KR20080029086A - Apparatus for measuring impact induced tensile-fracture - Google Patents

Abstract

An apparatus for measuring tensile strength is provided to measure tensile strength of a conductor using electromagnetic force generated when instant current is applied. An apparatus for measuring tensile strength comprises a pulse forming network(10) in which electric energy is saved, a power supply unit(20) applying power to the pulse forming network, a first coupling unit(50) electrically coupling the pulse forming network to one end of a sample, a second coupling unit(60) electrically coupled to the first connection unit, an insulation unit(70) insulating the first and second coupling units, a switch(40) positioned between the pulse forming network and the first coupling unit, and a third coupling unit(80) electrically connecting the second coupling unit to the pulse forming network.

Description

Tensile failure measuring device {Apparatus for measuring impact induced tensile-fracture}

1 is a cross-sectional view showing an embodiment of the present invention.

2 is a circuit diagram of a pulse molding part of the present invention.

3 is a cross-sectional view showing the current flow in the present invention.

4 is a schematic diagram showing a magnetic field and a force applied to a sample of the present invention.

<Brief description of the main parts of the drawing>

10: pulse molding part 20: power supply part

30 sample 40 switch

50: first connection portion 60: second connection portion

70: insulation portion 80: third connection portion

 The present invention relates to a tensile failure measuring device, and more particularly, to a tensile failure measuring device capable of measuring the tensile failure of the conductor materials due to the impact load.

In the field of defense research, breakdown of materials due to impact is an important area.

Conventional MTS (Material Test System) is to measure the strength at a constant pressure state by using a mechanical force to compress or tension the sample, it is impossible to measure the strength when the instantaneous pressure is applied.

Therefore, gas guns or other large-scale equipment had to be used to generate such an impact.

Therefore, there is a need for a device that obtains instantaneous pressure without using such large equipment.

The present invention is to solve the problems described above, and to provide a tensile failure measuring device that can measure the tensile failure of the conductor using the electromagnetic force generated when the instantaneous electricity is applied.

In order to achieve the above technical problem of the present invention, the present invention, the pulse molding unit is stored electrical energy; A power supply unit applying power to the pulse molding unit; A first connection part electrically connecting the pulse molding part and one end of the sample; A second connection part electrically connected to the other end of the sample; An insulation part for insulating the first connection part and the second connection part; A switch located between the pulse forming part and the first connection part; Preferably, the second connector includes a third connector electrically connecting the second connector and the pulse molding unit.

The pulse forming unit is formed of a combination of a capacitor and an inductor. In particular, it is preferable that a plurality of capacitors are commonly connected in parallel at each intermediate terminal of the plurality of inductors connected in series.

In this case, the magnitude and duration of the current pulse applied to the sample may be determined according to the voltage and capacity of the capacitor and the inductor, and the voltage is preferably 30 kV or less.

The sample placed between the first connector and the second connector may be formed in a cylindrical symmetrical shape with both ends larger in diameter, so that the specimen may receive a tensile force when the power is applied.

The first connecting portion is a cylindrical conductor having a first coupling groove to which the end of the sample is coupled to the lower side, and the second connecting portion is at least one cylindrical having a second coupling groove to which the end of the sample is coupled to the upper side. It is preferable that it is a conductor.

At this time, between the sample and the second connection portion, a liquid metal such as silver paste is located, so that even if there is a gap, it is possible to make excellent current flow.

Preferably, the insulating portion includes a holder portion surrounding the sample at a predetermined interval from the sample.

On the other hand, it is preferable that the third connection portion is a conductive wire coupled by the second connection portion and the pulse molding portion by a terminal, and may constitute eight terminals and conductive wires.

The power supply unit may be connected by a resistor and an inductor connected in series with the pulse molding unit to prevent current from flowing back to the power supply unit.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, in the pulse molding unit 10, power is applied from the power supply unit 20 to store electrical energy. Thus, the electrical energy stored in the pulse molding unit 10 has a specific magnitude in the sample 30. A current pulse with a duration of and is applied.

