DE2519668C3 - Arrangement for generating a sequence of pulses proportional to the product of two analog electrical quantities - Google Patents

Description

The invention relates to an arrangement /.ur generating a sequence of pulses proportional to the product of two analog electrical quantities, in particular for measuring electrical power and energy, in which an analog electrical quantity derived from the one measured quantity χ to be multiplied is derived from an integration stage an inonostable multivibrator and a reference voltage source existing current-Frcqucnz-Wandlcr is supplied, with a reference value derived from the reference voltage source superimposed on the analog electrical quantity for a time predetermined by the monostable multivibrator

<-, it becomes that it is directed against this size and to leads to a discharge of the integral ion capacitor of the integration stage.

The electrical power is generally measured by multiplying that of the

in measuring voltage and electrical derived from the measuring current Sizes in an analog multiplier stage. To record the electrical energy, it is necessary integrate the power measured in this way over time. For this purpose, the analog product value often becomes

π into one with the help of an analog-frequency converter proportional frequency converted. Then there is a device for measuring the electrical energy essentially consisting of an analog multiplier and an analog frequency converter. These are thanks to the Today's technology can be implemented electronically, but the technical effort is so far still greater than that of classic measuring principles. Therefore, the electricity meters were able to use electronic measuring units compared to the electrical

2 ^r > ity counters with Ferraris measuring mechanism as household counters for economic reasons not yet prevail. This is primarily opposed by the fact that with the currently known electronic measuring principles the analog multiplier stage and the analog frequency

(i) Converter two independent components form and that each of the two systems influences the measurement error independently of one another.

An arrangement of the type described above has become known from CH-PS 4 88 192. at

ΐϊ this well-known arrangement is to either of the two A dedicated analog-to-digital converter is assigned to multiplying variables. The pulse trains of the two Analog-to-digital converters are fed to a coincidence circuit which is controlled by a sampling oscillator

κι is clocked. The effort of the known arrangement is therefore relatively expensive.

The invention is based on the object of creating an arrangement which requires less effort. This object is achieved according to the invention

■ r> solved that the switching time of the monostable multivibrator is determined by an analog electrical variable derived from the second measured variable in such a way that the switching time is inversely proportional to the magnitude of this quantity, making one the product of the two

■ In analog electrical quantities proportional charging and discharging of the integration capacitor takes place and thus the frequency of the charging and discharging is proportional to the product of the two measured quantities.
The arrangement according to the invention is special

μ suitable for measuring electrical power and Energy in single-phase alternating current systems. Advantageously, one input variable is then from the Measurement current and the other input variable derived from the measurement voltage, the phase relationship

«Ι between the two measured quantities by one of the known circuits is taken into account. A particularly simple solution results from the fact that the the input variable proportional to the measuring current is fed via a switch to the integration stage, the

hi from a comparator preamplifier connected to the mains voltage to form the phase connections of the two input variables is controlled.

This enables the construction of a simple electrical circuit

Uiiszflhlers, since the two components analog multiplier and analog-frequency converter through a single component, which is also very simple in structure are replaced. The arrangement according to the invention can with practically undiminished accuracy compared to the ". known more complex arrangements can also be used economically for household meters and is competitive with the classic meter designs.

To measure the electrical power and energy in the In three-phase alternating current networks, the arrangement according to the invention is repeated for each phase, with the Output pulses of the individual arrangements are summed, so that the total number of output pulses corresponds to the energy consumption in the three phases. ι -,

Although the invention is used here solely from the standpoint of measuring electrical energy has been considered, the basic idea of this invention is of much greater importance.

The invention is explained in more detail with the aid of the drawing: n explained; it shows

F i g. 1 the principle of arrangement and

Fig.2 shows an embodiment for measuring the electrical energy in a single-phase network.

The measuring unit consists essentially of a> -, current-frequency converter, which is composed of Figure 1 of an integrator 6, a monostable multivibrator 8 and a reference voltage source.. 1, 2 and 10 denote the inputs and 9 denotes the output of the current-frequency converter. The input variable x derived from one of the two measured variables to be multiplied is at input 2 _t11. It is fed to the current-frequency converter via a resistor 4 and charges an integration capacitor 7 until the response threshold of the monostable π trigger stage 8 is reached. At this moment - via a resistor 3 and switch 5 - a current derived from the reference variable ζ of the reference voltage source is superimposed on the current derived from the input variable χ for a predetermined time Ti by the flip-flop stage in such a way that it is directed in the opposite direction; this leads to a discharge of the integration capacitor 7. This process is repeated with a repetition frequency F that is inversely proportional to the input variable χ and the reference variable ζ and the switching time Ti, the .y, monostable multivibrator

F = A "

ν r

K is a converter constant resulting from the circuitry, parameters. If the switching time Ti of the monostable multivibrator 8 is determined by an input variable y derived from the second measured variable in such a way that Ti is inversely proportional to y . then -, -, is

A- ' ^{1 =} .V

This results in an output frequency F _W) at output 9 which is proportional to the product of the two measured variables. The input variable y is fed to the monostable multivibrator via input IO and resistor II.

