JPH043253Y2 - - Google Patents

Description

[Detailed explanation of the idea] Industrial applications The present invention relates to a material testing machine.

BACKGROUND ART An example of this type of material testing machine is a press.

Problems that the invention aims to solve However, there are currently no presses that operate at high speeds of 1 m/s or higher, and presses are generally designed for use in compression, so they cannot be used in tension. Although there are load generators with high capacity and tensile capacity, there are none that can be used at high speeds of 5 m/s or higher. When it comes to high capacity and high speed,
Existing servo valves cannot be used as a means of controlling the load speed, and tens of thousands of units are almost impossible to put into practical use.
This is because a valve with a flow rate of min is required.

The present invention was devised in view of the above circumstances, and an object of the present invention is to provide a material testing machine that is small in size, has a high capacity, and generates a high-speed load.

Means for Solving the Problems In order to achieve the above object, the material testing machine of the present invention includes an actuator having a first piston, one cylinder chamber and the other cylinder chamber on both sides of the piston, and a constant cylinder chamber in one cylinder chamber. a hydraulic unit that applies hydraulic pressure, an accumulator that is operated by the hydraulic pressure to accumulate pressure, and pressurizes the other cylinder chamber to release the excess hydraulic pressure rising in the one cylinder chamber while moving the first piston to the starting position. a hydraulic discharge passage that communicates with the other cylinder chamber and discharges oil in the other cylinder chamber, and an on-off valve provided in the hydraulic discharge passage that opens the hydraulic discharge passage at high speed, The on-off valve has an on-off hole substantially orthogonal to the hydraulic discharge passage;
A valve body is oil-tightly and slidably inserted into the opening/closing hole, a second piston attached to one side of the valve body, and a second piston that urges the valve body in a direction to close the opening/closing hole. A return spring provided on the side opposite to the valve body of the second piston, a cylinder housing the valve body, the second piston, and the return spring, and a hydraulic discharge hole provided in the cylinder so as to communicate with the opening/closing hole. When the valve body is displaced against the return spring by the hydraulic pressure applied to the valve body side of the second piston and opens the opening/closing hole, the valve body is displaced by the hydraulic pressure applied to the valve body side of the second piston. The run-up period of the valve body until the valve body completely rises has a length such that the opening/closing hole is not opened and the opening/closing hole is opened after the valve body enters a constant speed region.

Action With the piston held at the starting position,
The release valve is opened, but at this time, the opening/closing hole is fully opened after the valve body enters the constant speed range, so the hydraulic pressure in the cylinder chamber on the opening/closing valve side flows out at high speed, and the other cylinder chamber is released into the accumulator. A high-speed load is generated by pressurization.

Embodiment FIG. 1 is a partially cutaway front view of a material testing machine according to an embodiment of the present invention.

In this figure, reference numeral 10 denotes a base, and a table 12 is fixed in the middle of a pair of left and right columns 11, 11 erected on the base 10, and above the table 12, a table 12 is attached to the columns 11, 11. A crosshead 13 is arranged which can be raised and lowered.

An actuator 2 is mounted on the bottom surface of the table 12.
0 cylinder 21 is installed, and this cylinder 2
Inside 1, upper and lower cylinder chambers 2 are connected by piston 22.
It is divided into 3 and 24 sections. A jig 15 for pulling the lower part of the specimen 14 downward is provided at the upper end of the piston rod 25 protruding upward from the table 12.
A load cell 16 is attached to the crosshead 13 for supporting the upper part of the specimen 14 and detecting the load. The cross-sectional area of the lower piston rod 26 is smaller than that of the upper piston rod 25, that is, the lower piston end surface is larger than that of the upper piston rod, and the same amount of hydraulic pressure is applied to the upper and lower cylinder chambers 23 and 24. At this time, there is a downward force F1 acting on the piston 22, which is the sum of the hydraulic pressure in the cylinder chamber 23 and the respective weights of the piston 22, piston rods 25, 26, and jig 15, and an upward force _F1 due to the hydraulic pressure in the cylinder chamber 24. The force F ₂ is balanced.

