CN101661057A

CN101661057A - Device for implementing power measurement based on resistance sampling by linear optocoupler

Info

Publication number: CN101661057A
Application number: CN200910307802A
Authority: CN
Inventors: 康尔良; 卫爱平
Original assignee: Harbin University of Science and Technology
Current assignee: Shuangyashan Electric Co Of Guo Wang Heilongjiang Power Co Ltd; State Grid Corp of China SGCC
Priority date: 2009-09-27
Filing date: 2009-09-27
Publication date: 2010-03-03
Anticipated expiration: 2029-09-27
Also published as: CN101661057B

Abstract

A device for implementing power measurement based on resistance sampling by a linear optocoupler belongs to the electrical measurement field. The device aims at solving the problem of low measurementprecision due to long-distance transmission of measurement results of the existing current dividers/voltage dividers. The device is realized by current signal measurement and voltage signal measurement. An analog current signal acquired by a current divider is converted into a digital signal by a current operation amplification module and a linear optocoupler isolation module, an analog voltage signal acquired by a voltage divider is converted into a digital signal by a voltage operation amplification module and a linear optocoupler separation module, digital signal processing and operation module DSP processing are performed on the obtained two digital signals, polarity of the current signal is judged by a current polarity judgment circuit which transmits identification to the DSP, polarity of the voltage signal is judged by a voltage polarity judgment circuit which transmits identification to the DSP, and the DSP controls a synchronous acquisition voltage signal and a synchronous acquisition current signal. The device is used for field precision power measurement.

Description

Adopt the power-measuring device of linear optical coupling realization based on resistance sampling

Technical field

The present invention relates to a kind of power-measuring device that adopts the linear optical coupling realization based on resistance sampling, belong to the electric measurement field.

Background technology

The result that the power-measuring device of electric measurement system will obtain is an active power, reactive power, the phase differential of applied power and voltage signal and current signal, the technological means that adopts mostly is synchronous acquisition current signal and voltage signal at present, utilize current transformer or Hall current sensor to gather current signal, utilize voltage transformer (VT) or Hall voltage sensor acquisition voltage signal, but current/voltage mutual inductor, Hall current/voltage sensor is used in the electric measurement system has certain limitation, the restriction that the current/voltage mutual inductor is subjected to frequency band can only detect near the current/voltage signal of frequency band rated frequency ± 5%, and signal is non-direct current signal; The frequency band that Hall current/voltage sensor uses is 0-100kHz, though can satisfy existing electric measurement frequency band requirement and Current Control precision, it is difficult in satisfies high-precision measurement requirement in whole frequency band and the range ability.Their application cost is all far above shunt/voltage divider.Therefore, shunt/voltage divider has obtained widespread use in the electric measurement field.

Use shunt in the electric measurement field and detect electric current, detect the mode of voltage with voltage divider, the simplest with its structure, the advantages of higher of kinetic current/change in voltage real-time once was used widely, but, the design feature of the long Distance Transmission of existing shunt/voltage divider influences measuring accuracy, cause measuring accuracy low: the voltage parameter behind the shunt sample rate current, voltage parameter after the voltage divider sampling will be unified to use and handle to background PC computer through long Distance Transmission, current sample gained voltage signal, voltage parameter after the voltage divider sampling can produce line drop in transmission course, and then influences the accuracy of detection of electric current; Because long Distance Transmission, disturb and cause that the sampled signal nonlinearities change influences the popularity that shortcoming such as accuracy of detection has restricted its application again thereby sampling circuit is subject to electromagnetic environment.

Summary of the invention

The measurement result that the objective of the invention is to solve existing shunt/voltage divider causes the low problem of measuring accuracy through long Distance Transmission, provides a kind of linear optical coupling that adopts to realize power-measuring device based on resistance sampling.

