DE1076289B - Arrangement for spark erosion with an impedance in the DC charging circuit of the accumulator - Google Patents

Description

The invention relates to an arrangement for spark erosion in which a direct voltage is applied via an impedance is connected to a memory that is parallel to the spark gap.

In the known devices, a spark is made to jump over the terminals of two electrodes, one of which forms the tool and the other forms the workpiece, with the material being transported contrary to the conditions prevailing in the electric arc in the direction of the Anode to cathode takes place.

In these known devices, the electrical circuit basically includes one with the Workpiece in series connected charging resistor, one connected in parallel to the terminals of the electrodes variable capacity and optionally a vibrator, which interrupts the contact of the Electrodes and causes the discharge of the capacitance to the electrode corresponding to the workpiece.

Because the efficiency ultimately depends on the discharge time and the peak power 'of the spark depends, such devices exhibit as a result of the used capacity based on imperfections, which automatically affect the quality of the received Impact spark discharge, which is more or less oscillating, which in particular a rapid wear of the tool.

It has already been proposed to use a delay ladder in parallel to improve the effect to apply to the spark gap. In this proposal, however, the delay ladder was in parallel connected to a capacitor acting as a memory, the connection via a coupling capacitor took place.

In contrast, the invention consists in the fact that only a memory directly to the spark gap parallel delay chain conductor is used, which is dimensioned so that the discharge in on takes place in a known manner at approximately constant voltage and that the charging follows without a break.

This results in the fundamental difference that, according to the invention, the delay chain conductor works as the only memory element that exists at all, while the older right has the Delay chain conductor only regulates the charging ratios of the storage capacitor, whereby only a part of the capacitors and inductances contained in the delay chain conductor parallel to the Gap lies.

In the older proposal, there is a significant pause between the individual discharges, which is precisely avoided with the subject matter of the invention. Such a break can occur in the case of the counter-invention arrangement for spark erosion
with an impedance in the DC charging circuit of the storage unit

Applicant:

Center National

de la Recherche Scientifique,

Paris

Representative: Dr.-Ing. W. Stuhlmann, Bochum,

and Dr.-Ing. B. Bloch,

Berlin-Wilmersdorf, Ballenstedter Str. 17,

Patent attorneys

Claimed priority:
France 21 November 1952

Marc Bruma, Pavillons-sous-Bois, Seine,

and Michel Magat, Bourg-la-Reine, Seine (France),

have been named as inventors

stood even if the order of magnitude of the capacitances and inductances is unfavorable is chosen; in this case there could only be insufficient damping of the individual discharge, however, there cannot be a significant pause between discharges, which is the erosion result significantly reduced.

The invention is explained below by way of example with reference to the drawing. ■

1 shows the electrical circuit of a device according to the invention;

Fig. 2 is a graph showing the change with time the voltage at the terminals of the electrode forming the tool and the workpiece.

According to Fig. 1, the device contains the terminals 1 and 2 of the DC voltage source E ₀ , a variable self-inductance 3, which with the z. B. a member formed by a valve or a dry rectifier with one-sided conductivity 4 is connected in series, a delay line 5 with the terminals 6 and 7, the self-inductances 8 to 11

909 757/414

and the capacities 12 ... to 16, which form the tool, negatively polarized electrode 17 and the workpiece 18 connected to the terminal 2, these Parts are immersed in a fluid with the help of any devices not shown, z. B. water, mineral oil, kerosene, etc.

In this device, the DC voltage generator feeds the delay line via the charging impedance, which discharges periodically between the electrode forming the tool and the workpiece.

The charging impedance is only formed by a self-inductance, which has an electrical resistance element is connected in series with one-sided conductivity. The main task of the charging impedance is the rush current in the delay line at the moment of voltage application to limit. This task can also be fulfilled by an ohmic resistance, which

the current impulse is limited to the maximum value / _M = -,

where V is the voltage supplied by the generator. When using a resistor, an amount of energy is consumed by Joule heat which is equal to the amount of energy stored in the delay line, so that the electrical efficiency of the overall arrangement is limited to 50%. The use of a self-inductance which excludes the loss of Joule heat, on the other hand, allows this efficiency to be increased to 98%, with the current surge at the maximum value

with a steller front the essential advantage of reducing the discharge time and thus increasing the instantaneous power or peak power of the spark, which becomes more intense, harder and practically vibration-free.

As a result of the production of vibration-free sparks by preventing any pole reversal, the corresponding wear and tear of the tool made meaningless.