The power supply unit 20 is connected to the pulse forming unit 10 through a dump inductor Le and a dump resistor Re to supply charge.

Such Re and Le prevent the current at the time of discharge from flowing back to the power supply unit 20. As such, the charge remaining on the capacitor of the pulse forming unit 10 is grounded through the dump switch 21 connected to the power supply unit 20 and the inductor Le.

As shown in FIG. 2, the pulse forming unit 10 includes a combination of capacitors C1, C2, C3, etc., and inductors L1, L2, L3, etc., and outputs current pulses according to their capacity and size. The size and duration of the is determined.

As shown in the combination of the capacitor and the inductor, a plurality of capacitors are connected in parallel to each intermediate terminal of the plurality of inductors connected in series with the power supply unit 20, and the other ends of the parallel connected capacitors are connected in common. have.

The magnitude and duration of this output current determines the magnitude and duration of the pressure applied to the sample 30 side. Depending on the material or size of the sample 30 to be tested, the voltage and capacity of the pulse forming unit 10 may have different values.

Corona discharge occurs when the voltage is higher than 40 kW in the air, so the maximum voltage is limited to 30 kW for the miniaturization of the system.

When the switch 40 is closed in this state, the electric energy stored in the pulse molding unit 10 is discharged, and an instantaneous current is applied to the sample 30. The switch 40 is triggered by a small trigger circuit and closed.

In addition, the sample 30 may have both ends 31 formed in a cylindrical symmetric shape having a larger diameter, so that the specimen 30 may receive a tensile force when the power is applied.

The positive pole of the pulse forming unit 10 is a high voltage and the negative pole is grounded (the positive pole is grounded when the high voltage side is a negative electrode, which will be described below).

When the switch 40 is closed, a current is discharged from the pulse molding unit 10 to flow to the first connection unit 50 and the second connection unit 60 on which the sample 30 is placed.

The load portion consisting of the first connector 50 and the second connector 60 has a cylindrically symmetrical structure, and the sample 30 is placed between the first connector 50 and the second connector 60. The first connector 50 and the second connector 60 are insulated by the insulator 70.

The insulating part 70 may be configured with a holder part 71 surrounding the sample 30 at a predetermined distance from the sample 30.

The sample 30 having an I-shape is fastened with a thread to the first connection portion 50 of the positive electrode, and the second connection portion 60 located on the other side of the sample 30 is precisely processed. The 30 and the cathode metal are brought into contact with each other, and a liquid metal 61 such as silver paste is applied to the gap between the second connection portion 60 and the sample 30 so as to conduct electricity.

In this structure, the current passes through the center of the first connection part 50 and the sample 30 and passes through the conductor of the second connection part 60 of the cathode, and then returns to the pulse forming part 10. Eight cathode terminals 62 are attached to the second connection portion 60 to allow a cylindrical uniform current to flow through the cathode.

In the second connector 60, the third connector 80 is connected to the pulse forming unit 10 through the terminal 62. A conductive wire may be used as the third connector 80.

In addition, a lower leg 90 for supporting the second connecting portion 60 may be configured.

Hereinafter, the operating principle of the device as described above in detail.

When the switch 40 is closed, the load current I flows through the path with the smallest inductance and resistance as shown in FIG.

That is, the current flowing through the positive electrode (first connector 50) and the current flowing through the negative electrode have a small inductance when the distance is close. Therefore, a current path is formed at the anode at the outer diameter portion and at the cathode at the inner diameter portion.

Also, since the surface of the metal has the least resistance, most current flows along the surface as shown in FIG.

When current flows in this way, a magnetic field is generated around it. 4 shows the direction of the current I , the magnetic field B , and the electromagnetic force F in the sample 30. In the portion where the radius of the sample 30 is small, the current flows downward, so that the magnetic field is generated clockwise.