The present invention includes shunt, voltage divider, current operator amplification and linear optical coupling isolation module, voltage operational amplifies and linear optical coupling isolation module, current polarity decision circuitry, polarity of voltage decision circuitry, electric current A/D change-over circuit, voltage A/D change-over circuit and digital signal processing and computing module DSP

The sampling resistor Ri two ends extension line of shunt is the voltage signal output end of shunt, the voltage signal output end of described shunt links to each other with the input end of linear optical coupling isolation module with the current operator amplification, the current operator amplification links to each other with the input end of electric current A/D change-over circuit with the output terminal of linear optical coupling isolation module, the output terminal of electric current A/D change-over circuit links to each other with the current sample input end of digital signal processing and computing module DSP, the current operator amplification links to each other with the input end of current polarity decision circuitry with the current polarity signal output terminal of linear optical coupling isolation module, the output terminal of current polarity decision circuitry links to each other with the current polarity control end of digital signal processing and computing module DSP

The divider resistance Rv two ends extension line of voltage divider is the voltage signal output end of voltage divider, the voltage signal output end of described voltage divider links to each other with the input end of linear optical coupling isolation module with the voltage operational amplification, the voltage operational amplification links to each other with the input end of voltage A/D change-over circuit with the output terminal of linear optical coupling isolation module, the output terminal of voltage A/D change-over circuit links to each other with the voltage sample input end of digital signal processing and computing module DSP, the voltage operational amplification links to each other with the input end of polarity of voltage decision circuitry with the polarity of voltage signal output part of linear optical coupling isolation module, the output terminal of polarity of voltage decision circuitry links to each other with the polarity of voltage control end of digital signal processing and computing module DSP

The synchronized sampling control end of digital signal processing and computing module DSP links to each other with the current sample control end of electric current A/D change-over circuit and the voltage sample control end of voltage A/D change-over circuit simultaneously.

Advantage of the present invention is: the voltage signal that shunt/the voltage divider sampling obtains need not be grown Distance Transmission and handle to the backstage, directly utilize digital signal processing and computing module DSP to handle at the scene, the result that direct acquisition will be used, it is the phase differential of active power, reactive power, applied power and voltage signal and current signal, like this, do not cause line drop in the time of can be, guaranteed the high precision of measuring because of long Distance Transmission.

Description of drawings

Fig. 1 is a structural representation of the present invention, and Fig. 2 is the measuring principle figure of shunt and voltage divider, and Fig. 3 is the structural representation of current operator amplification and linear optical coupling isolation module, and Fig. 4 is the structural representation of voltage operational amplification and linear optical coupling isolation module

Embodiment

Embodiment one: present embodiment is described below in conjunction with Fig. 1 and Fig. 2, the described employing linear optical coupling of present embodiment is realized comprising that based on the power-measuring device of resistance sampling shunt 1, voltage divider 2, current operator amplification and linear optical coupling isolation module 3, voltage operational amplify and linear optical coupling isolation module 4, current polarity decision circuitry 5, polarity of voltage decision circuitry 6, electric current A/D change-over circuit 7, voltage A/D change-over circuit 8 and digital signal processing and computing module DSP9

The sampling resistor Ri two ends extension line of shunt 1 is the voltage signal output end of shunt 1, the voltage signal output end of described shunt 1 links to each other with the input end of linear optical coupling isolation module 3 with the current operator amplification, the current operator amplification links to each other with the input end of electric current A/D change-over circuit 7 with the output terminal of linear optical coupling isolation module 3, the output terminal of electric current A/D change-over circuit 7 links to each other with the current sample input end of digital signal processing and computing module DSP9, the current operator amplification links to each other with the input end of current polarity decision circuitry 5 with the polar signal output terminal of linear optical coupling isolation module 3, the output terminal of current polarity decision circuitry 5 links to each other with the current polarity control end of digital signal processing and computing module DSP9

The divider resistance Rv two ends extension line of voltage divider 2 is the voltage signal output end of voltage divider 2, the voltage signal output end of described voltage divider 2 links to each other with the input end of linear optical coupling isolation module 4 with the voltage operational amplification, the voltage operational amplification links to each other with the input end of voltage A/D change-over circuit 8 with the output terminal of linear optical coupling isolation module 4, the output terminal of voltage A/D change-over circuit 8 links to each other with the voltage sample input end of digital signal processing and computing module DSP9, the voltage operational amplification links to each other with the input end of polarity of voltage decision circuitry 6 with the polar signal output terminal of linear optical coupling isolation module 4, the output terminal of polarity of voltage decision circuitry 6 links to each other with the polarity of voltage control end of digital signal processing and computing module DSP9

The synchronized sampling control end of digital signal processing and computing module DSP9 links to each other with the current sample control end of electric current A/D change-over circuit 7 and the controlling of sampling end of voltage A/D change-over circuit 8 simultaneously.

