JP3411474B2 - Indicating instrument - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an indicating instrument for measuring electric quantities such as current, voltage, electric power, reactive power, power factor and frequency.

[0002]

2. Description of the Related Art FIG. 6 is a block diagram of a measuring circuit portion of a conventional indicating instrument equipped with an electric circuit. In the figure,
1, 2, and 3 are the R phase and S of the electric circuit to be measured.
Phase, T phase. Reference numeral 4 is an instrument transformer (hereinafter, referred to as VT) for stepping down the voltage between the R phase and S phase, and 5 is a VT for stepping down the voltage between the S phase and the T phase. Reference numerals 6 and 7 are current transformers for measuring instruments (hereinafter referred to as CT) that transform currents of R phase and T phase, respectively. Reference numeral 8 is a signal conversion unit for converting the signals corresponding to VT4, 5 and CT6, 7 into a voltage signal proportional thereto. Reference numeral 9 denotes a multiplexer, which selects the output signal of the signal conversion unit 8 according to the control signal of the measurement control unit 12. 10
Is a measurement unit including an A / D conversion unit 11 and a calculation unit, which converts the output signal of the signal conversion unit 8 selected by the multiplexer 9 into a digital signal and measures the amount of electricity by calculation. These measurement values are stored in the measurement value storage unit 13 for each measurement item. Reference numeral 14 is a display device for displaying each measured value, and 15 is a display switching unit for switching the displayed measured value.

[0003]

The conventional indicating instrument is constructed as described above, and signals from VT4 and 5 correspond to voltage values, signals corresponding to CT6 and CT7 correspond to current values and VT.
From the signals corresponding to 4 and 5 and the signals corresponding to CTs 6 and 7, the calculation unit of the measuring unit 10 measures the electric quantity such as the power value, the reactive power value, and the power factor value. Of these, the power value,
The amount of electricity of the reactive power value and the power factor value is calculated by the phase error between the signals corresponding to VT4, 5 and the signals corresponding to CT6, 7,
The accuracy of the measured value is affected. The conventional indicating instrument does not have a phase error correcting function, but has a function such as zero level adjustment for adjusting the installation of the indicating instrument.
In addition, in order to increase the accuracy of the measured amount of electricity, it was necessary to select components that are less likely to cause phase errors.

That is, the conventional countermeasure against the phase error of the indicating instrument is implemented by selecting the parts, and the phase error due to the variation of the parts is not adjusted (corrected). Therefore, in the conventional indicating instrument, if there are variations in the selected components, the amount of electricity is measured by reflecting the phase error due to the variations in the components, and there is a problem that the precision of the amount of electricity measurement is poor. This phase error is V
T4, 5, CT6, 7, signal converter 8, A / D converter 1
1 occurs in the signal conversion unit 8, for example,
The phase error due to the transformer VT, the current transformer CT, and the capacitor, which convert the level to a minute signal level that can be input to the electronic circuit, has a particular influence.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a pointing instrument capable of correcting a phase error caused by variations in parts and capable of accurately measuring an electric quantity.

[0006]

An indicator instrument according to the present invention is mounted on a power receiving panel, a switchboard or the like to measure various amounts of electricity .
A signal converter for converting the first and second voltages into a voltage signal proportional thereto, and constant sampling of the converted signal
A / D conversion is performed at a cycle, and the A / D converted signal
A measuring unit for measuring a power value A of 1 and a second power value B, and
The ratio of the first and second power values A and B measured by the measuring unit
Phase error is calculated based on
However, at the time of measurement, depending on the above time,
Even if you shift the sampling timing of either one,
And a phase error measuring / correcting unit .

Further, a measuring unit and a phase error measuring / correcting unit
Is configured by a microcomputer program
A table having a preset phase-time relationship.
The phase error is time-converted with reference to the rule.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiment 1. 1 is a circuit block diagram showing a first embodiment of the present invention. In the figure, 1, 2, and 3 are R-phase, S-phase, and T-phase of an electric circuit to be measured, 4 is a voltage transformer (hereinafter referred to as VT) for stepping down the voltage between the R-phase and the S-phase, 5 Is a VT that steps down the voltage between the S and T phases, 6 and 7 are the R phase,
Current transformer for measuring current of T-phase (hereinafter referred to as CT)
Is. Reference numeral 8 is a signal conversion unit for converting the signals corresponding to the above VT 4, 5 and CT 6, 7 into a voltage signal proportional thereto, and 9 is a multiplexer, which is an output signal of the signal conversion unit 8 according to the control signal of the measurement control unit 12. Select. 10
Is a measurement unit including an A / D conversion unit 11 and a calculation unit, converts the output signal of the signal conversion unit 8 selected by the multiplexer 9 into a digital signal, and measures the amount of electricity by the calculation unit of the measurement unit 10. . These measurement values are stored in the measurement value storage unit 13 for each measurement item. 14 is a display for displaying each measured value, and 15 is a display switching unit for switching the displayed measured value. 16 is the phase error measurement of the signal corresponding to VT4, 5 and the signal corresponding to CT6, 7.
The correction unit includes an arithmetic processing unit 16a, a memory unit 16b, and a data table 16c.