The resulting Lorentz electromagnetic force F1 acts in the direction of pressing the current flowing sample. In other words, the current flowing sample is pinched (pinch or z-pinch in physical terms). The electromagnetic pressure P ₁ Is expressed as Equation 1:

[Equation 1]

Where I is the current (A), d is the diameter (cm) of the center portion of the sample (30) and the unit of pressure is Pascal.

In the lower portion 31 of the sample 30 in which current flows in the outer diameter direction, the magnetic field is generated in a direction penetrating the ground, and the electromagnetic force acts to push the sample 30 outward.

If the outer diameter of the lower portion 31 of the sample is D cm and the electromagnetic force F2 is calculated and divided by the area, the pressure P ₂ is calculated as follows.

[Equation 2]

The pressure obtained by the above equations (1) and (2) is a tensile force that pulls the sample 30 downward. Since the upper surface 31 of the sample 30 is fixed to the anode metal, the force F3 acting on the upper surface 31 does not have an effect of pulling the sample 30.

At this time, the tensile pressure applied to the sample 30 is the sum of the equation (1) and (2).

As such, the tensile pressure applied to the sample 30 determines the current time and current magnitude flowing through the load by adjusting the capacitances of the capacitors of the pulse forming unit 10 and the inductances of the inductor, as shown in FIG. 2. Then, the magnitude of the pressure applied to the sample 30 and the pressure application time are determined.

The above embodiment is an example for explaining the technical idea of the present invention in detail, and the present invention is not limited to the above embodiment, various modifications are possible, and various embodiments of the technical idea are all protected by the present invention. It belongs to the scope.

The present invention as described above can be configured with a simple and compact system, and thus can operate with only simple components, so that the maintenance is simple and the measurement time is short.

Claims (14)

A pulse molding unit in which electrical energy is stored; A power supply unit applying power to the pulse molding unit; A first connection part electrically connecting the pulse molding part and one end of the sample; A second connection part electrically connected to the other end of the sample; An insulation part for insulating the first connection part and the second connection part; A switch located between the pulse forming part and the first connection part; And a third connection part electrically connecting the second connection part and the pulse molding part. The tensile rupture measuring apparatus of claim 1, wherein the pulse forming unit comprises a combination of a capacitor and an inductor. 3. The tensile rupture measurement apparatus of claim 2, wherein the combination of the capacitor and the inductor is a plurality of capacitors commonly connected in parallel to respective intermediate ends of the plurality of inductors connected in series. The tensile breaking measurement apparatus of claim 2, wherein the magnitude and duration of the current pulse applied to the sample is determined according to voltages and capacitances of the capacitor and the inductor. 5. The tensile rupture measuring apparatus according to claim 4, wherein the voltage is 30 kV or less. The tensile breaking measurement apparatus according to claim 1, wherein the switch is operated by a triggering circuit. The tensile rupture measuring apparatus according to claim 1, wherein the sample is a cylindrical symmetrical type having a larger diameter at both ends. The tensile rupture measuring apparatus according to claim 1, wherein the first connection portion is a cylindrical conductor having a first coupling groove to which an end of the sample is coupled. The tensile rupture measurement apparatus of claim 1, wherein the second connection portion is at least one cylindrical conductor having a second coupling groove to which an end of the sample is coupled. The tensile rupture measurement apparatus according to claim 1, wherein a liquid metal is positioned between the sample and the second connection portion. The tensile breaking measurement apparatus according to claim 10, wherein the liquid metal is silver paste. The tensile rupture measurement apparatus according to claim 1, wherein the insulating portion includes a holder portion surrounding the sample at a predetermined distance from the sample. The tensile rupture measuring apparatus of claim 1, wherein the third connection part is a conductive wire coupled to the second connection part and the pulse molding part by a terminal. The tensile rupture measuring apparatus of claim 1, wherein the power supply unit is connected by a resistor and an inductor connected in series with the pulse molding unit.

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