TW201300788A - Power measurement apparatus - Google Patents

Abstract

An AD converter 15 conducts a sampling of a voltage signal and a current signal at an AD sampling timing set by a switch controlling part 19 and executes an AD conversion. At the time of dividing an AD sampling cycle m into n, for example, m=1/4 powerline cycle and n=3 is set. During the period A, an AD conversion is conducted in the first timing of three AD sampling timings. During the period B, an AD conversion is conducted in the second timing of three AD sampling timings. Furthermore, during the period C, an AD conversion is conducted in the third timing of three AD sampling timings. The power can be detected by individually moving each one of three AD sampling timings, in an accuracy as high as that detected in the case that the sampling executed at 3 times of AD sampling frequency.

Description

Power measuring device

The present invention relates to an electric power measuring apparatus that performs sampling on voltage and current signals and performs AD conversion to measure electric power.

Since the past, it has been known to use an AD (Analog Digital) converter that converts an analog signal into a digital signal, samples the input voltage waveform and the input current waveform, and measures the effective power by multiplying the sampling results. Then, the present type of electric power meter is sampled (for example, refer to Patent Document 1).

A conventional sputum sampling type electric power meter will be described with reference to FIG. Fig. 13 is a block diagram showing the internal structure of a conventional sputum sampling type electric power meter. In the 撷 sampling power meter 110, the analog voltage signal e input to the input terminal T1 is converted into a digital signal via the AD converter 131. Further, the analog current signal i input to the input terminal T2 is converted into a digital signal via the AD converter 132.

The two AD converters 131 and 132 are used as a common timing signal by the signal output from the clock generator 113, and the analog voltage signal e and the analog current signal i are respectively synchronized with the timing of the generation of the timing signal. Sampling is performed and converted to a digital signal separately.

Next, the voltage signals e(t) and current signals i(t) of the sample values at the same time are output from the two AD converters 131 and 132. Further, the voltage signal e(t) and the current signal i(t) are values at discrete time t.

In this way, whenever the timing signal is generated, the combination of the sample values at time t=t1, t2, ... (e(t1), i(t1)), (e(t2), i(t2)) It is output to the calculator 111 via the two AD converters 131 and 132.

The calculator 111 calculates the instantaneous power W(t) at the time t by multiplying the voltage value and the current value based on the input digital value (e(t), i(t)). Further, the calculator 111 calculates an effective power (average power) by performing an averaging calculation that averages a plurality of instantaneous powers. Further, the calculator 111 is constituted by, for example, a DSP (Digital Signal Processor) or a CPU (Central Processing Unit). The calculated effective power is displayed via display 112.

Patent Document 1 (Japanese Patent Publication No. 04-109173)

However, the conventional electric power measuring device described above has problems as follows. In the calculation of electric power, in the case of a signal mixed with a high frequency value such as a high-modulation wave, there is a need to shorten the period of the timing signal with the frequency value component thereof. Therefore, in the calculation of electric power, the number of sampling frequencies becomes high, so that it becomes necessary to increase the number of samples.

In order to perform high-speed sampling like this, it is necessary to use a high-performance AD converter and a CPU (microcomputer), so that the manufacturing cost of the power measuring device is increased. That is, in the case of a low-cost power measuring device, it is difficult to measure high-frequency power with high precision.

The present invention has been made in view of the above-described conventional matters, and provides an electric power measuring device capable of performing AD conversion of a signal having a high frequency value without increasing the number of samples and capable of measuring electric power with high precision.

An electric power measuring device according to an embodiment of the present invention is an electric power measuring device that measures electric power supplied from a power source to a load, and includes: sampling a signal of a voltage and a current supplied with a load of the electric power, and performing AD conversion AD conversion means, and will be via the aforementioned AD conversion means The calculation method of calculating the electric power by multiplying the values of the voltage and the current obtained by the AD conversion, and the switching means for dividing the sampling period m of the AD conversion means into n equal parts and setting the sampling interval at the m/n interval At the time point, the period in which the sampling is performed at the first time point is the first period, the period in which the sampling is performed at the nth time point is the nth period, and the first period to the nth are switched for each specified time width. During the period of time, the AD conversion means performs sampling at a timing during which the switching is performed by the switching means.

Further, the period in which the calculation means samples the voltage and current for power calculation is preferably at least a period of n times the specified time width.

