JP3290837B2 - Concrete specimen compression test equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a compression test apparatus used for a strength test of a concrete test piece, and more particularly to a compression test apparatus capable of completing a compression test without exploding a concrete test piece. .

[0002]

2. Description of the Related Art Conventionally, concrete has been used as a material for building buildings and structures. In order to confirm whether or not the strength of the concrete is appropriate, it is necessary to perform a compression test on the concrete test piece, and in this test, a maximum load that the concrete test piece can withstand, that is, a nominal strength, is obtained.

For such a compression test of a concrete test piece, a compression test apparatus having a configuration as shown in a block diagram in FIG. 4 is generally used. In the compression test apparatus shown in FIG. 4, after the magnitude of the compression load applied to the concrete test piece is detected by the load detector 5,
The signal is amplified by the load amplifier 3 and input to the adder 19. Further, a signal of a target value of a compressive load to be applied to the concrete test piece is input from the load-time characteristic generator 1 to the adder 19. Then, a signal indicating a load deviation between the target value and the current value of the compression load output from the adder 19 is amplified by the deviation amplifier 2 and input to the control valve drive unit 4. The control valve drive unit 4 controls the opening and closing of the control valve 6 so that the load deviation between the target value and the current value of the compression load approaches zero. At the same time as such load control, the output of the load amplifier 3 is input to the maximum value storage circuit 7 so that the maximum value of the compressive load applied to the concrete test piece is stored. Then, the stored maximum value of the compression load is input to the maximum value-current value subtraction circuit 8. As a result, when the current value output from the load amplifier 3 falls below the maximum load value stored in the maximum value storage circuit 7, the maximum value-current value subtraction circuit 8
Outputs the value of “maximum load−current load”. Then, the output value and the output of the limit setting device 9 are compared by the limit value comparing circuit 10, and when the value of “maximum load−current load” exceeds the value set in the limit setting device 9, the limit value comparison is performed. The control valve drive unit 4 closes the control valve 6 by a signal generated by the circuit 10 to remove the compressive load applied to the concrete test piece and terminate the compression test.

[0004]

In the conventional compression test apparatus shown in FIG. 4, the target value of the magnitude of the compression load applied to the concrete test piece output from the load-time characteristic generator 1 and the concrete test piece are described. The control valve drive unit 4 controls the opening and closing of the control valve 6 so as to eliminate the deviation from the compression load that is actually applied. Accordingly, the control valve driving unit 4 continues to apply a compressive load to the concrete test piece so as to match the target value regardless of how the concrete test piece is compressively fractured. The compressive load is continuously applied to the concrete test piece even in the state where the compressive fracture has begun. further,
In the conventional compression test apparatus shown in FIG. 4, the compression load applied to the concrete test piece is removed only when the value of “maximum load−current load” exceeds the value set in the limit setting device 9. It has been like that. Therefore, in the conventional concrete test piece compression test equipment, if the concrete test piece does not break down significantly, the load cannot be detected and the load cannot be unloaded, and the rigidity of the concrete test piece is high. Since the so-called explosion phenomenon in which the concrete test piece ruptures and shards are scattered occurs, there is a problem that the compression test of the concrete test piece cannot be performed safely.

The inventors of the present invention have conducted intensive studies to solve the above-mentioned problems. As a result, before the concrete test piece is compressed and fractured, the concrete test piece is compressed as shown in FIG. Paying attention to the phenomenon that the strain in the direction perpendicular to the direction, that is, the transverse strain greatly increases,
If the compressive load applied to the concrete test piece is controlled so that the magnitude of the transverse strain generated in the concrete test piece does not exceed the magnitude of the transverse strain when the concrete test piece breaks, the concrete test piece will It has been found that the compressive load applied to the concrete test piece can be reduced when performing the test, thereby preventing the explosion of the concrete test piece.

The present invention has been made based on the above research results, and an object of the present invention is to provide a compression test for a concrete test piece capable of terminating the compression test without exploding the concrete test piece. It is to provide a device.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a means for controlling the magnitude of a compressive load applied to a concrete specimen, and a method of producing a strain in a direction perpendicular to the direction of compression of the concrete specimen. Means, a means for setting a target value of the strain, and means for calculating a strain deviation between the detected strain and the target value, wherein the compression load control means sets the strain deviation to zero. This can be achieved by a concrete test piece compression test apparatus characterized in that the magnitude of the compressive load applied to the concrete test piece is controlled so as to approach the concrete test piece.

[0008]

The means for controlling the magnitude of the compressive load applied to the concrete test piece includes a strain set as the target value set in the target value setting means and a direction perpendicular to the compression direction generated in the concrete test piece. The magnitude of the compressive load applied to the concrete test piece is controlled so that the strain deviation from the strain of the concrete becomes zero. Therefore, the means for controlling the magnitude of the compressive load reduces the compressive load applied to the concrete test piece so that the strain of the concrete test piece approaches compression failure and does not exceed the target value. This can reduce the compressive load applied to the concrete test piece when the concrete test piece undergoes compressive failure, so that the concrete test piece can be prevented from exploding.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a concrete test piece compression test apparatus according to the present invention will be described in detail with reference to FIGS.