What apparatus of the present invention realized is the measurement of power, and the measurement of power need be gathered two signals, a current signal, one is voltage signal, in the present embodiment, gathers current signal with shunt 1, gather voltage signal with voltage divider 2, its measuring principle is described referring to Fig. 2.

Shunt 1 has sampling resistor Ri, and the sampling resistor Ri of shunt 1 is series in the tested loop, knows the shunting voltage u at described sampling resistor Ri two ends _iCan try to achieve current i, i=u _i/ Ri, the voltage signal at the described sampling resistor Ri two ends of sampling flow to current operator and amplify and linear optical coupling isolation module 3.

Whole resistance of voltage divider 2 are R _T, be connected in parallel in the loop that needs to measure resistance R _TThe tested voltage in two ends is U, divider resistance R _vIt is resistance R _TA part, divider resistance R _vThe branch pressure voltage at two ends is u _v, gather divider resistance R _vThe branch pressure voltage u at two ends _vFlow to voltage operational and amplify and linear optical coupling isolation module 4 u _v=U * R _T/ R _v, general divider resistance R _vResistance very little, so just can realize the measurement of high pressure.

Describe gathering current signal earlier, referring to shown in Figure 3, current operator amplifies and linear optical coupling isolation module 3 comprises the two large divisions, a part is that computing is amplified, another part is a linear optical coupling, the circuit that can realize this function has a lot, the circuit that present embodiment provides as shown in Figure 3, current operator amplifies and linear optical coupling isolation module 3 comprises the first linear optical coupling OC1, first resistance R 1, second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the 5th resistance R 5, the 6th resistance R 6, the first integrated transporting discharging A1, the second integrated transporting discharging A2, the 3rd integrated transporting discharging A3, the first diode D1, the second diode D2, the 3rd diode D3, the 4th diode D4, first capacitor C 1, second capacitor C 2 and the 3rd capacitor C 3, the first linear optical coupling OC1 is by first LED, the feedback light electric diode PD1 and the first output photodiode PD2 form, one end of first resistance R 1 links to each other with the voltage signal output end of shunt 1, the other end of first resistance R 1 links to each other with the positive pole of the first diode D1, the other end of first resistance R 1 links to each other with the negative pole of the second diode D2 simultaneously, the negative pole of the first diode D1 links to each other with the inverting input of the first integrated transporting discharging A1 and the negative pole of feedback light electric diode PD1 simultaneously, first capacitor C 1 is connected in parallel between the inverting input and output terminal of the first integrated transporting discharging A1, the 3rd diode D3 is connected in reverse parallel between the inverting input and output terminal of the first integrated transporting discharging A1, the output terminal of the first integrated transporting discharging A1 links to each other with an end of the 4th resistance R 4, and the other end of the 4th resistance R 4 links to each other with the negative pole of LED;

The positive pole of the second diode D2 links to each other with the positive pole of feedback light electric diode PD1, the anodal of the second diode D2 links to each other with the inverting input of the second integrated transporting discharging A2 simultaneously, second capacitor C 2 is connected in parallel between the inverting input and output terminal of the second integrated transporting discharging A2, the 4th diode D4 forward is connected in parallel between the inverting input and output terminal of the second integrated transporting discharging A2, and the output terminal of the second integrated transporting discharging A2 links to each other with the positive pole of LED;

The tie point extension line of the normal phase input end of the first integrated transporting discharging A1 and the normal phase input end of the second integrated transporting discharging A2 links to each other with an end of the 3rd resistance R 3, the other end ground connection of the 3rd resistance R 3, the tie point extension line of the normal phase input end of the first integrated transporting discharging A1 and the normal phase input end of the second integrated transporting discharging A2 links to each other with an end of second resistance R 2 simultaneously, and the other end of second resistance R 2 links to each other with current polarity decision circuitry 5.

