DE1516181C - Electronic active consumption meter - Google Patents

Description

The main patent describes an electronic active consumption meter with a Hall multiplier, an AC amplifier to amplify the AC component of the Hall voltage, a downstream phase-sensitive rectifier bridge circuit, whose control voltage is derived from the consumer voltage and whose output voltage is an electronic integration device, e.g. B. a circuit with a counter throttle is fed. The Hall multiplier is one of the two input variables, preferably the consumer voltage, fed via a rectifier bridge circuit. The zero crossings of the control voltage coincide with the zero points of the rectified input variable of the Hall multiplier.

In electronic integration with a choke whose induction is known to be the integral of applied voltage is proportional, one can achieve the saturation state in a known way 20: use to trigger a counter. However, if the accuracy requirements are high, an error occurs on, the creation of which is to be considered in the following. For the sake of simplicity, this is done first assume that the Hall voltage, i.e. H. be the voltage to be integrated, a direct voltage.

According to the law of induction, for the duration T of the reversal of magnetization of the Drosselkerff by a constant voltage U ₁₁ :

30 the output resistance of the amplifier. The relationship then applies to integration

Only u _D contributes to the integration.

If the hysteresis loop of the core material of the integration choke is replaced approximately by a magnetization line with two kinks, as shown in FIG. 2a, then the magnetization current i can be assumed to be constant during the integration process and has approximately the value

I =

VV

H _{c is} the coercive force of the core material, / _{F is} the closed iron path of the integration choke, and w is the number of turns.

This gives the relative error of the integration

RH _c l _F w U ₁₁

U ₁₁ dt = U ₁₁ ■ T = w -q _F ■ AB.

(1)

The counting frequency /, i.e. the number of increments of the counter per second, results from

_f _ l._ Uh T wq _F - AB

U ₁₁ . (2)

40 In practice, the counting frequency / is "mostly between Ό.5 and 50 Hz. In this range, the coercive force H _{c changes} at most by a factor of 2. On the other hand, a certain minimum operating range must be provided for electronic counters as well as commercially available counters, for example 1 : 100. So U _{H changes} from U _{11 min} to about 100 U _{11 mi} ". This means that the maximum error occurs at the minimum Hall voltage. There one can assume that the coercive force corresponds to that of the static hysteresis loop, since the Counting frequency is exceptionally low, so the maximum value results from

U _{11 min}

On the basis of FIG. 1 and 2 one can deduce that this proportionality is due to the ohmic Resistances in the choke circuit and because of the hysteresis of the choke core material are not exactly adhered to will.

F i g. 1 schematically shows an electronic active consumption meter known per se with a Hall generator 1, the excitation of which (first input variable) is achieved with the aid of a winding 3 placed in the circuit of consumer 2, while the control current (second input variable) is proportional to the voltage at consumer 2. The resulting output voltage u _H is fed to an amplifier 4. The direct current component of the Hall voltage corresponds to the active power. You can filter out the AC voltage component of the Hall voltage, smooth the DC voltage component and then obtain a DC voltage U _n for the integration choke 5. Every time the choke 5 goes into saturation, the trigger amplifier 6 is triggered and switches the counter 7 further.

The integration current i flows through. an ohmic resistance R in the integration circuit, which is composed of the winding resistance of the integration choke and additional resistances that depend on the amplifier and the associated devices. Essentially , this is about You can keep this error small if you use high-quality material with a low coercive force and the largest possible U _Hmin , i.e. high pre-amplification. However, it cannot be completely eliminated in this way.

FIG. 2b shows the profile of the voltage U ₁₁ and the error voltage (hatched area) during a magnetization reversal period T. The corresponding times I ₁ to t ₄ are plotted in FIG. 2a along the magnetization line. The error considered above can now be compensated for by adding a voltage U _v of magnitude 1 · R to the voltage U ₁₁ . This is indicated in FIG. 1, where such a current is impressed on the resistor 9 in the integration circuit from an external DC voltage source via a large series resistor 8 that the voltage U _v arises across it.

It is not necessary here to also change the voltage as a function of the changes in the integration current 1. Rather, it is sufficient to relate the voltage to the conditions at the lowest counting frequency, i.e. also to the coercive force H _{c0 of} the static loop, and to keep it constant for the entire working range of the counter. The voltage compensates for the error at

3 4

the lowest voltage U _Hmin , while at higher However, the field winding 3 of the Hall power, i.e. a higher voltage U ₁₁ , the generator is not connected to the mains voltage, added voltage U _v no longer plays a role. but placed in the circuit of consumer 2.

3a and 3b relate to the case, the control current of the Hall generator is with the help that the voltage to be integrated is not a rectifier, 5 of a rectifier 10 from the mains voltage is an alternating voltage, and that when it conducts, so has the form of a commutated sine power factor cos φ = 1. Fig. 3 b shows voltage again.

a reversal of the magnetization period of the integration dros- The Hall alternation emitted by the Hall generator, during the corresponding times i _x to t ₉ of voltage is written after the compendium has been displayed. Here 10 system voltages, as will be explained in more detail below, compensation is possible by supplying a DC, a phase-sensitive DC voltage which corresponds to the mean value of the areas supplied in the bridge circuit 11, for example, FIG. 3b with hatched areas. via a transformer, of which only the two

This grain secondary windings 12 and 13 are shown to encounter considerable difficulties. the

compensation method, however, when the power 15 control of this bridge circuit is carried out by the

factor of the consumer is different from 1. In practically square-wave output voltage of a

This is because the multivibrator 18 to be integrated takes this case.