Moreover, the aforementioned specified time range is preferably an integer multiple of the power cycle.

Further, it is preferable that the switching means switches the order from the first period to the nth period to the next time after the first period to the nth period are switched in a predetermined order.

Further, it is preferable that the switching means change the switching order of the first period to the nth period in accordance with the sequence.

Further, it is preferable that the switching means irregularly change the switching order of the first period to the nth period.

Further, the aforementioned n is preferably 2.

Further, the aforementioned specified time width is preferably a half-wave period of each of the aforementioned voltage and current signals.

Further, it is preferable that the switching means switch between the first period and the second period in the reverse order of the order in which the first period and the second period are switched.

Moreover, the aforementioned AD conversion means is preferably in every second time frame The degree of the start of the aforementioned sampling period m is adjusted to be such that the aforementioned signal is a zero-crossing point from a negative transition to a positive transition or a positive transition to a negative zero cross.

Further, when the AD conversion means performs the AD conversion of the voltage and current signals in a time division manner, it is preferable that the switching means replace the order of the AD conversion with the voltage at each third time width. The one of the currents and the current is performed first.

Further, it is preferable that the number of samples of one cycle is fixed to a specified number instead of the number of power supply frequencies.

Further, it is preferable to sample the voltage and current signals of a plurality of loads supplied from at least one power source in a time-division manner, and to obtain the electric power supplied to the plurality of loads, respectively.

Further, when the plurality of loads are switched for each of the predetermined time ranges to sample the respective signals of the voltage and the current, it is preferable that the switching means changes the first period to the nth for each of the loads. The order of switching between periods.

Further, the switching means preferably changes the switching order of the first period to the nth period of each of the loads in accordance with the sequence.

Further, it is preferable that the switching means irregularly change the switching order of the first period to the nth period of each of the loads.

According to an embodiment of the present invention, the sampling period m is divided into n equal parts, and the nth period from the first period to the nth time point of the first time point is switched for each specified time width. The AD conversion of the signal of the high frequency value is performed by increasing the number of samples, and the power can be measured with high precision.

The objects and features of the present invention will become more apparent from the description of the appended claims appended claims.

[Formation for implementing the invention]

Embodiments of the power measuring device according to the present invention will be described with reference to the drawings. In the entire drawings, the same or similar components are denoted by the same reference numerals, and the description thereof is omitted. The electric power measuring device according to the present embodiment can be applied to a sputum sampling type electric power meter or a multi-circuit electric power meter.

(First embodiment)

Fig. 1 is a view showing the internal configuration of the electric power measuring device 1 according to the first embodiment. The power measuring device 1 includes a voltage detecting unit 11, a current detecting unit 12, a signal switching unit 13, a signal amplifier 14, an AD converter 15, a power calculating unit 16, a display 17, and timing generation as shown in FIG. The configuration of the controller 18 and the switching control unit 19.

The voltage detecting unit 11 detects the voltage supplied from the system power source 21 to the load 24.

The current detecting unit 12 detects the current supplied from the system power source 21 to the load 24.

The signal switching unit 13 switches the detection target to the voltage detecting unit 11 or the current detecting unit 12.

The signal amplifier 14 amplifies the signal of the voltage or current input through the signal switching unit 13.

The timing generator 18 generates a timing signal serving as a reference when the AD converter 15 performs AD conversion.

The AD converter 15 takes a signal amplified by the signal amplifier 14 at a timing synchronized with the timing signal output from the timing generator 18. And converting the value of the sampled signal into a digital value.

The switching control unit 19 is configured to output a switching signal of the voltage detecting unit 11 and the current detecting unit 12 to be detected to the signal switching unit 13, and to set the time at which the AD converter 15 performs sampling (AD sampling). The signal at the time point is output.

Further, the switching control unit 19 has a configuration including a variable setting unit 19a and a sequence setting unit 19b.

The variable sampling unit 19a sets the AD sampling period m, the number of divisions n, the time width W, and the time width Y.

The order setting unit 19b sets the order of the periods set by the different AD sampling points as will be described later.

The power calculation unit 16 calculates the instantaneous power value by multiplying the digital value of the current signal AD-converted by the AD converter 15 and the digital value of the voltage signal, and calculates the instantaneous power in the specified period. The values are accumulated and averaged to calculate the effective power value.

The display 17 displays the effective power value and the like output by the power calculation unit 16.

