuring device and measures the displacement. Start measuring the displacement caused on the test piece side by the instrument,
The second feature is that the load on the test piece side is started after or simultaneously with the start of the measurement. In addition to the above-mentioned second characteristic, the creep testing machine of the present invention has a play in the middle of the load transmitting means for transmitting the load of the weight to the test piece so that the load on the side of the test piece is 100% from zero. A third feature is that the change in the load and the change in the displacement on the side of the test piece are measured over time during the transition to the load. Further, in addition to the above-mentioned third feature, the creep tester of the present invention sets the actual creep test start point at the time point when the measured load value applied to the test piece side is 100% of the weight, and at that time point. The fourth feature is that the displacement measured by the displacement measuring device is set as the zero point of the deformation amount of the test piece.

According to the first feature, the load applied to the test piece side during the creep test is used as a reference load and the actual load applied to the test piece side is measured by the load measuring device, and the displacement generated on the test piece side during the creep test is measured. The displacement measuring device can accurately measure each. Therefore, the actual load and the amount of deformation applied to the test piece during the entire test from the start of the creep test can be accurately obtained with time, and accurate creep test data can be obtained. In addition, since the load measurement and the displacement measurement can be accurately performed from the start of the creep test, it is possible to accurately know at what time after the creep test the load becomes the reference load that is the weight load. Become. In addition, even when performing a load / unload test, it is possible to accurately obtain the load applied to the test piece and the amount of deformation over time, and the elastic deformation and viscous force caused by overlapping in the resin material, etc. It is possible to know elastic deformation and creep deformation accurately.

According to the second feature, in addition to the function and effect of the first feature, the creep test is started from a state where no load is applied to the test piece, so that the creep test is started before the start of the creep test. It is possible to eliminate the adverse effect on the test data due to the application of some applied load, especially to the data on the material having delicate deformation characteristics even for a small load such as a resin material. In addition, since the load measurement with the load measurement device and the displacement measurement with the displacement measurement device are started from the state where no load is applied, the creep load is started on the test piece side after that. It is possible to accurately measure at what point in time the load is actually applied to the test piece side, and more accurate data regarding the actual start point of the creep test can be obtained.

According to the third feature, in addition to the effect of the second feature, a play is provided in the middle of the load transmitting means for transmitting the load of the weight to the test piece. To more reliably measure the change over time of the applied load from the time when the applied load is zero to 100% load and the change over time of the displacement occurring on the test piece side during that time with the time generated by the play. You can Therefore, from the start of the creep test until the 100% load is applied, what kind of load and displacement actually occur on the test piece side, and when the 100% load is reached, the displacement measuring device detects It is possible to accurately measure the displacement on the side of the test piece to be measured, and to make a more accurate determination of the starting point of the actual load application to the test piece in the creep test and the origin of the deformation amount measurement of the test piece. You can get the data.

According to the fourth feature, in addition to the action and effect of the third feature, the actual creep test starting point is set at the time when the measured load applied to the test piece side becomes 100% of the weight. And by setting the displacement measurement value at that time as the displacement measurement zero point of the test piece, the actual test start time in the creep test can be accurately obtained, and the actual test start time By subtracting the measured displacement amount at the actual test start point (zero deformation amount point of the test piece) from the displacement amount measured after that, the actual deformation amount generated in the test piece can be obtained accurately. .

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the creep testing machine of the present invention will be further described below with reference to the drawings. Figure 1
FIG. 2 is a schematic configuration diagram of a creep testing machine showing an embodiment of the present invention, FIG. 2 is a detailed view of a part of the creep testing machine, (A) shows a set state of test pieces before the start of testing, (B) FIG. 3 is a diagram showing a state of a test piece during a test. FIG. 3 is a time (second) -load load curve and time (second) -displacement curve diagram at the beginning of the creep test, and FIG. 4 is a time showing a result of a tensile creep test of a resin material using the creep tester of the present invention. FIG. 5 is a typical example of a time-displacement curve showing the result of a load / unload test of a resin material using the creep tester of the present invention.

1 and 2, reference numeral 1 is a weight as a load applying means. The weight 1 is raised and lowered by a weight raising and lowering jack 3 installed on a jack support base 4,
The load of the weight 1 is applied to the test piece W side by being placed on the weight support tool 2 at the lower end of the weight rod 5.