30 is a servo valve as a control valve, and upper and lower cylinder chambers 23, 24 are connected to each other by hydraulic passages 31, 32.
It is connected to the.

40 is an accumulator, and a cylinder 41
and piston 42. The left cylinder chamber 43 is connected to the upper cylinder chamber 23 of the actuator 20 and the hydraulic unit 50, and the right cylinder chamber 44 is filled with a gas for accumulating pressure.

60 is an on-off valve for high-speed switching, which can slide at right angles to the hydraulic pressure discharge passage 70 from the cylinder chamber 24 below the actuator 20. A valve body 61 having a round rod shape and a relatively large cross-sectional area, and this valve body 6
1 to the closed state, that is, a return spring 63 that fits into the opening/closing hole 62 to close it, and a cylinder 65 that accommodates a piston 64 integral with the valve body 61. In addition, the cylinder 65 has a solenoid valve 8.
0 is connected, and a flow rate control valve 90 is arranged in a passage 70 between the cylinder chamber 24 on the lower side of the actuator 20 and the opening/closing hole 62 of the opening/closing valve 60 .

In addition, 100 is a passage that leads a large amount of oil instantly discharged from the on-off valve 60 to the oil tank 200 with a margin, and 300 is a hydraulic pressure supply passage 40 to the solenoid valve 80.
With the accumulator provided at 0, the hydraulic oil is stably supplied to the solenoid valve 80. The cylinder 65 is provided with a hydraulic discharge hole that communicates with the opening/closing hole 62 on one side and with the passage 100 on the other side.

Next, the operation of the above configuration will be explained.

From the hydraulic unit 50 to the upper cylinder chamber 23 of the actuator 20 and the accumulator 40
Hydraulic oil at a constant pressure P is supplied to the cylinder chamber 43 on the left side of the cylinder. As a result, the accumulator 4
The piston 42 of No. 0 moves rightward to compress the gas body in the cylinder chamber 44, and a pressure accumulation state is formed.

With the valve element 61 of the on-off valve 60 closing the on-off hole 62, the cylinder chamber 24 below the actuator 20 is opened from the passage 32 under the control of the servo valve 30.
Hydraulic oil at a pressure higher than the pressure P is supplied to the pump. This causes the piston 22 to rise, and the rising excess hydraulic pressure in the upper cylinder chamber 23 is forcibly pushed out from the passage 31. Therefore, the cylinder chamber 23 still maintains the pressure P.

When the piston 22 reaches the starting position as shown in the figure, the supply of hydraulic oil to the cylinder chamber 24 is stopped, and the cylinder chamber 24 and the cylinder chamber 23 are
pressures are kept equal. That is, the piston 22 is held at the starting position shown in the figure.

The crosshead 13 is lowered and the specimen 14 is attached.

The solenoid valve 80 is operated to switch the port. As a result, hydraulic oil is supplied to the cylinder 65 of the on-off valve 60, and the piston 64, that is, the valve body 61
moves back against the return spring 63. At this time,
Until the hydraulic pressure from the solenoid valve 80 is completely raised, the valve body 61 simply slides inside the opening/closing hole 62.
Do not open the opening/closing hole 62. In other words, as shown in FIG. 2, the solenoid valve 80 is run-up by the axial length l from the tip of the valve body 61 to the inside of the opening/closing hole 62.

When the valve body 61 enters the constant speed region after the run-up and opens the opening/closing hole 62, the oil in the lower cylinder chamber 24 quickly flows into the passage 70 because the opening/closing hole 62 has a relatively large cross-sectional area. From passage 10
At the same time, the pressure inside the upper cylinder chamber 23 drops rapidly, causing the accumulator 40 to
The gas body whose pressure has been accumulated in the cylinder chamber 44 expands and pressurizes the upper cylinder chamber 23. That is, a downward force is generated on the piston 22,
A high-speed tensile load is applied to the specimen 14.

In this case, the pressure and cross-sectional area of the upper cylinder chamber 23 are P ₁ and A ₁ , the pressure and cross-sectional area of the lower cylinder chamber 24 are P ₂ and A ₂ , the mass of the movable part including the piston 22 is M, and the downward direction When the velocity of is V, the tensile load on the specimen 14 is the force Ft, which is Mdv/dt+Ft=P ₁ A ₁ −P ₂ A ₂ from the motion equation.
Further, the maximum speed Vmax is controlled by a flow control valve 90 located in the hydraulic discharge passage 70.