In the present embodiment, the power calculation unit 16 and the switching control unit 19 can be configured by a relatively inexpensive general-purpose microcomputer. The above-described respective values (AD sampling period m, number of divisions n, time width W, and time width Y) are set in the variable setting unit 19a through the input interface in the microcomputer.

Fig. 2 is a timing chart showing the point of AD sampling corresponding to the signal waveform. The AD sampling timing at which the AD converter 15 performs AD conversion is set via the switching control unit 19 as described above. Therefore, the AD sampling period m can be divided into n equal parts, and can be set at the time of the m/n interval for AD sampling, one of which is to set m = 1/4 of the power supply period. The case of n=3.

Further, the time width (designated period) W is set to an integer k times the sampling period m. By setting the time width W to an integer k times (W = m × k) of the sampling period m, sampling of the high-modulation component becomes easy.

Further, the period Tc during which the voltage and current for integrating (calculating) the electric power value are sampled is at least the time width W when the AD sampling period m is divided into n equal parts. Period of multiple (Tc=W×n). Further, since the power value integration period Tt is a period in which the voltage and the current are individually sampled, it is twice the period Tc (Tt = Tc × 2).

In the period A (first period) of the time width W, the AD conversion is performed at the first time point of the first order among the three AD sampling time points. In the period B (second period) of the time width W, the AD conversion is performed at the second time point among the three AD sampling time points. Further, in the period C (nth period) of the time width W, the AD conversion is performed at the third time point of the third order (nth order) among the three AD sampling time points. Thereby, the order of the AD sampling time points is repeatedly set in the order of the first time point, the second time point, and the third time point via the order setting unit 19b.

By moving the three AD sampling time points one by one, it is possible to detect electric power with the same high precision as in the case of sampling with three times the AD sampling frequency value.

Here, the start point of the AD sampling period m is periodically adjusted using the signal of the detection target. Fig. 3 is a timing chart showing the change of the zero cross-cut pulse signal for adjusting the start point of the AD sampling period m. The sampling start point of the AD conversion is adjusted to, for example, a zero cross-cut point where the voltage signal changes from negative to positive, or from positive to negative, and cross-cut to zero, and zero crossing of the H-level/L level change The starting point of the pulse signal.

Figure 3(a) shows a zero cross-cut pulse signal. Figure 3(b) shows the detected object signal. The AD converter 15 adjusts the start point of the AD sampling period m at the start point of the zero cross-cut pulse signal for each time amplitude Y (the second time amplitude), and AD sampling from the adjusted starting point. The signal is sampled at the time. In this manner, since the AD sampling timing is periodically synchronized with the signal of the detection target, the AD sampling timing can be adjusted with high precision.

Further, as described above, the switching between the periods (the periods A, B, C, ... X) (the first period to the nth period) for each predetermined period W, that is, the switching of the different AD sampling points is It is performed in advance in the order set by the sequence setting unit 19b.

Further, for example, the random number generator may be provided in the sequence setting unit 19b, and the point of the AD sampling may be switched using the irregular value (random value) generated by the random number generator. Thereby, it is possible to prevent the intermittent sampling of the intermittent signal as seen at the load current from being synchronized, and it is possible to perform the power measurement irrespective of the intermittent signal.

4 is a timing chart showing the point at the time of AD sampling in the case where the specified period W is a half-wave period (1/2 of the power supply period). Here, the AD sampling period m is 1/4 of the power supply period, and the value of the division number n is 3.

During the half-wave period on the positive side, two points of the first time point of the period A are sampled (sampling twice). During the half-wave period on the negative side, two points of the second time point of the period B are sampled (sampling twice). During the half-wave period on the next positive side, two points of the third time point of the period C are sampled (sampling twice). During the half-wave period of the next negative side, two points of the first time point of the period A are sampled (sampling twice).

FIGS. 5(a) and 5(b) are explanatory diagrams for explaining the point of AD sampling in the case where the specified period W is a half-wave period. Fig. 5(a) is an explanatory view showing a case of 16-point sampling/cycle, and Fig. 5(b) is an explanatory view showing a case of 8-point sampling/cycle.

Here, the AD sampling period m is 1/8 of the power supply period, and the value of the number of divisions n Is 2. The signal waveforms of the power supplies on the plus side and the minus side are considered to be the same. In this case, as shown in FIG. 5(b), sampling of odd sampling points in the 16-point sampling of FIG. 5(a) is performed on the positive side, and FIG. 5(a) is performed on the negative side. Sampling of even sample points.