As shown in FIG. 1, a concrete test piece compression test apparatus 100 according to the present embodiment is configured such that a control valve driving unit 4 opens and closes a control valve 6 so that the magnitude of a compressive load applied to the concrete test piece is increased. Is being controlled. Further, the concrete test piece compression test apparatus 100 of the present embodiment includes a diametral strain detector 13 and a diametric strain amplifier 12 as means for detecting strain in a direction perpendicular to the compression direction of the concrete test piece; Diameter strain as a means to set the target value of strain-
A first control circuit 20 includes a time characteristic generator 11 and an adder 19 and a deviation amplifier 2 as means for obtaining a strain rate deviation between the target value and the strain rate of the detected strain. Further, the concrete test piece compression test apparatus 100 of the present embodiment includes a compression load detector 5 and a compression load amplifier 3 as means for detecting the magnitude of the compression load applied to the concrete test piece, and a maximum value of the compression load. Maximum value storage circuit 7 as a means for storing the maximum value of the stored compressive load and a maximum value-current discount as a means for obtaining a load deviation between the stored maximum value of the compressive load and the current value of the compressive load applied to the concrete test piece. Calculation circuit 8 and a limit value setting device 9 as means for setting the limit value of the load deviation.
And a second control circuit 30 having a limit value comparison circuit 10 as means for comparing the limit value with the load deviation.

The first control circuit 20 controls the magnitude of the compressive load applied to the concrete test piece so that the strain deviation between the strain generated in the concrete test piece and the target strain becomes zero. is there.

The diametral strain-time characteristic generator 11
Outputs the target value of the strain generated in the concrete test piece to the adder 19. At this time, in the present embodiment, a target strain value that increases at a constant speed after the start of the compression test of the concrete test piece is output.

The diametral strain detector 13 is a clip-type strain gauge attached to the surface of a concrete test piece, and the diametric transverse strain amplifier 12
Is a device that amplifies the strain detected by the strain gauge. In this embodiment, since the shape of the concrete test piece is cylindrical, the clip-type strain gauge is attached to the outer peripheral surface of the concrete test piece so as to measure the strain in the diameter direction of the concrete test piece. I have.

After the compressive load applied to the concrete test piece reaches a maximum, the second control circuit 30 reduces the concrete test piece as the concrete test piece gradually breaks in compression, and the amount of the decrease is a predetermined value. This is a circuit for terminating the compression test when the size becomes large.

The compression load detector 5 is a load cell interposed between a concrete test piece and a compression tester,
After its output is amplified by the compression load amplifier 3, it is input to the maximum value storage circuit 7 and the maximum value-current value subtraction circuit 8. Then, the maximum value storage circuit 7 stores and holds the maximum value of the compressive load applied to the concrete test piece. The maximum-current value subtraction circuit 8 calculates a load deviation between the maximum value of the compression load stored in the maximum value storage circuit 7 and the value of the compression load currently applied to the concrete test piece. It outputs to the limit value comparison circuit 10. The limit value setting device 9 is provided to set the time at which the compression load is reduced from the maximum value to stop the compression test. The limit value comparison circuit 10 outputs a signal to the control valve drive unit 4 when the output from the maximum value-current value subtraction circuit 8 exceeds the limit value set in the limit value setting unit 9. Have been.

Next, the operation of the concrete test piece compression test apparatus 100 of the present embodiment configured as described above will be described. When a compressive load is gradually applied to the concrete test piece by the control valve driving unit 4 opening the control valve 6, the strain of the concrete test piece detected by the diametral strain detector 13 becomes equal to the diameter of the concrete test piece. The signal is amplified by the directional distortion amplifier 12 and output to the adder 19. On the other hand, the diametral strain-time characteristic generator 11
Outputs the target value of the strain to the adder 19 at a constant speed after the start of the test. The adder 19 provides the deviation amplifier 2 with a distortion deviation between a target value of the distortion generated by the diametral distortion-time characteristic generator 11 and a current value of the distortion detected by the diametric distortion detector 13. Output. When the output of the strain deviation is amplified by the deviation amplifier 2 and then input to the control valve driving unit 4, the control valve driving unit 4 generates a strain generated in the concrete test piece,
The control valve 6 is opened and closed so that the deviation of the strain generated by the diametral strain-time characteristic generator 11 from the target value becomes zero, and the magnitude of the compressive load applied to the concrete test piece is adjusted.