The conversion accuracy that linear optical coupling occurs with market the highest with frequency band the highest come type selecting, in the present embodiment, the first linear optical coupling OC1 adopts HCNR200 molded lines optocoupler or HCNR201 molded lines optocoupler.Shunting voltage signal u _iThe linear transformation primary side by the feedback light electric diode PD1 and first LED of the first linear optical coupling OC1, the first diode D1, the second diode D2, the 3rd diode D3, the 4th diode D4, first resistance R 1, second resistance R 2, the 3rd resistance R 3, the 4th resistance R 4, the first integrated transporting discharging A1, the second integrated transporting discharging A2, first capacitor C 1, second capacitor C 2 are formed.

The linear transformation secondary side is exported photodiode PD2 by first of the first linear optical coupling OC1, the 3rd integrated transporting discharging A3, and the 5th resistance R 5, the 6th resistance R 6 and the 3rd capacitor C 3 are formed, and the gain G AIN that act as signal of the 6th resistance R 6 regulates.

When first LED passes through drive current If, send infrared light (servo luminous flux).This light is radiated at respectively on feedback light electric diode PD1, the first output photodiode PD2, and feedback light electric diode PD1 absorbs the part of servo luminous flux, thereby produces Control current I1 (I1=0.005If).This electric current is used for regulating If to compensate the non-linear of first LED.The linear ratio of servo luminous flux that the output current I2 that the first output photodiode PD2 produces and first LED send.Make servo current gain K1=I1/If, forward gain K2=I2/If; Transmission gain K3=K2/K1=I2/I1 then, the representative value of K3 is 1.Shunting voltage signal u _iWhen importing for positive polarity, this road of the first diode D1, the first integrated transporting discharging A1 participates in work, positive polarity output; Shunting voltage signal u _iWhen importing for negative polarity, this road of the second diode D2, the second integrated transporting discharging A2 participates in work, and negative polarity output that is to say, shunting voltage signal u _iCan be just also can be negative, promptly shunt voltage signal u _iCan be direct current, also can be to exchange.At the on-the-spot general measure of electric measurement all is AC signal, is that object describes with the sampling AC signal below.

Shunting voltage signal u _iThe judgement of polarity finish by current polarity decision circuitry 5, current polarity decision circuitry 5 comprises the 4th integrated transporting discharging A4, the 5th integrated transporting discharging A5, the 7th resistance R 7, the 8th resistance R 8 and the second linear optical coupling OC2, the second linear optical coupling OC2 comprises second LED 2, the second output photodiode PD3, the first triode T1, the second triode T2, the positive pole of the second output photodiode PD3 links to each other with the base stage of the first triode T1, the negative pole of the second output photodiode PD3 links to each other with the collector of the first triode T1, the emitter of the first triode T1 links to each other with the base stage of the second triode T2, the grounded emitter of the second triode T2

The inverting input of the 4th integrated transporting discharging A4 links to each other with the other end of first resistance R 1 of current operator amplification and linear optical coupling isolation module 3, the positive input end grounding of the 4th integrated transporting discharging A4, the output terminal of the 4th integrated transporting discharging A4 links to each other with the other end of second resistance R 2 of current operator amplification and linear optical coupling isolation module 3, the output terminal of the 4th integrated transporting discharging A4 links to each other with the normal phase input end of the 5th integrated transporting discharging A5 simultaneously, the reverse inter-input-ing ending grounding of the 5th integrated transporting discharging A5, the output terminal of the 5th integrated transporting discharging A5 links to each other with an end of the 7th resistance R 7, the other end of the 7th resistance R 7 links to each other with the positive pole of second LED 2, the minus earth of second LED 2

The collector of the first triode T1 links to each other with the end of power Vcc with the 8th resistance R 8 simultaneously, the other end of the 8th resistance R 8 links to each other with the collector of the second triode T2, the tie point extension line of the collector of the other end of the 8th resistance R 8 and the second triode T2 is as the output terminal of current polarity decision circuitry 5, and output current polarity identifies V _Sign1

Shunting voltage signal u _iDuring for positive polarity, current polarity decision circuitry 5 output current polarity sign V _Sign1=0, shunting voltage signal u _iDuring for negative polarity, current polarity decision circuitry 5 output current polarity sign V _Sign1=1, current polarity identifies this switching value and gives digital signal processing and computing module DSP9, is used to judge that current signal is in positive half period or negative half-cycle.