The value sampled at time 10 in Fig. 5(b) and the value sampled at time 2 in Fig. 5(a) are indicated by the same value with only the opposite sign. Similarly, the value sampled at the time point 12 in Fig. 5(b) and the value sampled at the time point 4 in Fig. 5(a) are indicated by the same value with only the opposite signs.

That is, when the signal waveform of the power supply is the same on the plus side and the minus side, since two sample values at individual time points can be obtained, even if the sample is sampled at 8 points/cycle, the image can be obtained. The effect of sampling at 16 points sampling/cycle.

In Fig. 5(a) and Fig. 5(b), although the area of the rectangle formed by using the sampling point as one of the vertices is an amount proportional to the electric power, even if it is an 8-point sampling/period It is also possible to obtain the same area as the 16-point sampling/cycle. Therefore, power can be detected with high precision in the same manner. Moreover, when the specified period W is a half-wave period, power calculation becomes easy. Furthermore, since the value of the number of divisions n is 2, sampling can be completed in one cycle.

6(a) to 6(c) are explanatory diagrams for explaining an effect of a case where sampling is performed at the time of AD sampling when the predetermined period W is a half-wave period. Fig. 6(a) shows, for example, a case where the load current waveform is an intermittent signal in which a signal is present during one wavelength period and that a change such as a signal does not exist in the next one wavelength period.

For such an intermittent signal, it is shown in FIG. 6(b) that the period A at which sampling is performed at the first time and the period B at which sampling is performed at the second time are every one. Switching during the wavelength period. In this case, since the signal waveform is sampled only at the first time point of the period A, and is not sampled at the second time point of the period B, the accuracy of the AD conversion is reduced.

It is shown in Fig. 6(c) that both the period A and the period B are in the case of switching every half wave. In this case, the signal waveform on the positive side is sampled at the first time point of the period A, and the signal waveform on the negative side is sampled at the second time point of the period B.

In the AC waveform, most of the load current waveforms are the same on the positive side and the negative side. Therefore, with respect to the load current waveform as described above, since the sampling is performed at two points of the periods A and B in the one waveform, the accuracy of the AD conversion can be improved, and thus the power can be detected with high precision.

Next, the switching control unit 19 outputs a signal in which the order of the period A and the period B is switched to the signal switching unit 13 every one wavelength period in the order set by the order setting unit 19b. Fig. 7 is a timing chart showing the point of AD sampling in the case where the order of the period A and the period B is switched every 1 wavelength. Here, the AD sampling period m is 1/8 of the power supply period, the specified period W is a half-wave period (1/2 of the power supply period), and the value of the division number n is 2.

For the signal waveform on the positive side (period A), sampling of odd points in the 16-point sampling of Fig. 5(a) is performed. For the signal waveform on the negative side (period B), sampling of even points in the 16-point sampling of Fig. 5(a) is performed. Also, during every 1 wavelength period, period A and period B are interactively switched.

That is, the signal waveform on the positive side of the first order is sampled at the first time points 1, 3, 5, and 7 of the period A. For the signal waveform on the negative side of the second order, samples are taken at the second time points 10, 12, 14, and 16 of the period B. For the first The signal waveform on the positive side of the 3-bit is sampled at time points 2, 4, 6, and 8 of period B. For the signal waveform on the negative side of the fourth order, samples are taken at the first time points 9, 11, 13, and 15 of the period A. In this manner, during the half-wave period, the period A and the period B are alternately switched, and 16-point sampling is performed in two periods.

8(a) to 8(c) are explanatory views for explaining the effect of the case where the AD sampling time is performed in the case where the order of the period A and the period B is switched every one wavelength period. Fig. 8(a) shows such a signal waveform that is asymmetrical on both the positive side and the negative side as seen in the load current waveform.

In the case of such an asymmetrical signal waveform, in FIG. 8(b), the period A in which the sampling is performed at the first time point and the period B in which the sampling is performed at the second time point are alternately switched every half-wavelength period. In this case, the signal waveform on the positive side is sampled only at the first time point of the period A, and the signal waveform on the negative side is sampled only at the second time point of the period B. Thus, the accuracy of the AD conversion is reduced.