A balance lever 8 having the weight rod 5 attached to one end side is supported by a balance lever support 7 like a balance. Reference numeral 6 denotes a balance adjusting weight, which is moved left and right to adjust the balance of the balance lever 8. The balance adjusting weight 6 can be provided on one side or both sides of the balance lever support base 7.

A test piece rod 9 is attached to the other end of the balance lever 8. The rod 9 for a test piece and the rod 5 for a weight are attached to the balance lever 8 so that the balance lever 8 hangs vertically regardless of the posture of the balance lever 8. An upper U-link 9a is provided at the lower end of the test piece rod 9. The upper U-link 9a is connected to the upper chuck 11a by a pin 13. The upper chuck 11
The a grips the upper end side of the test piece W. On the other hand, a fixing rod 10 is fixed to the main body fixing portion 12 of the device corresponding to the test piece rod 9, and a lower portion U is attached to the upper end of the fixing rod 10.
A link 10a is provided. The lower U-link 10a is connected to the lower chuck 11b by a pin 13.

Lower U-link 10a of the fixed rod 10
An elongated hole 10b is provided as a hole through which the pin 13 is inserted, so that "play" can be performed between the lower U-link 10a and the lower chuck 11b connected by the pin 13. Further, the lower chuck 11b has the long hole 1
It is configured so that it can be placed on the lower U-link 10a by 0b, that is, a state of supporting the weight (see FIG. 2A). Weight rod 5, balance lever 8, test piece rod 9, upper U-link 9
The a, the fixed rod 10, the lower U-link 10a, the upper chuck 11a, the lower chuck 11b, and the pin 13 serve as load transmitting means for transmitting the load of the weight 1 to the test piece W. The "play" is formed in the middle of the load transmitting means. Weight 1 by this play
There is a time delay when the load due to is applied to the side of the test piece W, and a change in the applied load occurs during that time.

Reference numeral 14 is, for example, a load measuring device comprising a load cell, which is provided at an intermediate position of the rod 9 for a test piece.
The load applied to the test piece W side is measured. Further, reference numeral 15 is a displacement measuring device, which can be composed of, for example, a laser displacement meter 15a and a laser displacement meter plate 15b attached at an intermediate position of the rod 9 for a test piece, and measures the displacement generated on the side of the test piece W. . Reference numeral 16 is a constant temperature bath, and 17 is a temperature sensor. 18 is a heat shield plate. By providing the constant temperature layer 16, the creep test can be performed in a predetermined temperature atmosphere.

The device may be provided with a controller 19. The controller 19 inputs the data from each sensor, such as the load load data measured by the load load measuring device 14, the displacement data measured by the displacement measuring device 15, the temperature information measured by the temperature sensor 17, and the like,
Also, the operation of the jack 3 for lifting and lowering the weight, the load measuring device 1
4 and the displacement measuring device 15 are commanded to start and stop the measurement at predetermined timings, and also control the operation of each part of the device.

The test piece W is set in the tester as follows. Now, by raising the weight raising / lowering jack 3, the weight 1 is kept retracted upward from the weight support 2 of the weight rod 5, and the test piece W is first moved to the upper chuck 1.
Attach to 1a. The upper chuck 11a to which the test piece W is attached is attached to the upper U-link 9a with the pin 13. Next, the balance adjusting weight 6 is adjusted so that the balance lever 8 becomes horizontal. And the upper U-link 9a
Then, the upper chuck 11a is once removed. Next, test piece W
Attach the lower chuck 11b to the upper chuck 1 again.
1a is attached to the upper U-link 9a with the pin 13. The lower chuck 11b holding the test piece W is fixed to the fixed rod 1
0 on the lower U-link 10a. Then, the pin 13 connects the lower chuck 11b and the lower U-link 10a.
In this state, the test piece W is supported from below by the lower U-link 10a via the lower chuck 11b, and no load is applied to the test piece W. Also the lower U-link 10a
The long hole 10b causes the test piece W to move to the lower chuck 11b.
It becomes a state of being connected with "play" with the lower U-link 10a via. If necessary, the constant temperature layer 16 is heated to a predetermined temperature. With the above, the setting of the test piece W is completed.

