JPH03150477A - Power transducer - Google Patents

Abstract

PURPOSE:To prevent the change in ON-time resistance of a switch caused by the temperature and also to suppress the generation of transient at the switching time by impressing the voltage which is converted from an AC current, on the switch after converting it to the current signal by a voltage/current converting circuit. CONSTITUTION:The AC current Ii from an object to be measured is outputted to a resistor RL as a voltage signal VL. This voltage signal Vi is converted to the AC current signal (i) by the voltage/current converting circuit V/I. This current signal (i) is outputted to an inversion input end (-) of adding/integrating circuit Q1 through a switch SW1 and at the same time outputted to an inversion input end (-) of inversion amplifier Q3 through a switch SW3. The switch SW1 is opened/closed by a control signal CS and the switch SW3 is opened/ closed by a inversion control signal <CS>, and each current signal (i) are formed to the currents i1, i2 respectively. Those are added and integrated by the adding/integrating circuit Q1, thereby the voltage signal V02 multiplied by the objective voltage and current, that is the electric power, is obtained.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to an electric quadrature transducer for measuring the electric power of an object to be measured, and in particular improves characteristics such as eliminating the influence of mixed coal while simplifying the configuration. Regarding the power l-transducer.

<Prior art> Figure 4 shows the conventional power using a pulse width modulation multiplier).
FIG. 2 is a block diagram showing the configuration of a transducer.

The AC voltage V from the object to be measured is outputted to the pulse width modulator PWM via the voltage transformer P'.On the other hand, the pulse width modulator PWM receives a carrier frequency having a predetermined pulse width from the oscillator OSC. FC is supplied.

The pulse width of this carrier frequency 1·c is modulated by the AC voltage Vi, and the control signal CS has a duty corresponding to this AC voltage (■), and the inverted control signal < C
S > is output to the output terminals Q and <Q> of the pulse width modulator PWM.

An alternating current I from the object to be measured is input through a current transformer Ci' and output as a voltage signal 1 to a resistor R+ connected to its output winding. This voltage signal ■1- is connected to the resistor R,5,! 14100 switch SW.

Add/integrate through l? 8Q, inverting input terminal (-)
is output to. Then, this resistance l<, and the switch SW
1 is connected to a common potential point COM via a semiconductor grounding switch SW2.

Furthermore, the voltage 1C Vl is applied to the inverting amplifier Q2. resistance R2,
and is outputted to the inverting input terminal (-) of the addition/integration circuit Q1 via the switches SW, , @. And this resistance R2
The connection point between the I' conductor and the semiconductor switch SW3 is connected to the common potential point COM via the grounding switch SW, l of the I' conductor.

Switches SW and SW4 are opened and closed by control signals jj and CS, and switches SW2 and SW3 are opened and closed by control signals <CS
>, and a DC signal Vo1 proportional to the power to be measured is output to the output terminal of the addition/integration circuit Q1.

In the configuration I below, the on time 1,1 of the switch SW is determined by the control signal C8, and the inversion control D of the switch SW3 is
The on-times 1 and 2 due to +V<CS> are both proportional to the AC voltage V.

In addition, a voltage signal Vl proportional to the magnitude of the alternating current I is applied to the switch 8W, and a current that is the inverse of this Dengetsu No. 318 V1 flows through the switch SW3, so these are added and integrated. The currents added in circuit Q1 end up being AC voltage ■1 and AC current 1. The value is proportional to the product of Addition・
Integrating circuit Q1 outputs a voltage corresponding to this product. Outputs 1.

<Problems to be Solved by the Invention> However, since the above-mentioned power 1-langue generator is configured as a semiconductor switch such as the switch SWI, SW:l, etc., the temperature coefficient of the on-resistance of these switches is ignored. Moreover, the deterioration of linearity due to 1 to range engine 1 in the switching of these switches cannot be ignored.