In FIG. 8(c), the order of the switching period A and the period B per one wavelength is alternately switched. In the same manner, the signal waveform on the positive side is repeatedly subjected to sampling in the first half-wavelength period and the first time in the period A, and in the third-order half-wavelength period and the second-period in the period B. sampling.

Further, similarly, the signal waveform on the negative side is repeatedly sampled at the second half of the second-order wavelength period and the period B, and sampled at the first time point of the wavelength range of the fourth order and the period A.

Therefore, for the positive and negative asymmetric signal waveforms, since the sampling is performed at the two AD sampling points of the respective periods A and B on the positive side and the negative side, the accuracy of the AD conversion becomes high, and thus the power can be detected with high precision. .

In this way, even with respect to the signal waveforms in which the positive and negative are asymmetric, since the order of the period A and the period B is alternately switched between the previous time and the next time, As long as the same waveform is two or more consecutive times, the accuracy of the AD conversion can be improved.

According to the power measuring device 1 of the first embodiment, the sampling of the first waveform is performed by shifting the sampling point of the AD sampling, and the high-modulation wave component can be detected even with a small number of samples, so that the accuracy of the AD conversion can be improved. In other words, the AD conversion of the signal of the high frequency value can be performed without increasing the number of samples, so that the power can be measured with high precision.

Therefore, even if the sampling frequency value is not increased, the same power calculation as in the case of n times the number of sampling frequencies can be performed. In addition, it becomes a microcomputer that does not require high computing power, and can be calculated by a general-purpose microcomputer, and thus the cost is reduced.

In the first embodiment, sampling has been described for either voltage and current, but actually voltage and current are alternately sampled to perform power calculation. This point will be described in the second embodiment below.

(Second embodiment)

In the first embodiment, the case where voltage detection or current detection is performed for one system power supply is shown. In the second embodiment, a plurality of loads (electrical circuits) that supply electric power from at least one system power supply are present, and electric power measurement is performed by switching electrical circuits at time intervals.

Fig. 9 is a block diagram showing the internal configuration of the electric power measuring device 1a in the second embodiment. The same components as those in the first embodiment are denoted by the same reference numerals, and their description will be omitted. Here, a configuration and an operation different from those of the first embodiment will be described.

The electric power measuring device 1a of the second embodiment detects individual voltages and currents for a plurality of electric circuits (also simply referred to as "circuits"). electric power.

Therefore, the power measuring device 1a is provided with a voltage detecting unit 11a and a current detecting unit 12a that detect the voltage and current of the first circuit. Further, a voltage detecting unit 11b and a current detecting unit 12b that detect the voltage and current of the second circuit are provided. Similarly, a voltage detecting unit 11c and a current detecting unit 12c that detect the voltage and current of the third circuit are also provided. Here, the example is the same as the third loop, but the same applies to the fourth and subsequent loops.

The signal switching unit 33 switches the signal to be detected to detect the voltage and current of each loop.

The switching control unit 39 outputs a switching signal for switching the detection target to the signal switching unit 33, and outputs a signal for setting the point of AD sampling to the AD converter 15. Further, the switching control unit 39 has a configuration including a variable setting unit 39a and a sequence setting unit 39b.

The variable setting unit 39a sets the time width Z (the third time width) in addition to the AD sampling period m, the number of divisions n, the time width W, and the time width Y, as in the first embodiment.

The sequence setting unit 39b sets the switching sequence of the period (period A, period B, period C, ... period X) set by the AD sampling point and the switching order of the plurality of loops.

This switching sequence can be arbitrarily set. The number of examples that can be switched can be obtained by calculating the number n of signals using a plurality of loops to be switched and the sequence nPr of the number of periods (the number of divisions n) at which the AD sampling point is set. Alternatively, the switching sequence can be set to an irregular value generated by the random number generator.

Further, similarly to the first embodiment, the switching control unit 39 and the electric power are switched. The calculation unit 16 may be constituted by a general-purpose microcomputer. The variable setting unit 39a sets the time width Z (the third time width) in addition to the above values (the AD sampling period m, the number of divisions n, the time width W, and the time width Y) through the input interface in the microcomputer. ). The order setting unit 39b sets the order in which the programs stored in the ROM are executed by the CPU of the general microcomputer.