After the setting of the test piece W is completed, the test operator turns on the test start switch of the controller 19 to start the creep test. Controller 1
Reference numeral 9 commands the descent of the weight lifting / lowering jack 3 on which the weight 1 is placed from the raised position, and starts measurement by the load measuring device 14 and the displacement measuring device 15 before the weight 1 is placed on the weight support 2. Let Of course, the command for the lowering operation of the jack 3 for lifting and lowering the weight and the command for starting the measurement of the load measuring device 14 and the displacement measuring device 15 can also be performed by a manual switch operation by the test operator. In short, the load measuring device 14
Then, the measurement of the displacement measuring device 15 is started in advance, and the load load by the weight 1 may be applied to the test piece W side later or at the same time.

When the measurement by the load measuring device 14 and the displacement measuring device 15 is started prior to the load of the weight 1 as described above, the load measuring value on the test piece W side by the load measuring device 14 becomes Always start from zero. This is because the test piece W is initially supported on the lower U-link 10a via the lower chuck 11b.

From the time when the weight 1 is placed on the weight support 2, the test piece W and the lower chuck 11b start to rise through the balance lever 8, the test piece rod 9, the upper U-link 9a, and the upper chuck 11a. Then, the displacement measuring device 15 detects the displacement on the side of the test piece W. However, this displacement is a displacement caused by the movement of the pin 13 in the "play" portion of the elongated hole 10b, and is not due to the deformation of the test piece W. The load of the weight 1 is not applied during the "play". The lower part U during this "play"
The weight of the lower chuck 11b separated from the link 10a is measured by the load measuring device 14. Further, when the "play" by the elongated hole 10b is completed, after that time, the total load of the weight 1 is applied to the test piece W, and the load measurement value by the load measuring device 14 on the test piece W side is 100% of the weight 1. It becomes a load. Therefore, by setting the time when the applied load measuring device 14 detects the 100% load of the weight 1 as the start time of the actual creep test, the start time of the creep becomes accurate and the creep deformation of the resin material or the like starts from the beginning of the load application. Accurate data with no time error can be obtained with respect to the resulting material and also to the material in which creep proceeds in a relatively short time. The load measuring device 1
The time when 4 detects the 100% load of the weight 1 can be automatically detected in the controller 19. Of course, the operator may later examine the obtained time-load load curve to determine the time when the load reaches 100% load of the weight 1.

[0021] In addition to obtaining the actual start time of the creep test by capturing the change in the measured load value, the change in the amount of displacement that occurs when the "play" ends in the "play" portion is large. It is also possible to catch the time when the inclination of the displacement curve changes significantly and set it as the start time of the actual creep test.

FIG. 3 shows time (seconds) -load load curve and time (seconds) at the beginning of the creep test conducted in a predetermined atmosphere using the present creep tester for a resin material.
-A displacement curve. The time axis is small and the load and displacement are measured every 0.2 seconds. In the figure, when the creep test is started at the time when the measurement by the applied load measuring device 14 and the displacement measuring device 15 is started (time 0), after the start of the measurement by the applied load measuring device 14 and the displacement measuring device 15. Four
Until the second, the weight 1 has not yet been placed on the weight support 2. Therefore, the displacement detected by the displacement measuring device 15 is zero, and the test piece W is the lower chuck 11.
Since it is supported on the lower U-link 10a via b, the load detected by the load measuring device 14 is substantially zero.

At the time of 2.6 seconds from the start, the weight 1 is placed on the weight support 2 and the load of the weight 1 is applied to the test piece W side, so that the displacement is started on the test piece W side. I understand. However, the displacement generated here is not due to the deformation of the test piece W, but is merely due to the displacement measuring device 15 capturing the displacement due to the movement of the pin 13 in the elongated hole 10b. That is, it is the displacement caused by the "play" portion. Also, slightly later than the start of the displacement (2.
8 seconds), the value of the load applied by the load measuring device 14 slightly increased from substantially zero, and this value continues to be a constant value until 4.8 seconds. During this time, the lower chuck 11b is separated from the lower U-link 10a, and the weight of the lower chuck 11b and the like is detected as the load on the test piece W side. Then, from 4.8 seconds to 6.4 seconds from the start of the test, as the transition period just before the "play" ends, a state in which the measured load load is rapidly increasing is measured, and "play" The large amount of displacement in the non-resistance state during the period between “,” and the state in which the amount of displacement decreases due to the generation of resistance are measured.