In addition, if this power source 1 to Lance 7 is configured as a 3-phase 3-wire or 3-phase 4-wire polyphase power source 1 to Lance 7, for example, a large number of inverting amplifiers are required. It has the disadvantage of being expensive.

Means for Solving the Problems> In order to solve the problems, the present invention provides pulse width modulation means for pulse width modulating an AC voltage to be measured and outputting a control signal and an inverted control signal. , a first stage of constant current conversion for converting an alternating current to be measured into a constant current corresponding to the alternating current; a first switch means that is switched by a control signal and outputs the constant current as a first switching current;
Inversion control (inversion amplification means that inverts the polarity of the constant current switched by REj and outputs it as a first switching current, and a direct current that corresponds to the power to be measured by adding and integrating these first and second switching currents) The addition/integration means for outputting a signal is implemented.

Function: The pulse width modulation means pulse width modulates the AC current to be measured, outputs a control signal and this inversion control signal, and the constant current conversion means converts the AC current to be measured into a constant value corresponding to this AC current. The constant current is converted into a current, and the constant current switched by the control signal by the first switching means is outputted to the addition/integration means together with the first switching current, and the inverting amplification stage - 4L is switched by the inverting control signal. The polarity of the constant current is reversed and output as a second switching current to the addition/integration means together with the first switching current, and the iCi corresponding to the power to be measured is sent to the output terminal of the addition/integration means.
Obtain idiom i).

<Example> Examples of the present invention will be described above with reference to the drawings. FIG. 1 is a small-scale B+Cock diagram of the configuration of one practical example of the present invention.

Note that for parts not shown in FIG. 4 that have the same functions as the power transducer, the same reference numerals will be replaced by 1 and I, and the description thereof will be omitted as appropriate.

An alternating current 1i from the object to be measured is input via a current transformer CT, and is output as a voltage signal V1 to a resistor connected to its output winding. This electric current (n-signal i9) is converted by the voltage/current conversion circuit V/I into an alternating current signal (j) corresponding to electric current (IF), electric current (1).

This current signal i is outputted to the inverting input terminal (-) of the adder/integrator circuit Q via switch SW, and is also outputted to the inverting input terminal (-) of the inverting amplifier Q3 via switch SW3. This inverting amplifier Q3 has its non-inverting input terminal (G) connected to the common potential point COM, and its inverting input terminal (-
) is connected to the output terminal via a resistor R3. This output terminal is connected to the inverting input terminal (-) of the addition/integration circuit Q1 via a resistor Rd.

The switch SW is opened and closed by the control signal C8, and the switch SW3 is opened and closed by the inversion control ridge <c S >, and the current signal i is set to the current j4.42, and these are connected to the feedback circuit with a resistor R and a capacitor C. They are added and integrated by an addition/integration circuit Q1 to which a parallel circuit is connected, and output as an output voltage V02 to its output terminal.

Next, the operation of the embodiment configured as shown below will be explained using the waveform diagram shown in FIG.

FIG. 2(a) shows the waveform of the control signal C8 output from the output terminal Q of the pulse width converter PWM, and the second l;M
l (I7> is the waveform of the inverted control signal -q<cs> output from its inverted output terminal <Q>. In both cases,
Control signal i3 (,: S on period l17, off period [
, 2 match the off period and on period of the inverted control signal <CS>.

And these on period 1.1 and off period 1, 2 are as follows.
It is modulated by the alternating current voltage, and the following relationship holds true between A and 13 as constants and the deviation.

t+ /(t+ +t, 2) A [1+(Vi /[3) J...(1)+
-2/ (1-+ + 1-2) A 1.1. (Vi/B)] ...(2
) Also, the currents i1.12 switched by the switches SW + and SW 3 are j, = CL, I 7 / (t, + −L 1'
-2)...(3)i2- Ct2Ii (R:+
/Ra)/(1,++j2)...(4)
It has something to do with this. (Fj and C are constants.

Here, select h3/R,=1, and add/integrate circuit Q1.
Output voltage integrated by ■. 2 becomes as follows.