When the concrete test piece cannot withstand the compressive load and approaches the compressive failure, the strain of the concrete test piece tends to increase greatly, as shown in the lateral strain graph 50 shown in FIG. Then, the control valve driving unit 4 controls the control valve driving unit 4 so that the magnitude of the strain of the concrete test piece detected by the diametral strain detector 13 does not exceed the target value of the strain generated by the diametric strain-time characteristic generator 11. The control valve 6 is closed to reduce the compressive load applied to the concrete test piece as shown in FIG. 3, so that the strain of the concrete test piece does not increase significantly and the deviation from the target value becomes zero. Is done. Thereby, in the compression test using the concrete test piece compression test apparatus 100 of the present embodiment, when the concrete test piece is compressed and fractured, the compressive load applied to the concrete test piece is reduced, so that the concrete test having high rigidity is performed. Even when the specimen is subjected to a compression test, no explosion occurs in the concrete specimen.

On the other hand, when the concrete test piece approaches the compressive fracture, the compressive load applied to the concrete test piece gradually decreases after reaching the maximum. When the reduction range of the compression load output from the maximum value-current value subtraction circuit 8 to the limit value comparison circuit 10 exceeds the limit value set in the limit value setting device 9, the control from the limit value comparison circuit 10 is performed. A signal is output to the valve drive unit 4, the control valve 6 is closed, and the compressive load applied to the concrete test piece is released to complete the compression test.

That is, according to the concrete test piece compression test apparatus 100 of the present embodiment, the compressive load applied to the concrete test piece when the concrete test piece is compressed and fractured can be reduced, so that a concrete test piece having high rigidity can be obtained. Even when performing a compression test on a piece, the compression test can be terminated without exploding the concrete test piece. Further, in the concrete test piece compression test apparatus 100 of the present embodiment, since a strain that increases at a constant speed is set as a control target, a compression test can be performed efficiently.

Incidentally, the concrete test piece compression test apparatus of the present invention is not limited to the above-described embodiment, and it goes without saying that various modifications can be made based on the gist of the present invention. For example, in the above-described embodiment, the target is to increase the strain at a constant speed.
It is not necessary to be limited to this, and it is also possible to change the magnitude of the target strain for control according to the elapsed time after the start of the test, or to set the strain to be constant regardless of the elapsed time. good.

[0021]

As described above, the concrete test piece compression test apparatus of the present invention has means for controlling the magnitude of the compressive load applied to the concrete test piece, and means for controlling the magnitude of the compressive load perpendicular to the direction of compression generated in the concrete test piece. Means for detecting strain in the direction, means for setting a target value of the strain, and means for obtaining a strain deviation between the detected strain and the target value, wherein the compression load control means calculates the strain deviation. Along with controlling the magnitude of the compressive load applied to the concrete test piece so as to approach zero, the target value is set to be smaller than the magnitude of the strain generated in the concrete test piece when the concrete test piece breaks in compression. Because of this, the concrete test piece approaches compression failure, and the range of decrease in the compressive load increases greatly, exceeding the set limit value. When that compressive load applied to the concrete specimen is controlled to decrease. Therefore, according to the concrete test piece compression test apparatus of the present invention, the compression test can be completed without exploding the concrete test piece, and the compression test of the concrete test piece can be performed safely.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an embodiment of a concrete test piece compression test apparatus according to the present invention.

FIG. 2 is a graph showing temporal changes in longitudinal strain and transverse strain generated in a concrete test piece in a compression test.

FIG. 3 is a graph showing temporal changes in longitudinal strain and transverse strain generated in a concrete test piece according to the present invention.

FIG. 4 is a block diagram illustrating a configuration of a conventional concrete test piece compression test apparatus.

[Explanation of symbols]

 Reference Signs List 1 load-time characteristic generator 2 deviation amplifier 3 compression load amplifier 4 control valve drive unit 5 compression load detector 6 control valve 7 maximum value storage circuit 8 maximum value-present value subtraction circuit 9 limit value setting unit 10 limit value comparison Device 11 Transverse strain-time characteristic generator 12 Diameter strain amplifier 13 Diameter strain detector 19 Adder 20 First control circuit 30 Second control circuit 40 Longitudinal strain graph 50 Lateral strain graph 51 Lateral strain increasing portion 100 Concrete test piece compression test apparatus according to the invention

────────────────────────────────────────────────── ─── Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G01N 3/00-3/62 JICST file (JOIS)

Claims (2)

(57) [Claims] A means for controlling a magnitude of a compressive load acting on a concrete test piece; a means for detecting a strain generated in the concrete test piece in a direction perpendicular to a compression direction; and setting a target value of the strain. And a means for calculating a strain deviation between the detected strain and the target value, wherein the compressive load control means controls the magnitude of the compressive load applied to the concrete test piece so that the strain deviation approaches zero. A compression test apparatus for concrete test pieces, characterized in that the test piece compression control is performed. 2. The concrete test piece compression test apparatus according to claim 1, wherein the target value of the strain is set as a strain rate.