F - k -

where K ' and K "are also constants. If the input variables χ and y are derived from the measuring current or the measuring voltage at a consumer, the number of output pulses of the measuring circuit is directly proportional to the electrical energy consumed.

The main advantage of the proposed circuit for measuring electrical power is that in comparison to the existing solutions there is less need for electronic components, above all To achieve things is because of the power-frequency conversion is carried out in one step.

Fig. 2 shows an embodiment of the invention for measuring electrical energy in single-phase networks. Effectiveness? the same parts have the same reference numerals as in rig. I provided. The earthed neutral conductor is denoted by 15 and the conductor of phase R is denoted by iö. In this case, the input variable χ is derived from the measuring current. It is formed by the voltage drop of the measuring current at a shunt 17, one end of which is connected to the input of the current-frequency converter via the resistor 4, while the other end is connected to the device ground. The device ground therefore carries the potential of phase R.

A solution with a current transformer whose secondary current at a load resistor has a corresponding Voltage drop is also possible.

The second input variable y is derived directly from the measurement voltage. For this purpose, the anode of a diode 12 is connected to the neutral conductor 15 and its cathode is connected to the device ground carrying the potential of the R phase via a smoothing capacitor 13. This second input variable y then appears as a smoothed DC voltage at the output 10 of the external the diode 12 and the smoothing capacitor 13 existing rectifier circuit and feeds a current proportional to it via the resistor 11 into the current-controlled monostable multivibrator a. The influence of the phase shift between current and voltage can be taken into account with the aid of circuits known per se. In FIG. 2, a comparator amplifier 18 and a switch 19 are available as substitutes for this purpose, the effect of which corresponds to that of a phase-controlled rectifier. One input of the comparator amplifier is connected to the neutral conductor 0, while the other input is connected to the device ground carrying the potential of the R phase. The pulses present at the output of the power-frequency converter are added up in a pulse counter 14!

The solution indicated in Fig. 2 already represents the main part of an electronic system for measurement of electrical energy. Only the supply part and the display are missing, so that the proposed one System forms a single-phase alternating current meter.

For this I Blatt Zcichiuinticn

Claims (5)

Patent claims: 1. Arrangement for generating a sequence of pulses proportional to the product of two analog electrical quantities, in particular for measuring electrical power, in which an analog electrical quantity derived from the one measured quantity fxj to be multiplied consists of an integration stage, a monostable multivibrator and a reference voltage source Current-frequency converter is supplied, with a reference variable ζ derived from the reference voltage source being superimposed on the analog electrical variable for a time specified by the monostable multivibrator in such a way that it opposes this variable and causes a discharge of the integration capacitor of the integration stage , characterized in that the switching line fT,) of the monostable multivibrator (8) is determined by an analog electrical variable derived from a second measured variable (y) in such a way that the switching time (7Ί) is inversely proportional to the amount of this variable (y) , whereby a charging and discharging of the integration capacitor (7) proportional to the product of the two analog electrical quantities (x, y) takes place and thus the frequency (F) of the charging and discharging is proportional to the product of the two measured quantities (x, y) \ sv . 2. Arrangement according to claim I for measuring the electrical power in single-phase AC networks, characterized in that one input variable (x) is derived from the measurement current and the other input variable (\) is derived from the measurement voltage, the phase relationship between the both measured variables is taken into account by one of the known circuits. 3. Arrangement according to claim 2, characterized in that the input variable (x) proportional to the measuring current is fed to the integration stage (6) via a switch (19) which is supplied by a comparator amplifier (18) connected to the mains voltage to form the phase relationships of the two Input variables is controlled. 4. Arrangement according to one of claims I to 3, characterized in that for measuring the electrical energy, a counter (14) is connected downstream. 5. Arrangement according to claims 1 to 3 / ur measurement of electrical power and energy in Three-phase alternating current networks, characterized in that in each phase the arrangement for Power measurement is provided and the output impulses summed up of the individual arrangements will.