ίο The device of Fig. 1 works as follows:

When the delay line is discharged, the time

t = 0 the constant voltage E _{0 is applied} to terminals 1 and 2. After a time Τ = π yZ ^ C ^

(where C ₇ - the total capacitance of the delay line and L _{3 is} the charging inductance) the voltage at terminals 6, 7 of the. Delay line the value to:

E _t = E ₀ [1 +. e

JF Z

Im =

Z =

where C ₇ - is the total capacitance of the delay line.

Another advantage resulting from the known use of self-inductance is the reduction in the charging time of the delay line with a corresponding increase in the number of sparks in the unit of time, which allows the operating frequency of the arrangement to be increased. It is known that the charging time of a capacitor battery with the value Cj, which corresponds to the total capacitance of the delay line in question, is 4.6 RCγ, while the inventive combination of a charging inductance L and a delay line with the capacitance C ₇ only requires a charging time T = 3.14 ZC _T. For Z = R , the charging time T is only 0.68 of the time required to accumulate the same amount of energy in a resistor-capacity system. It follows that under otherwise identical circumstances, the operating frequency of an inventive arrangement with a self-inductance and \ ^r erzögerungsleitung l, is 47 times greater than the operating frequency of a system with resistance and capacitance. The rectifier element, which may be connected in series, prevents the voltage at the terminals of the delay line from swinging by a value V and blocks it at the maximum value, which is theoretically IV and practically 1.8 f if the power generator supplies a constant DC voltage over time.

The use of a delay line instead of a battery of capacitors offers one and the same given capacitance value while at the same time producing a discharge in the form of a pulse 1 τ ic

where α is a number (a = —- R / ii2-with 2? = Ohm's

ι \ -L ₃

Resistance of the charging circuit), which indicates the attenuation of the charging circuit.

It can be seen that for a <Ci the voltage E ₁ at the terminals of the delay line exceeds the value of the charging voltage E ₀ and that for very small values of α (α E ^ 0.02) E _t approximately double that of E ₀

will.

If the distance between the tool 8 and the workpiece is kept at a value close to that at which a voltage 2 E _{0 is} just sufficient to generate a discharge through the conductor separating means, the charge does not become oscillatory , provided,

that the wave resistance Z ₀ = l / - = r the deceleration

approximately equal to the self-impedance of this discharge, that is, of the order of magnitude of approximately 0.01 ohms. The discharge duration is given by the time constant of the delay line δ = 2Z ₀ -C ₁ - seconds. It is seen that in a delay line with a total capacity of 200 ■ IQ ⁶ J ⁷ and a characteristic impedance Z ₀ = 10- ² ohm the discharge time

(5 = 2 x 10-2-200 x 10- ⁶ = 4 microseconds
amounts to.

The same process begins after a time T after the discharge, as indicated in FIG.

The energy drawn from the delay line of the voltage source E ₀ in a time T is thus discharged between the tool and the workpiece in a time δ.

The peak performance in the discharge is thus

-5-times greater than that supplied by the voltage source power, since δ of the order of microseconds (10 ^-6 seconds) and T is of the order of milliseconds (10 seconds ^s), one sees that the peak power in a Discharge can be 100 times greater than the average power of the power source. This means that with a power source which supplies 1 kW at the terminals 1, 2 of the device shown schematically in FIG any electrically conductive metal or

any alloy of any mechanical hardness is sufficient.

The voltage source E ₀ is due to a purely ohmic impedance of the value

Ct) 2

loaded, which is worth the value of the charging current of the delay line to the apex

L \ 1

Ct j ^

limited.

Fig. 2 shows the time course of the voltage E between the electrode forming the tool and the workpiece. It can be seen that the instantaneous power of the spark can be great because the discharge time δ is extremely short.

Claims (4)

Patent claims: 1. Arrangement for spark erosion, in which a DC voltage via an impedance to a Memory is connected, which is parallel to the spark gap, characterized in that as Memory only one directly to the spark gap parallel delay chain conductor is provided, which is dimensioned so that the discharge takes place in a manner known per se at approximately constant voltage and that the charging joins without a break. 2. Arrangement according to claim 1, characterized in that the characteristic impedance of the delay line (5) approximately equal to the impedance of the discharge circuit (17, 18) during the discharge is. 3. Arrangement according to claim 1 and 2, characterized in that the impedance lying in the charging circuit formed by a self-induction coil (3) connected in series with a rectifier (4) will. 4. Arrangement according to claim 1 to 3, characterized in that the wave resistance of the Delay chain conductor (5) about 0.01 ohms and the total capacitance of the delay chain conductor (5) is about 200 microfarads. Considered publications:
German Patent No. 967 179;
U.S. Patent Nos. 2,235,385, 2,322,561. 1 sheet of drawings © 909 757/414 2.60