In addition, in the embodiment described above, the servo valve 30 as a control valve can be replaced with another valve, for example, a solenoid valve. Although the actuator 20 is used for tension, it can also be used for compression. Furthermore, the actuator 20 can be installed horizontally rather than vertically as shown. in this case,
The cross-sectional areas of the two cylinder chambers 23 and 24 can be set equal to each other.

Effects of the Invention As can be seen from the above explanation, the material testing machine of the present invention includes a first piston, an actuator having one cylinder chamber and the other cylinder chamber on both sides of the piston, and a constant hydraulic pressure applied to one cylinder chamber. A hydraulic unit, an accumulator operated by the hydraulic pressure to accumulate pressure, and control for moving the first piston to a start position while pressurizing the other cylinder chamber and releasing excess hydraulic pressure rising in the one cylinder chamber. a hydraulic discharge passage that communicates with the other cylinder chamber to discharge oil in the other cylinder chamber; and an on-off valve that is provided in the hydraulic discharge passage and opens the hydraulic discharge passage at high speed; The valve includes an opening and closing hole substantially perpendicular to the hydraulic discharge passage;
A valve body is oil-tightly and slidably inserted into the opening/closing hole, a second piston attached to one side of the valve body, and a second piston that urges the valve body in a direction to close the opening/closing hole. A return spring provided on the side opposite to the valve body of the second piston, a cylinder housing the valve body, the second piston, and the return spring, and a hydraulic discharge hole provided in the cylinder so as to communicate with the opening/closing hole. When the valve body is displaced against the return spring by the hydraulic pressure applied to the valve body side of the second piston and opens the opening/closing hole, the valve body is displaced by the hydraulic pressure applied to the valve body side of the second piston. The run-up period of the valve body until the valve body completely rises has a length such that the opening/closing hole is not opened and the opening/closing hole is opened after the valve body enters a constant speed region.
Therefore, since the material testing machine of the present invention has a steep fall in the oil pressure in the other cylinder chamber, it is possible to generate high speed and high load.

[Brief explanation of drawings]

FIG. 1 is a partially cutaway front view of a material testing machine according to an embodiment of the present invention, and FIG. 2 is an explanatory diagram of a run-up mechanism. 20... actuator, 22... piston,
23, 24...Cylinder chamber, 30...Control valve, 4
0...Accumulator, 50...Hydraulic unit, 60...Opening/closing valve.

Claims (1)

[Scope of utility model registration request] an actuator having a first piston and one and the other cylinder chambers on both sides of the piston; a hydraulic unit that applies a constant hydraulic pressure to one cylinder chamber; an accumulator that is operated by the hydraulic pressure to accumulate pressure; a control valve that pressurizes a cylinder chamber to move the first piston to a start position while releasing excess hydraulic pressure rising in the one cylinder chamber; and a control valve that communicates with the other cylinder chamber to release oil in the other cylinder chamber. A hydraulic discharge passage for discharging the hydraulic pressure, and an on-off valve provided in the hydraulic discharge passage to open the hydraulic discharge passage at high speed, and the on-off valve has an on-off hole substantially perpendicular to the hydraulic discharge passage;
A valve body is oil-tightly and slidably inserted into the opening/closing hole, a second piston attached to one side of the valve body, and a second piston that urges the valve body in a direction to close the opening/closing hole. A return spring provided on the side opposite to the valve body of the second piston, a cylinder housing the valve body, the second piston, and the return spring, and a hydraulic discharge hole provided in the cylinder so as to communicate with the opening/closing hole. When the valve body is displaced against the return spring by the hydraulic pressure applied to the valve body side of the second piston and opens the opening/closing hole, the valve body is displaced by the hydraulic pressure applied to the valve body side of the second piston. The material testing machine is characterized in that a run-up period of the valve body until the valve body completely stands up has a length such that the opening/closing hole is not opened and the opening/closing hole is opened after the valve body enters a constant speed region.