JPH0435792Y2 - - Google Patents

Description

[Detailed explanation of the invention] (a) Industrial application field This invention relates to a material testing machine for testing the material of test pieces.

(b) Prior Art For example, when testing a specimen for fatigue, a testing machine that repeatedly applies a load to the specimen using a load rod of a hydraulic actuator is generally used. To apply repeated loads, the specimen may be chucked using a grip attached to the loading rod. Then, when hydraulic pressure is supplied to the actuator, a load is repeatedly applied to the specimen by the load rod. The specimen can therefore be fatigue tested. However, in this case, when the hydraulic pressure of the hydraulic actuator is discharged during a power outage, the weight of the specimen, the load rod, and the grip act on the specimen, and a large static load is applied to the specimen. For this reason, accurate test data cannot be obtained even if the specimen is continuously tested after being energized. The specimen may be damaged by the weight of the specimen, load rod, and grips. Therefore, it was necessary to use a new specimen and conduct the test again from the beginning. In addition, even if the hydraulic power source is stopped in an emergency, the hydraulic pressure of the hydraulic actuator is discharged, and the weight of the specimen, load rod, and grip acts on the specimen. The same applies when the hydraulic power source and hydraulic actuator fail.

(c) Purpose Therefore, this invention is designed to use a material testing machine that applies a test load to a specimen using a load member such as a load rod, so that the weight of the specimen and load member can be applied in the event of an emergency such as a power outage. Does not affect the sample,
This was done to prevent any load other than the test load from being applied to the specimen.

(D) Configuration According to this invention, in a material testing machine equipped with a load member such as a load rod so as to be displaceable in the vertical direction, the load member applies a test load in the vertical direction to the specimen. A fluid pressure jack is arranged below the load member, the jack is connected to a fluid pressure source, a solenoid valve is provided between the jack and the fluid pressure source, and the jack is biased by a fluid pressure accumulator, a compression spring, etc. means for supplying fluid pressure from the fluid pressure source to the jack during the test, evacuating the jack from the load mechanism by the fluid pressure, and reducing the fluid pressure of the jack by the solenoid valve in an emergency. There is provided a material testing machine characterized in that the jack is discharged and the jack is pressed against the load member by the biasing force of the biasing means to support the weight of the specimen and the load member.

(E) Embodiments Hereinafter, embodiments of this invention will be explained with reference to the drawings.

In FIG. 1, a specimen 1 is chucked by a pair of upper and lower grips 2H and 2L.
This testing machine is designed to repeatedly apply a load to the specimen 1, and the lower grip 2L is attached to the load rod 4 of the hydraulic actuator 3. The actuator 3 has a servo valve 5, is mounted on the crosshead 6 of the test machine, and is connected to a pump 7 and a tank 8. The upper grip 2H is attached to the load cell 10 of the cross yoke 9.

In addition, a hydraulic jack 11 is installed below the load rod 4.
The jack 11 has a piston 12 and is connected to the pump 7 and the tank 8.
Further, a solenoid valve 13 is provided between the jack 11, the pump 7, and the tank 8. Further, in this embodiment, a hydraulic accumulator 14 is connected to the jack 11. The accumulator 14 has a gas bag 15 filled with gas.

In the material testing machine configured as described above,
When the electromagnetic valve 13 is energized and switched, hydraulic pressure from the pump 7 is supplied to the jack 11. Therefore, the piston 12 of the jack 11 is pushed down by the hydraulic pressure of the pump 7. The piston 12 is retracted from the load rod 4 and the load rod 4 is released from the piston 12.

After that, when the servo valve 5 is operated, the pump 7
hydraulic pressure is supplied to the actuator 3, and a load is repeatedly applied to the specimen 1 by the load rod 4. Also, the reaction force of the load on the specimen 1 is the load cell 1
0 to the specimen 1 by the load cell 10.
load is detected. Therefore, the specimen 1 can be subjected to a fatigue test.

Further, for example, when the pump 7 stops during a power outage, the hydraulic pressure of the actuator 3 is discharged to the tank 8. Therefore, the weight of the specimen 1, the load rod 4, and the grip 2L acts on the specimen 1, and there is a risk that a large tensile load will be applied to the specimen 1. cannot be added. When the pump 7 is stopped during a power outage, the energization of the solenoid valve 13 is also canceled and the solenoid valve 13 is automatically switched. Therefore, the hydraulic pressure of the jack 11 is discharged to the tank 8, and the oil pressure of the jack 11 is discharged to the tank 8.
The gas bag 15 expands, and the piston 12 of the jack 11 is pushed up by the oil pressure. The piston 12 is pressed against the load rod 4 and pushes it upward. Therefore, the jack 11 supports the weight of the specimen 1, the load rod 4, and the grip 2L. Therefore, even if the hydraulic pressure of the actuator 3 is discharged, the weight of the specimen 1, the load rod 4, and the grip 2L does not act on the specimen 1, and no large tensile load is applied to the specimen 1.
Therefore, if the test piece 1 is continuously tested after being energized, accurate test data can be obtained. There is no need to retake the test from the beginning.