FIG. 2 is a flowchart of the phase error correction according to the first embodiment. First, in step 101 of the flowchart, a first electric quantity having a power factor of 1,110 V, 500 W at 60 Hz is input to the electric circuits 1, 2, 3 from a power source (not shown). Steps 102 and 103
In A, the signals corresponding to VT 4 and 5 and the signals corresponding to CT 6 and 7 are A / D converted at constant sampling intervals, and the respective A / D converted data are stored in the storage unit 13. A / D measured in steps 102 and 103 in step 104
The first power value A is obtained from the converted data.

At step 105, a power source (not shown) is applied to the electric circuits 1, 2, and 3 to obtain a power factor LEAD of 60 Hz.
(Advance) Input the second amount of electricity of 0.5, 110 V, and 500 W. In steps 106 to 108, the same processing as in steps 102 to 104 is performed and the second power value B
Ask for. In step 109, step 104,
From the power value A and the power value B obtained in step 108, the correction coefficient K =
B / (2 × A) is calculated.

Here, FIG. 4 shows a vector diagram for obtaining electric power by the two-power method. In the three-phase balanced circuit, in the two-power method, the power value can be obtained by the sum of the product of the R-phase / S-phase voltage and the R-phase current and the product of the S-phase / T-phase voltage and the T-phase current. The power value A when the power factor is 1 is as follows. A = V ₁₂ · I ₁ · cos (30 ° + θ ₁ ) + V ₃₂ · I ₃ · cos (−30 ° + θ ₁ ) ... (501) where V ₁₂ is the R-S phase voltage, I ₁ Is R phase current, V
₃₂ is a voltage between T phase and S phase, I ₃ is a T phase current, and θ ₁ is a phase error (angle).

The power value B when the power factor LEAD is 0.5 is as follows. _{B = V 12 · 2I 1 ·} cos (30 ° + theta ₁ +60 _{°) + V 32 · 2I 3 ·} cos (-30 ° + theta ₁ +60 °) (502) where the power value A and the reference value of the formula 501 The difference with 500 W of the error is the power error due to the phase error, but there is a possibility that the values such as V ₁₂ , I ₁ , V ₃₂ , and I ₃ in Expression 501 may include the error, that is, other than the error due to θ ₁ . May include things. Therefore, the correction coefficient K is calculated by the equations 501 and 502.
(= B / (2 × A)), V ₁₂ , I ₁ , V ₃₂ , I ₃
If is made erasable, the equation depends only on θ ₁ and can be adjusted more accurately. Therefore, the phase error can be detected by obtaining the correction coefficient K by the following equation 503. K = B / 2A = [cos (90 ° + θ ₁ ) + cos (30 ° + θ ₁ )] / [cos (30 ° + θ ₁ ) + cos (−30 ° + θ ₁ )] = cos (60 ° + θ ₁ ) / cos θ ≈ cos (60 ° + θ ₁ ) ・ ・ ・ (503) (from cos θ ≈ 1)

The following equation 504 is an equation for converting the phase error angle θ ₁ into time, and when one cycle time of the AC waveform is T, the delay time T _D (μsec) can be expressed as in equation 504, The delay time T _D shown in Expression 505 can be obtained from the correction coefficient K by Expressions 503 and 504. _{T D = (θ 1/360} °) × (1 / T) × 10 -3 ··· (504) (T = 1/60 when 60Hz) _{Accordingly, T D = (16666 / 2π} ) × (cos - ¹ K + π / 3) (505) In step 110, the delay time T _D corresponding to the correction coefficient K is obtained from the memory table 16c (see FIG. 3) of the memory unit 16b of the phase error measurement / correction unit 16, and the step 11
1 determines the delay time T _D , and the phase error measurement / correction unit 1
The delay time T _D is stored in the memory unit 16b of No.6.

The delay time T _D is the time to delay (advance) the start of sampling. If there is no factor that causes a phase error in the circuit, the signals corresponding to VT4 and VT, CT6,
The signal corresponding to 7 may be A / D sampled at the same timing, but if a phase error occurs in the circuit, V
It is necessary to delay the sampling of the signal corresponding to either the signal corresponding to T4, 5 or the signal corresponding to CT6, 7.