After 6.4 seconds from the start of the test, the value measured by the load measuring device 14 becomes a constant value. This constant value is exactly the load of the weight 1. That is, it can be seen that the loaded load reached 100% of the weight 1 at 6.4 seconds after the start of the test. From this point, the load of the weight 1 is actually the test piece W.
Therefore, this time is set as the actual creep test start time, that is, the actual time-strain curve start time of the test piece W in the creep test. In the case of resin material,
Since creep deformation occurs together with elastic deformation and viscoelastic deformation immediately after the start of the load of the weight 1 actually applied to the test piece W, the actual creep test start time (6.4 seconds from the start of the test). Is important. The actual creep test start time (6.4 seconds from the start of the test) is the zero point of creep deformation (strain) of the test piece W. That is, it is considered that the displacement measured by the displacement measuring device 15 before that is not due to the creep deformation generated in the test piece W. As a result, the amount of creep deformation that occurs in the test piece W itself can be measured more accurately.

FIG. 4 shows a tensile creep test of a resin material under an atmosphere of 110 ° C. under a test stress (load of weight 1 ÷ sectional area of test piece W) of 1.96 MPa using this creep tester. Is a time (minute) -strain curve in which the above-mentioned actual creep test start time point is expressed as time point 0. Here, the time axis is large. It can be seen that the strain is large in the first 100 minutes or so after the start of the test, and then becomes small. Further, the strain progresses in a shorter time than in the case of using a metal material or the like. An accurate time-strain curve can be obtained by obtaining the actual test start point in the initial test start.

FIG. 5 is a typical example of a time-displacement curve showing a result of a load / unload test of a resin material while measuring a load and a displacement using the creep tester of the present invention. The 0 point on the time axis is the load start point. In the figure, the immediate recovery amount D of the displacement at the time of unloading is the elastic deformation amount, the slowly recovering amount N is the viscoelastic deformation amount, and the unrecoverable amount K is the creep deformation amount.

[0027]

According to the creep tester of the first aspect of the present invention, the creep tester applies a load to the test piece and measures the amount of deformation of the test piece over time. A tester, which uses a weight that is a constant load as the load applying means, comprises a load measuring device that measures a load applied to the test piece side, and a displacement measuring device that measures the displacement generated on the test piece side, Since the load applied to the test piece side and the displacement generated on the test piece side during the test were measured over time, the weight load was used as a reference load,
The actual load applied to the test piece side during the creep test can be accurately measured by the load measuring instrument, and the displacement generated on the test piece side during the creep test can be accurately measured by the displacement measuring instrument. Therefore, the actual load and the amount of deformation applied to the test piece during the entire test from the start of the creep test can be accurately obtained with time, and accurate creep test data can be obtained. In addition, since the load measurement and the displacement measurement can be accurately performed from the start of the creep test, it is possible to accurately know at what time after the creep test the load becomes the reference load that is the weight load. Become. Also, when performing a load / unload test, it becomes possible to accurately obtain the load applied to the test piece and the amount of deformation over time.
It is possible to accurately distinguish and know the elastic deformation, the viscoelastic deformation, and the creep deformation that are generated in the resin material and the like in a superimposed manner. As described above, accurate data can be obtained even for a material that is sensitive to a load such as a resin and has a deformation characteristic that causes large creep deformation in a relatively short period of time. Further, according to the creep tester according to claim 2,
In addition to the effect of the configuration according to claim 1, the test piece is set so that no load is applied, first the measurement of the load applied to the test piece side is started by the load load measuring instrument, and the test piece side is measured by the displacement measuring instrument. Since the measurement of the displacement occurring at the start was started and the load on the test piece side was started after the start of this measurement or at the same time, the adverse effect on the test data due to the application of some load before the start of the creep test, Particularly, even for a small load such as a resin material, it is possible to eliminate a bad influence on data of a material having a delicate deformation characteristic. In addition, since the load measurement with the load measurement device and the displacement measurement with the displacement measurement device are started from the state where no load is applied, the creep load is started on the test piece side after that. It is possible to accurately measure at what point in time the load is actually applied to the test piece side, and more accurate data regarding the actual start point of the creep test can be obtained. According to the creep testing machine of claim 3, in addition to the effect of the configuration of claim 2, a play is provided in the middle of the load transmitting means for transmitting the load of the weight to the test piece, and the test piece side is provided. Since the change in the load on the test piece side and the change in the displacement are measured over time during the transition from the zero load to 100% load, the load applied to the test piece is 100 from zero
It is possible to more reliably measure the change with time of the applied load until the load reaches% and the change with time of the displacement occurring on the side of the test piece during that time with the time generated by the play. Therefore, 10 after starting the creep test
By the time 0% load is applied, what kind of load and displacement actually occurred on the test piece side, and 100%
It is possible to accurately measure the displacement on the side of the test piece detected by the displacement measuring instrument when a load is applied, determine the actual starting point of load application to the test piece in the creep test, and deform the test piece. More accurate data can be obtained regarding the determination of the origin in the quantity measurement. Further, according to the creep tester of claim 4, in addition to the effect of the configuration of claim 3, the time when the measured value of the load applied to the test piece side is 100% of the weight is actually measured. The creep test start point was used, and the displacement measurement value at that time was used as the zero point for the amount of deformation of the test piece, so the actual test start point in the creep test can be accurately obtained, and the actual By subtracting the measured displacement at the actual test start time (zero deformation point of the test piece) from the displacement measured after the test start time, the actual deformation amount generated in the test piece can be obtained accurately. be able to.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a creep testing machine showing an embodiment of the present invention.