Current operator amplifies and linear optical coupling isolation module 3 output analog voltage signal U _Out1, described analog voltage signal U _Out1Port connects electric current A/D change-over circuit 7, and electric current A/D change-over circuit 7 is with analog voltage signal U _Out1Convert 16 digital signal to, and export to digital signal processing and computing module DSP9.

Describe gathering voltage signal more below, referring to shown in Figure 4, the structure of voltage operational amplification and linear optical coupling isolation module 4 and current operator amplification and linear optical coupling isolation module 3 are identical, branch pressure voltage signal u _vAmplify and linear optical coupling isolation module 4 output analog voltage signal U through voltage operational _Out2, described analog voltage signal U _Out2Port connects voltage A/D change-over circuit 8, and voltage A/D change-over circuit 8 is with analog voltage signal U _Out2Convert 16 digital signal to, and export to digital signal processing and computing module DSP9.

Branch pressure voltage signal u _vThe judgement of polarity finish by polarity of voltage decision circuitry 6, the structure of polarity of voltage decision circuitry 6 and current polarity decision circuitry 5 are identical, polarity of voltage decision circuitry 6 output voltage polarity sign V _Sign2, branch pressure voltage signal u _vDuring for positive polarity, polarity of voltage decision circuitry 6 output voltage polarity sign V _Sign2=0, branch pressure voltage signal u _vDuring for negative polarity, polarity of voltage decision circuitry 6 output voltage polarity sign V _Sign2=1, polarity of voltage identifies this switching value and gives digital signal processing and computing module DSP9, is used to judge that voltage signal is in positive half period or negative half-cycle.

For the accuracy that guaranteed output calculates, the voltage signal in the same loop of synchronous acquisition and current signal data guaranteeing the simultaneity of phase place collection, and then calculating voltage and current and phase difference are only correct.Therefore, by digital signal processing and computing module DSP9 Control current A/D change-over circuit 7 and 8 while of voltage A/D change-over circuit acquired signal, and read it and export digital signal, digital signal processing and computing module DSP9 preserve real time data, calculate first-harmonic effective value, fundamental frequency, phase place, the harmonic component of signal.Utilize result of calculation can calculate the applied power S in this loop, phase difference, active power P and the reactive power Q of voltage and current.

Product by the effective value of the effective value of voltage and electric current can calculate the applied power S in tested loop; The voltage-phase calculated value deducts the power-factor angle φ that the current phase calculated value obtains this loop; The cosine that applied power S multiply by power-factor angle φ obtains the active power P in loop; The sine that applied power S multiply by power-factor angle φ obtains the reactive power Q in loop.

Like this, the user has just obtained to want the final measurement that obtains at the scene, does not cause line drop in the time of can be because of long Distance Transmission, has guaranteed the high precision of measuring.

Leading indicator of the present invention: the bandwidth that the present invention measures, frequency band is 010kHz, and the accuracy of electric current and voltage is owing to 0.2 grade, and the power measurement accuracy is better than 1.0 grades, satisfies the requirement to power test of existing electric-power metering and electromechanical testing national standard.

Embodiment two, the difference of present embodiment and embodiment one is, it also comprises optical-fibre communications sending module OTS10, optical-fibre communications receiver module OTR11 and optical communication interface circuit 12, the output terminal of digital signal processing and computing module DSP9 links to each other by the input end of BUS bus with optical-fibre communications sending module OTS10, light signal is of coupled connections between the input end of the output terminal of optical-fibre communications sending module OTS10 and optical-fibre communications receiver module OTR11, the output terminal of optical-fibre communications receiver module OTR11 links to each other with optical communication interface circuit 12 by the BUS bus, and other is identical with embodiment one.