Fig. 10 is a timing chart showing the point of AD sampling in the case where the order of AD conversion is replaced with the case where the voltage and current are performed first. The switching control unit 39 replaces the order of AD conversion at each time width Z with one of the voltage waveform and the current waveform. This time amplitude Z is set to be an integer j times the time width W.

Specifically, in the first time width Z, the AD waveform of the voltage waveform is first performed at the first time point of the period A, and then the AD waveform of the current waveform is performed at the second time point of the period B, and is repeatedly performed.

When this time amplitude Z is passed, the switching order of the AD conversion is replaced with the current waveform first. That is, in the next time width Z, the AD waveform of the current waveform is first performed at the first time point of the period A, and then the AD conversion of the voltage waveform is performed first at the second time point of the period B, and the switching is repeated.

In this way, by replacing the switching order in which the AD conversion is performed first among the voltage and the current, the following effects can be obtained. Since the AD conversion of the current and voltage to be the product of the product is performed in order of time division, a time difference of several μsec (see Δt in the figure) of the time difference of the AD conversion time is generated. However, by periodically replacing the switching order of the AD conversion with the one that is performed first, the time difference of the number of μsec can be canceled in the calculation, and the measurement accuracy of the power can be improved.

Further, as described above, the switching sequence like this is set in sequence Alternatively, it is set to an irregular value, so that sampling in synchronization with the intermittent signal can be prevented, and power calculation can be performed independently of the intermittent signal.

Further, the switching order of the AD conversion is replaced with the one of the voltage and the current, and the same can be applied to the first embodiment.

The following shows the case where the switching control section 39 changes the AD sampling time point in each loop, and changes the combination of the loop and the AD sampling time point every time width W. Furthermore, the AD conversion performed in each circuit is changed as described above: the switching order of the AD waveform conversion of the voltage waveform and the current waveform. That is, as described above, the time width W is an integer k times the sampling period m, and the period Tc of any one of the voltage and current for integrating (calculating) the sampled power value is divided into n in the AD sampling period m. In the case of equal division, it is a period of n times the time width W, and the power value integration period Tt is twice the period Tc. Here, when the time width Z is used, since the voltage and the current are alternately switched for each time width Z due to the period of the power integration period Tt, the power value can be relatively accurately measured.

Fig. 11 is an explanatory view showing the point of AD sampling for each loop. The switching control unit 39 switches the circuit for performing AD conversion for each time width W in the order set by the sequence setting unit 39b. Display: Switching loop 1, loop 2, loop 3 of 3 loops.

In the loop 1, the AD conversion is performed in the order of the first time point of the period A and the second time point of the period B. In the loop 2, AD conversion is performed in the order of the second time point of the period B and the third time point of the period C. In the loop 3, AD conversion is performed in the order of the third time point of the period C and the first time point of the period A.

Specifically, it is shown that three ADs of the first time point of each circuit switching period A, the second time point of the period B, and the third time point of the period C are changed. The order of the points at the time of sampling.

Figure 12 is a graph showing the combination of changing the order of the points at which the AD sampling is switched at each loop.

In the first time width X, in the time range W, the circuit A is switched in the period A, the circuit 2 is switched in the period B, the circuit 3 is switched in the period C, and the circuit 1 is switched in the period B during the period C. The loop 2 switches the loop 3 during the period A, and finally switches the loop 1 during the period C, switches the loop 2 during the period A, and switches the loop 3 during the period B.

In the second time width X, in the time width W, the switching circuit 1 in the period A, the switching circuit 2 in the period C, and the switching circuit 3 in the period B, and then switching the circuit 1 and switching in the period B during the period C. The circuit 2 switches the circuit 3 during the period A, and finally switches the circuit 1 during the period B, and switches the circuit 2 during the period A, and switches the circuit 3 during the period C.

In the third time width X, in the time interval W, the circuit B is switched in the period B, the circuit 2 is switched in the period A, the circuit 3 is switched in the period C, and then the circuit 1 is switched in the period A and switched in the period C. The circuit 2 switches the circuit 3 during the period B, and finally switches the circuit 1 during the period C, and switches the circuit 2 during the period B, and switches the circuit 3 during the period A.

In this way, even if the switching sequence is changed during each circuit change period, the same effect can be obtained by delaying the AD sampling time point.

Further, even in the switching sequence of the period of each loop, the order setting unit 39b may set the order in accordance with the sequence or the value of the irregularity. Thereby, it is possible to prevent sampling in synchronization with an intermittent signal such as a load current, and it is possible to perform measurement irrespective of intermittent current.