Voltage both positive and negative values The output voltage of the bridge circuit 11 at. This is illustrated in FIG. 4. 4a is fed to the integration choke 19, with which initially shows the mains voltage u and the consumer 20, an ohmic resistor 20 is connected in series. At the current i at a certain phase shift φ. Resistance 20 has a notable voltage. The Hall generator generates a drop in the product from this only when the saturation of the choke u · i is proportional to the Hall voltage according to FIG. 4b. 19 is reached. In this case, a tilting error voltage is again shown hatched 21, which represents via switching transistors 22 and changes its sign with the voltage to be integrated, a counter 23 -tifn tion applied to DC voltage. If you go one step forward from the assumption. - from the fact that the error voltage is a square wave voltage to the mains voltage - "is also a phase, the mean value '" is connected to the converter 24, with the help of which the control voltage for the multivibrator 18 is rotated by 180 °

(2 ν 30 can be. In this way one can

1 -J for 0 S φ S ^ r ■ (7) grationsdrossel 19 alternately in the positive and

⁷¹ ' let the negative saturation be integrated. As soon as the

Saturation is reached, the control of the multi-Darin is U _K, the amplitude of the error voltage, vibrator 18 is changed, with the help of a Tran as shown in Fig. 4c. 35 sistor 26, which is in the direct current branch of a diode

One could thus achieve a compensation of the error bridge in series with a resistor 25 at the point when a direct voltage U _{Fm is} the input of the phase inverter 24. The phase position of the reducing throttle would also be fed. This control voltage for the multivibrator depends on the DC voltage would then have to depend on the power factor, whether the transistor 26 blocks or is permeable. of the consumer are controlled, which would mean a considerable 40. According to the invention, the Hallspan effort would now be required. circuit an adjustable square wave voltage

The present invention relates to a particularly dazzled one that is simplified by a square-wave oscillator 27 Solution of the problem described is supplied with a known structure. The control an electronic active consumption meter after which takes place with the help of one in the consumer circuit Main patent. According to the invention, the Korn- 45 current transformer 28, since the consumer current in prepensation achieved by the fact that in the Hallspan- lying case the input circuit which is not to be rectified an adjustable square wave voltage is one size. The control inputs of the square wave oscillator is dazzled, the same phase position as the not 27 are to the secondary winding of the converter 28 has the input variable to be rectified. The connected after that, the one limiting member 29 in parallel Amplification made demodulation generated 50 lies. To the secondary winding of the output transau This square-wave voltage is automatically required by the square-wave oscillator 27 Compensation voltage according to Fig. 4c. voltage divider consisting of two resistors 30 and 31

To take into account the actual shape of the closed, of which the resistor 31 is adjustable magnetization line of the core material, it is green and lies in the Hall voltage circuit.
stig, in the case of the compensation voltage in addition to a voltage, an alternating element dependent on the phase angle φ is also faded into the Hall voltage circuit, which can be introduced via a transformer to a constant element that is derived from the mains voltage according to 32, i.e. the further invention to be rectified by fading in an alternation - input variable, is derived. From which the voltage can be generated which has the same chip position as the input variable to be rectified. 60 voltage divider is the adjustable resistor 34 connected to the consideration of square and higher Hall voltage circuit.

Linking is not necessary for compensation, as it should be noted that under Hallspan

practice has shown. After demodulation, the entire current path between the

a Hall electrode and the integration choke are available from the displayed alternating voltage

commutated sinusoidal voltage according to FIG. 4d. 65 is standing. It is evident that the compensation

In FIG. 5, an exemplary embodiment of the invention voltages is not only in front of, but also

shown schematically, which occurs in many inputs within or at the end of the amplifier.

details at F i g. 1 of the main patent. can be dazzled.

The mode of operation of the compensation according to the invention is illustrated in FIGS. 4 clearly. With the aid of the square-wave oscillator 27, a square-wave voltage is generated which is in phase with the current curve i in FIG. 4a. Furthermore, an alternating voltage that is in phase with the voltage curve u is faded into the Hall voltage circuit. After the product formation from the sizes i and | u | In the Hall generator, the insertion of the two compensation voltages, the amplification and the demodulation, the integration choke is supplied with compensation voltages according to FIGS. 4c and 4d. The compensation voltage according to FIG. 4c takes into account the component dependent on the phase angle and that according to FIG. 4d takes into account the constant component of the error. Both parts can be considered separately from each other.

Claims (3)

Patent claims: 1. Electronic active consumption meter with a Hall multiplier, an AC amplifier to amplify the alternating current component of the Hall voltage, a downstream phase-sensitive rectifier bridge circuit whose control voltage is derived from the consumer voltage is derived and the output voltage is fed to the electronic integration of a circuit with a counter throttle, at to the Hall multiplier one of the two input variables, preferably the consumer voltage, is fed via a rectifier bridge circuit and the zero crossings of the control voltage coincide with the zero points of the rectified input variable of the Hall multiplier according to Patent 1,295,073, thereby characterized in that an adjustable square wave voltage in the Hall voltage circuit is displayed that has the same phase position as the input variable that is not to be rectified has. 2. Active consumption meter according to claim 1, characterized in that in the Hall voltage circuit In addition, an adjustable AC voltage is displayed that has the same phase position as the has the input variable to be rectified. 3. Active consumption meter according to claims 1 and 2, characterized in that in the Hall voltage circuit is the output of a square-wave generator triggered by the consumer current (27) and the secondary winding of a transformer (32) connected to the AC voltage is connected. - - 1 sheet of drawings