The phase correction work is completed as described above, and the flow chart in the operating state is shown below. Step 1
13a sets the timer to the A / D delay time T _D when sampling the signals corresponding to VT4 and 5, and step 113b sets the timer to the delay time T _D when sampling the signals corresponding to CT6 and CT7. Therefore, T _D stored in step 112 is set in any one of the timers 113a and 113b, and 0 is set in the remaining timers. Since the case where the sampling of the signals corresponding to CT6 and CT7 is delayed is described here, VT
The timer set value is set to 0 for A / Ds 4 and 5.

In steps 114a and 114b, sampling is started when each timer elapses, and in steps 115a and 115b, A / D is performed at fixed sampling intervals.
The converted data is stored in the storage unit 13. Step 116
The values of various electric quantities are obtained from the A / D conversion data measured at 115a and 115b. As described above, steps 113 to 116 are continuously repeated in the operating state, and the measurement data is displayed on the display 14 as necessary.

As described above, the correction coefficient K is obtained from the power values under two different conditions, the delay time T _D is obtained based on the correction coefficient K, and the sampling time is delayed by this delay time T _D. It is possible to correct the error due to the variation of the parts by the automatic calculation by the calculation of the microcomputer, and it is possible to measure the electricity quantity with high accuracy without complicating the work. Moreover, since the delay time T _D can be obtained from the table on the memory in correspondence with the correction coefficient K, the delay time T _D can be obtained in a short time.

Embodiment 2. FIG. 5 is a flowchart of the phase error correction of the indicating instrument according to the second embodiment. The circuit configuration is the first embodiment.
Is the same as. In the flowchart of FIG. 5, steps 201 to 209 and 211 to 216 are the same as steps 101 to 109 and 111 to 116 of the first embodiment.

In the second embodiment, as a method for obtaining the delay time T _D in step 210, step 20
Using the power values A and B obtained in Nos. 4 and 208, the delay time T _D is obtained by the equation 505. With this configuration, in addition to the effect of the first embodiment, the data table is not required, requires less memory capacity free.

[0020]

As described above, according to the present invention, since the error due to the variation of the parts can be corrected by the automatic calculation by the calculation of the microcomputer, the work is not complicated and the quantity of electricity can be accurately measured. It becomes possible to measure.

Further, it is possible to determine in response to the correction coefficient a delay time T _D from the memory table, that Do is possible to obtain a short time delay time T _D.

[Brief description of drawings]

FIG. 1 is a circuit block diagram showing an indicating instrument according to a first embodiment of the present invention.

FIG. 2 is a flowchart illustrating the operation of the first embodiment.

FIG. 3 is a diagram showing a data table according to the first embodiment.

FIG. 4 is a vector diagram illustrating an arithmetic expression according to the first embodiment.

FIG. 5 is a flowchart explaining the operation of the indicating instrument according to the second embodiment of the present invention.

FIG. 6 is a circuit block diagram showing a conventional indicating instrument.

[Explanation of symbols]

1 electric circuit R phase, 2 electric circuit S phase, 3 electric circuit T phase, 4, 5 meter transformer, 6, 7 meter current transformer, 8 signal converter, 9 multiplexer, 10 measuring section, 11 A / D conversion unit, 12 measurement control unit, 13 measured value storage unit, 14 display unit, 15 display switching unit, 16
Phase error measurement / correction unit, 16a Arithmetic processing unit, 16b
Memory section, 16c data table.

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-7-325636 (JP, A) JP-A-8-262073 (JP, A) JP-A-61-221677 (JP, A) JP-A-7- 322494 (JP, A) JP-A-9-89949 (JP, A) JP-A-4-363672 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) G01R 21/00-22 / 00 130 G01R 11/00-11/66

Claims (2)

(57) [Claims] 1. An indicator instrument for measuring various amounts of electricity, which is attached to a power receiving panel, a power distribution panel, or the like, for inputting first or second data.
Current and first, the second voltage, and a signal converter for converting a voltage signal proportional to it, the converted signal constant
A / D conversion is performed at the sampling cycle, and this A / D conversion is performed.
The first power value A and the second power value B from the signal
Measuring unit and first and second power values measured by the measuring unit
Phase error is calculated based on the ratio of A and B, and this phase error
Is converted into time, and when measuring, the current and
And / or voltage sampling timing
An indicator instrument comprising a phase error measuring / correcting unit for shifting the ringing. 2. The measuring unit and the phase error measuring / correcting unit are
The program consists of a microcomputer
See the table that has the relationship between phase and time
The phase error is time-converted in accordance with the above.
1 indicator device as claimed.