According to the electric power measurement device 1a of the second embodiment, even when a plurality of circuits measure electric power, the image can be high-tuned with good precision. A signal waveform of a high frequency value such as a wave is subjected to AD conversion.

In addition, the present invention is of course not limited to the configuration of the above-described embodiment, and any configuration may be adopted as long as it has a function capable of achieving the function shown in the patent application range or a function capable of achieving the configuration of the embodiment. Can be applied.

For example, the number of samples of one cycle may be fixed to the specified number, for example, fixed to 8-point sampling and 16-point sampling; in this case, even if the power frequency value is changed to 50 Hz, 55 Hz, 60 Hz, etc. An algorithm for calculating the power needs to be changed, and thus can be easily realized.

Further, in the above-described embodiment, the AD conversion is performed by sampling the signals of the voltage and the current in a time-division manner by one AD converter. However, the two AD converters may be separately sampled and AD-converted. By multiplying the voltage value and the current value sampled at the same time, the time difference can be made non-existent (i.e., there is no time difference).

All of the above embodiments, the illustrative examples and the modifications of the embodiments can be combined with each other. The preferred embodiments of the present invention have been described above, but the present invention is not limited to the specific embodiments, and various modifications and changes may be made without departing from the scope of the claims. Within the scope of the invention.

1‧‧‧Power measuring device

11‧‧‧Voltage Detection Department

11a‧‧‧Voltage Detection Department

11b‧‧‧Voltage Detection Department

11c‧‧‧Voltage Detection Department

110‧‧‧撷Sampling this type of electricity meter

111‧‧‧Calculator

112‧‧‧ display

113‧‧‧ Timing generator

12‧‧‧ Current Detection Department

12a‧‧‧ Current Detection Department

12b‧‧‧ Current Detection Department

12c‧‧‧ Current Detection Department

13‧‧‧Signal Switching Department

131‧‧‧AD converter

132‧‧‧AD converter

14‧‧‧Signal Amplifier

15‧‧‧AD converter

16‧‧‧Power Computing Department

17‧‧‧Monitor

18‧‧‧ Timing generator

19‧‧‧Switch Control Department

19a‧‧‧Variable Setting Department

19b‧‧‧ Order setting department

1a‧‧‧Power measuring device

1b‧‧‧Power measuring device

1c‧‧‧Power measuring device

21‧‧‧System Power

24‧‧‧load

33‧‧‧Signal Switching Department

39‧‧‧Switch Control Department

39a‧‧‧Variable Setting Department

39b‧‧‧Sequence setting department

m‧‧‧AD sampling period

n‧‧‧Division

Tc‧‧‧Sampling period

Tt‧‧‧Power value calculation period

W‧‧‧ time range

Y‧‧‧ time range

Fig. 1 is a block diagram showing the internal configuration of an electric power measuring device according to a first embodiment.

Fig. 2 is a timing chart showing the timing of AD sampling for a signal waveform.

3 is a timing chart showing changes in the zero cross-cut pulse signal for adjusting the start point of the AD sampling period m; (a) a zero cross-cut pulse signal, and (b) a signal to be detected.

4 is a timing chart showing the point of AD sampling in the case where the specified period W is a half-wave period (1/2 of the power supply period).

FIG. 5 is an explanatory diagram for explaining the point of AD sampling in the case where the specified period W is a half-wave period; (a) is an explanatory diagram of a case of 16-point sampling/cycle, and (b) is an 8-point sampling/cycle. Description of the figure.

6(a) to 6(c) are explanatory diagrams for explaining the effect of sampling at the time of AD sampling in the case where the specified period W is a half-wave period; FIG. 6(a) is a repetition of the image 1 wavelength. The period signal exists, and the intermittent signal in which the signal does not change during the next one wavelength period, the period A in which the sample is sampled at the first time point, and the period B in which the sample is sampled at the second time point are in each An example of replacement in one wavelength period, and (c) in FIG. 6 are examples in which each of the period A and the period B is replaced by each half wave.

Fig. 7 is a timing chart showing the point of AD sampling in the case where the order of the period A and the period B is switched every 1 wavelength.