Embodiment one obtains the series of computation data in digital signal processing and computing module DSP9, these data are net results that the user will use, these data send the user to by optical-fibre communications, the BUS bus adopts the RS485 bus, optical communication interface circuit 12 adopts the RS485 interface circuit, or the BUS bus adopts the CAN bus, optical communication interface circuit 12 employing CAN interface circuits.The optical communication interface circuit 12 that is BUS bus and user side is consistent.

Calculating good high-precision data like this, at the scene can not reduce the precision of measurement for user side through Optical Fiber Transmission.And the means of present embodiment transmission are to adopt optical-fibre communications, and a little less than the interference that is subjected to, whole range accuracy of detection unanimity, antijamming capability are strong, have realized the digitizing communication function.

Claims

1. adopt the power-measuring device of linear optical coupling realization based on resistance sampling, it is characterized in that, it comprises shunt (1), voltage divider (2), current operator amplifies and linear optical coupling isolation module (3), voltage operational amplify and linear optical coupling isolation module (4), current polarity decision circuitry (5), polarity of voltage decision circuitry (6), electric current A/D change-over circuit (7), voltage A/D change-over circuit (8) and digital signal processing and computing module DSP (9)

The sampling resistor Ri two ends extension line of shunt (1) is the voltage signal output end of shunt (1), the voltage signal output end of described shunt (1) links to each other with the input end of linear optical coupling isolation module (3) with the current operator amplification, the current operator amplification links to each other with the input end of electric current A/D change-over circuit (7) with the output terminal of linear optical coupling isolation module (3), the output terminal of electric current A/D change-over circuit (7) links to each other with the current sample input end of digital signal processing with computing module DSP (9), the current operator amplification links to each other with the input end of current polarity decision circuitry (5) with the current polarity signal output terminal of linear optical coupling isolation module (3), the output terminal of current polarity decision circuitry (5) links to each other with the current polarity control end of digital signal processing with computing module DSP (9)

The divider resistance Rv two ends extension line of voltage divider (2) is the voltage signal output end of voltage divider (2), the voltage signal output end of described voltage divider (2) links to each other with the input end of linear optical coupling isolation module (4) with the voltage operational amplification, the voltage operational amplification links to each other with the input end of voltage A/D change-over circuit (8) with the output terminal of linear optical coupling isolation module (4), the output terminal of voltage A/D change-over circuit (8) links to each other with the voltage sample input end of digital signal processing with computing module DSP (9), the voltage operational amplification links to each other with the input end of polarity of voltage decision circuitry (6) with the polarity of voltage signal output part of linear optical coupling isolation module (4), the output terminal of polarity of voltage decision circuitry (6) links to each other with the polarity of voltage control end of digital signal processing with computing module DSP (9)

The synchronized sampling control end of digital signal processing and computing module DSP (9) links to each other with the current sample control end of electric current A/D change-over circuit (7) and the voltage sample control end of voltage A/D change-over circuit (8) simultaneously.

2. employing linear optical coupling according to claim 1 is realized the power-measuring device based on resistance sampling, it is characterized in that, it also comprises optical-fibre communications sending module OTS (10), optical-fibre communications receiver module OTR (11) and optical communication interface circuit (12), the output terminal of digital signal processing and computing module DSP (9) links to each other by the input end of BUS bus with optical-fibre communications sending module OTS (10), light signal is of coupled connections between the input end of the output terminal of optical-fibre communications sending module OTS (10) and optical-fibre communications receiver module OTR (11), and the output terminal of optical-fibre communications receiver module OTR (11) links to each other with optical communication interface circuit (12) by the BUS bus.

3. employing linear optical coupling according to claim 2 is realized the power-measuring device based on resistance sampling, it is characterized in that, the BUS bus adopts the RS485 bus, and optical communication interface circuit (12) adopts the RS485 interface circuit.

4. employing linear optical coupling according to claim 2 is realized the power-measuring device based on resistance sampling, it is characterized in that, the BUS bus adopts the CAN bus, and optical communication interface circuit (12) adopts the CAN interface circuit.