In addition, if the configuration is such that the electromagnetic valve 13 is de-energized not only during a power outage but also when the pump 7 is stopped in an emergency, the weight of the specimen 1, load rod 4, and grip 2L is supported by the jack 11. A large tensile load was not applied to the specimen 1.
Therefore, in this case as well, accurate test data can be obtained by driving the pump 7 again and continuing testing the specimen 1. The same applies when the pump 7 and hydraulic actuator 3 fail.

It should be noted that various modifications of this invention can be considered in addition to the above-mentioned embodiments. For example, instead of the hydraulic accumulator 14 shown in FIG. 1, a fluid pressure accumulator that supplies fluid pressure other than hydraulic pressure may be used. In some cases, the jack 11 may be provided with a compression spring 16, as shown in FIG. 2, and the piston 12 may be pressed against the load rod 4 by the elasticity of the compression spring 16. In this case as well, the jack 11 can support the weight of the specimen 1, the load rod 4, and the grip 2L, and similar effects can be obtained.

FIG. 3 shows a test machine in which a bending load is applied to a specimen 18 by a pair of hydraulic actuators 17. Actuator 17 is connected to load rod 19
, the load rod 19 is connected to the bar 20,
The specimen 18 is attached to a bar 20. Therefore, when hydraulic pressure is supplied to the actuator 17, a bending load is applied to the specimen 18, and the specimen 1
8 can be bend tested. This testing machine also has a pair of hydraulic jacks 21 arranged below the bar 20. In an emergency such as a power outage, the piston 22 of the jack 21 is pressed against the bar 20, and the weight of the specimen 18, load rod 19, and bar 20 is supported by the jack 21.
Therefore, even if the hydraulic pressure of the actuator 17 is discharged, the weight of the specimen 18, load rod 19, and bar 20 does not act on the specimen 18, and the specimen 18
A large bending load cannot be applied to the FIG. 4 shows a test machine in which a vibration load is applied to a specimen 24 by a hydraulic actuator 23. The hydraulic actuator 23 has a load rod 25 and is connected to the specimen 2.
4 is supported by a table 26, which is connected to a load rod 25. Therefore, when hydraulic pressure is supplied to the actuator 23, the specimen 2
4 can be vibrated integrally with the table 26 to conduct a vibration test. Additionally, this testing machine has a pair of hydraulic jacks 27 placed below the table 26.
has. In an emergency such as a power outage, the piston 28 of the jack 27 is pressed against the table 26, and the weight of the specimen 24, load rod 25, and table 26 is supported by the jack 27.
Therefore, even if the hydraulic pressure of the actuator 23 is discharged, the specimen 24 and the table 26 do not fall. Therefore, there is no possibility that an impact load will be applied to the specimen 24.

(F) Effect As explained above, according to this invention, a load member such as the load rod 4 is equipped to be able to be displaced in the vertical direction, and a vertical test load is applied to the specimen 1 by the load member. In the material testing machine, a fluid pressure jack 11 is arranged below the load member, the jack 11 is connected to a fluid pressure source, and a solenoid valve 13 is provided between the jack 11 and the fluid pressure source,
The jack 11 is provided with biasing means such as a fluid pressure accumulator 14 and a compression spring 16. and,
During the test, fluid pressure from a fluid pressure source is supplied to the jack 11, and the jack 11 is retracted from the load member by the fluid pressure. Therefore, a test load can be applied to the specimen 1 by the load member. Furthermore, in an emergency such as a power outage, the fluid pressure in the jack 11 is discharged by the solenoid valve 13, and the jack 11 is pressed against the load member by the urging force of the urging means, so that the weight of the specimen 1 and the load member is supported. be done. Therefore, no load other than the test load is applied to the specimen 1, and the intended purpose can be achieved.

[Brief explanation of the drawing]

Fig. 1 is a sectional view showing an embodiment of this invention, Fig. 2 is a sectional view showing a modification of Fig. 1, and Figs. 3 and 4 show other test machines using this invention. FIG. 1... Specimen, 4... Load rod, 7... Pump, 8... Tank, 11... Jacket, 13...
Solenoid valve, 14...accumulator, 16...compression spring.

Claims (1)

[Scope of utility model registration request] In a material testing machine that is equipped with a load member such as a load rod that can be moved vertically and applies a test load in the vertical direction to a specimen using the load member, a fluid pressure jack is installed below the load member. The jack is connected to a fluid pressure source, a solenoid valve is provided between the jack and the fluid pressure source, and the jack is provided with biasing means such as a fluid pressure accumulator or a compression spring, and the jack is connected to the fluid pressure source during the test. of fluid pressure is supplied to the jack, the jack is evacuated from the load member by the fluid pressure, and in an emergency, the fluid pressure of the jack is discharged by the solenoid valve, and the urging force of the urging means is A material testing machine characterized in that the jack is pressed against the load member to support the weight of the specimen and the load member.