VO2= (l I +12) R=+C1i 1
Pe3 (t, +-t2)/'(t, + -1-
t-2) 2ACVllll/f3 ■VI I I ... (
5) In this way, a voltage obtained by multiplying the voltage and current of the measurement object is transmitted to the output terminal of the addition/integration circuit Q1, and the power consumed by the measurement object is obtained from -1.

FIG. 3 is a block diagram showing the configuration of an embodiment of the present invention when measuring polyphase AC power.

When measuring three-phase, four-wire polyphase alternating current, a '3 wattmeter model is used, and this embodiment shows the configuration for this case.

V, ~ ■3 are respectively (16 to 11
i11 is the AC voltage from the constant object. Oscillator (') S
C.

~OS C3 respectively connect the oscillator OS C and the pulse width modulator 1. ) W M + ~, l) W M 3 are respectively connected to pulse width modulators 1' W M and voltage transformers S l''
I'', ~I'i' 3 are respectively voltage transformers P l
It has a configuration corresponding to ``.

The control signals C8, -, C8, and the inverted control signals C8,〉~, and <CS3> have similar waveforms to the control signals C5 and C8, respectively, but their pulses The widths correspond to AC voltages V, .about.3, respectively.

Switches SW5 and SW7.8W9 each have a control signal C.
8, , cs2, cs3, switches SW6, SW
s, SW+. are respectively inverted control (No. 34<C8I>
, <CS2>, <,CS3>.

Further, 11 to 13 are alternating currents from the measurement target corresponding to alternating current 1, respectively. Current transformer CT,~,c
'+', . . . each have a configuration corresponding to the current transformer C'F. Therefore, the voltage signal V14,
~V l 3 occurs in the same way as Dengetsu-Kaigo V.

These electric j+ are electric moon −/current conversion circuit V/].

−v/13, the voltages t, Vll, ~VI3, respectively
is converted into a current signal jj corresponding to switch 1) YSW
5 to SW, o are opened and closed, and finally added in an addition/integration circuit, and output as an output voltage o3 to its output terminal. This output voltage V. 3 is proportional to the power consumed by the measurement target, as in the case shown in FIG. 1.

<Effects of the Invention> As explained in detail in conjunction with the 1-1 embodiment, according to the present invention, after converting an alternating current into a voltage, the voltage/current converter circuit converts the alternating current into a current signal, which is then applied to the switch. This makes it possible to prevent changes in the on-resistance of the switch due to temperature, and also to suppress the occurrence of transients during switching. Furthermore, since the inverting amplifier is inserted after the switch, the grounding switch can be omitted. Furthermore, since only one inverting amplifier is required for constructing a multiphase alternating current electroquadratic transducer, the construction is simple and the cost can be reduced to 1.

[BRIEF DESCRIPTION OF THE DRAWINGS] Fig. 1 is a block diagram showing the configuration of an embodiment of the present invention, Fig. 2 is a waveform diagram explaining the operation of the embodiment shown in Fig. 11172 and FIG. 4 are block diagrams showing the configuration of a conventional power 1 Herans duuser. 1-"I', P'T'+ ~ P T 3- Voltage transformation device, 'l', C'1゛, ~CT3...Current transformer, PWM, PWM + \PWM3・
...Pulse width modulator, V/1. V/'], -V/I,・
・・Voltage/current conversion circuit, Q, ・・Addition/integration circuit,
Q2, Q3...inverting amplifier.

Claims (1)

[Claims] pulse width modulation means for pulse width modulating an alternating voltage to be measured and outputting a control signal and an inverted control signal; constant current converting means for converting the alternating current to be measured into a constant current corresponding to the alternating current; , first switching means that is switched by the control signal and outputs the constant current as a first switching current; and inverting amplification means that inverts the polarity of the constant current that is switched by the inversion control signal and outputs it as a second switching current. and an addition/integration means for adding and integrating these first and second switching currents and outputting a DC signal corresponding to the power of the object to be measured.