FIG. 2 is a detailed view of part of the creep tester, (A) showing a set state of the test piece before the start of the test, and (B) showing a state of the test piece during the test.

FIG. 3 is a time (second) -load load curve and a time (second) -displacement curve diagram at the beginning of the creep test.

FIG. 4 is a time (minute) -strain curve diagram showing the results of a tensile creep test of a resin material using the creep tester of the present invention.

FIG. 5 is a typical example of a time-displacement curve showing the results of a load / unload test of a resin material using the creep tester of the present invention.

[Explanation of symbols]

1 weight 2 weight support 3 Jack for lifting and lowering weight 4 jack support 5 Weight rod 6 Balance weights 7 Balance lever support 8 balance lever 9 Test piece rod 9a Upper U-link 10 fixed rod 10a Lower U-link 10b long hole 11a Upper chuck 11b Lower chuck 12 Main body fixing part 13 pin 14 Load measuring device 15 Displacement measuring device 15a Laser displacement meter 15b Laser displacement gauge plate 16 constant temperature bath 17 Temperature sensor 18 Heat shield 19 Controller W test piece

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Kaoru Inoue             1 Toyota Town, Toyota City, Aichi Prefecture Toyota Auto             Car Co., Ltd. (72) Inventor Yuichi Miyake             1 Toyota Town, Toyota City, Aichi Prefecture Toyota Auto             Car Co., Ltd. F-term (reference) 2G061 AA01 AB02 AC03 CA10 EA01                       EA02 EB05 EB07

Claims (4)

[Claims] 1. A creep tester for applying a load to a test piece to measure the amount of deformation of the test piece over time, wherein a weight having a constant load is used as the load applying means and is applied to the test piece side. Equipped with a load measuring device that measures the applied load and a displacement measuring device that measures the displacement that occurs on the test piece side, so that the load applied to the test piece side and the displacement that occurs on the test piece side during the test can be measured over time. Creep tester characterized by 2. The test piece is set so that no load is applied, and first, the measurement of the load applied to the test piece side is started by the load measuring instrument, and the displacement generated on the test piece side is started by the displacement measuring instrument. The creep tester according to claim 1, wherein the load on the test piece side is started after or at the same time as the start of the measurement. 3. A load transmission means for transmitting the load of the weight to the test piece is provided with a play in the middle thereof, and the load on the test piece side changes from zero to 100% load while the load on the test piece side changes. The creep testing machine according to claim 2, wherein a change in applied load and a change in displacement are measured with time. 4. The actual creep test starting point is when the measured load value applied to the test piece side reaches 100% load of the weight, and the measured displacement value measured by the displacement measuring instrument at that time is the deformation of the test piece. 4. A quantity zero point is set.
The creep testing machine described in.