8(a) to 8(c) are explanatory views for explaining the effect of the case of the AD sampling time when the order of the period A and the period B is switched every one wavelength period; FIG. 8(a) is on the positive side. Both the negative side and the negative side are asymmetric signal waveforms, and FIG. 8(b) shows an example in which the period A for sampling at the first time point and the period B for sampling at the second time point are alternately replaced during each half wavelength period, FIG. 8 (FIG. 8) c) The order of A and period B during the switching of each wavelength is an alternative example.

Fig. 9 is a block diagram showing the internal structure of the electric power measuring device according to the second embodiment.

Fig. 10 is a timing chart showing the point of AD sampling in the case where the switching order of AD conversion of voltage and current is changed.

Fig. 11 is an explanatory view showing the point of AD sampling for each loop.

Figure 12 is a diagram showing the sequence of points when switching AD sampling at each loop change. A combination of charts.

Fig. 13 is a block diagram showing the internal structure of a conventional sputum sampling type electric power meter.

1‧‧‧Power measuring device

11‧‧‧Voltage Detection Department

12‧‧‧ Current Detection Department

13‧‧‧Signal Switching Department

14‧‧‧Signal Amplifier

15‧‧‧AD converter

16‧‧‧Power Computing Department

17‧‧‧Monitor

18‧‧‧ Timing generator

19‧‧‧Switch Control Department

19a‧‧‧Variable Setting Department

19b‧‧‧ Order setting department

21‧‧‧System Power

24‧‧‧load

Claims (16)

An electric power measuring device for measuring electric power supplied from a power source to a load, and comprising: an AD conversion means for sampling a signal of a voltage and a current supplied with a load of the electric power, and performing AD conversion, The calculation means for calculating the electric power and the switching means by multiplying the values of the voltage and the current by the AD conversion means by the AD conversion means, and dividing the sampling period m of the AD conversion means into n equal parts, and setting it at m/n When sampling is performed at intervals, the period in which the sampling is performed at the first time is referred to as the first period, and the period in which the sampling is performed at the nth time is referred to as the nth period, and the first period is switched for each specified time width. The period to the nth period; and the AD conversion means performs sampling at a timing during which the switching is performed by the switching means. The power measuring device according to claim 1, wherein the period in which the calculating means samples the voltage and the current for calculating the power supply force is at least a period of n times the specified time width. The power measuring device of claim 2, wherein the aforementioned specified time range is an integral multiple of a power cycle. The power measuring device according to any one of claims 1 to 3, wherein, after switching the first period to the nth period in a predetermined order, the switching means switches the first period to the next time The sequence of n periods is switched to a different order from the previous one. The power measuring device according to claim 4, wherein the switching means changes the switching order of the first period to the nth period in accordance with a sequence. The power measuring device of claim 4, wherein the foregoing switching means The switching order of the first period to the nth period is irregularly changed. The power measuring device of claim 1, wherein the aforementioned n is 2. The power measuring device of claim 1, wherein the aforementioned specified time range is a half-wave period of each of the aforementioned voltage and current signals. The power measuring device according to claim 7, wherein the switching means switches the next first period and the second period in a reverse order from the first period and the second period. The power measuring device according to any one of claims 1 to 3, wherein the AD conversion means adjusts a start time point of the sampling period m for each second time width to: the signal is changed from negative to positive, Or change from positive to negative zero cross. The power measuring device according to any one of claims 1 to 3, wherein, in the case where the AD conversion means performs the AD conversion of the voltage and current signals in a time division manner, the switching means is for each third time The amplitude is replaced by the order of AD conversion: the one of the aforementioned voltage and current is performed first. The power measuring device according to one of claims 1 to 3, which is not based on the number of power supply frequencies, but fixes the number of samples of one cycle to a specified number. The power measuring device according to any one of claims 1 to 3, wherein the signals of the voltages and currents of the plurality of loads supplied by the at least one power source are sampled and time-divided, and are respectively supplied to the power measuring device. The aforementioned plurality of loads of power. The power measuring device of claim 13, wherein the switching means is for each of the foregoing negatives when the plurality of loads are switched for each of the specified time ranges and the signals of the voltage and current are sampled. The switching sequence of the first period to the nth period is changed. The power measuring device according to claim 14, wherein the switching means changes the switching order of the first period to the nth period of each of the loads in order. The power measuring device according to claim 14, wherein the switching means irregularly changes a switching order of the first period to the nth period of each of the loads.