JPH11337597A - Measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the cost of a measuring system by measuring integrating measured values respectively corresponding to respective ones in a plurality of integrating terms independent of each other. SOLUTION: In this wattmeter 1, by integratedly computing electric power values based on measured data Da-Dc outputted from measuring units 2 by a control part 3, respective integrated power respectively corresponding to respective measuring units 2a-2c and in a plurality of integrating terms independent of each other. Accordingly, only by using a set of the wattmeter 1, integrated power values corresponding to respective ones in a plurality of integrating terms can be measured. By inputting measuring data Da-Dc measured by the measuring units 2a-2c and computing the integrated power values in the control part 3 according to the measured result of an internal timepiece 21, only by setting the time of the one internal timepiece 21, measurement can be begun correctly and surely at the measurement beginning time of the respective integrating terms, and the measurement can be completed at the respective measurement completing times correctly and surely.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a measuring apparatus applicable to ammeters such as an integrating wattmeter and an integrating ammeter for measuring integrated power and integrated current.

[0002]

2. Description of the Related Art Conventionally, for example, when measuring integrated power for a plurality of independent integration periods, the following measuring method is used. First, for example, when trying to measure the integrated power for the U-phase and V-phase of commercial AC for three independent integration periods, as shown in FIG. Integral wattmeter 6
1a to 61c (hereinafter, when no distinction is made, the "power meter 6
1 "). In this case, these wattmeters 61a to 61c are each configured identically, and are clamp-type current measurement sensors 62a (or 6).
2b, 62c) and voltage measuring probes 63a, 64a (or 63b, 64b, 6) for measuring the inter-phase voltage.
3c, 64c).

Next, as shown in FIG. 1, the U-phase is clamped by a current measuring sensor 62a of a power meter 61a, and voltage measuring probes 63a and 64a are connected to the U-phase and V-phase, respectively. Similarly, the U phase is clamped by the current measuring sensors 62b and 62c of the wattmeters 61b and 61c, and the voltage measuring probes 63b and 64b and the voltage measuring probes 63c and 64c are respectively changed to the U phase and the V phase. Connecting. Next, an integration period is set by operating each integration period setting switch (not shown) provided in the wattmeters 61a to 61c. In this case, for example, for the wattmeters 61a, 61b, and 61c, the start time is set to 12:00, 12:30, and 13:00, and the end time is set to 14:00, 15:00, and 13:00. Set to 16:00.

Then, when the time of the internal clock in each wattmeter 61 reaches the set start time, the wattmeter 61a first starts measuring the integrated power, and thereafter, every time the set start time is reached, the power The total 61b, 61c starts measurement in order. On the other hand, when the time of the internal clock in each power meter 61 reaches the set end time, the power meters 61a, 61b, 61c
Terminates the measurement and displays the measured integrated power on a display unit (not shown).

[0005]

However, these wattmeters 61 have the following problems. First, the wattmeter 61 starts the measurement when the set start time is reached and ends the measurement when the set end time is reached, according to the time of the internal clocks which are individually built in. Therefore, the integration period during which one power meter 61 can measure simultaneously is
There is only one. For this reason, as in the above example, when trying to measure the integrated power corresponding to each of a plurality of independent integration periods, the same number of wattmeters 61 as the number of the integration periods are required. There is a problem that the cost of the entire system rises.

Second, each wattmeter 61 determines whether the measurement start time or the measurement end time has been reached based on the time of an internal clock incorporated therein. For this reason, when it is desired to accurately measure the integrated power during the integration period from the measurement start time to the measurement end time, the internal clocks in the wattmeters 61 must be accurately set. For this reason, the measurement system using the conventional wattmeter 61 has a problem that the work for accurately setting the integration period is complicated.

[0007] The present invention has been made in view of such a problem, and has as its main object to provide a measuring apparatus capable of reducing the cost of a measuring system. It is another object of the present invention to provide a measuring device capable of easily performing an accurate setting operation of the integration period.

[0008]

According to a first aspect of the present invention, there is provided a measuring device for measuring an integrated measured value by integrating a measured value measured based on an input signal. It is characterized in that integrated measurement values respectively corresponding to a plurality of independent integration periods can be measured.

According to a second aspect of the present invention, there is provided the measuring apparatus according to the first aspect, wherein a plurality of measuring units capable of independently measuring the measured values are provided based on the measured values measured by the plurality of measuring units. A calculating unit for calculating integrated measurement values corresponding to a plurality of integration periods set for each measurement unit.

In the measuring apparatus according to the first and second aspects, when a plurality of integration periods independent of each other are set, the measurement value is measured based on the input signal, and at each of the integration periods,
The integrated measured value is measured by integrating the measured values. Therefore, it is possible to measure integrated measurement values corresponding to each of a plurality of integration periods by using only one measuring device.

According to a third aspect of the present invention, in the measuring apparatus of the second aspect, a timer circuit for measuring each of a plurality of set integration periods is provided. Accordingly, the measurement values of a plurality of measurement units are input and the integrated measurement value is calculated.

In these measuring apparatuses, one timer circuit measures each of a plurality of set integration periods. Therefore, if you want to start the measurement reliably at the measurement start time and surely end the measurement at the measurement end time, you can set the time of that one timer circuit, and the measurement will start accurately and reliably at the measurement start time of each integration period. Is started, and the measurement is ended accurately and reliably at each measurement end time. Therefore, it is possible to accurately measure each integrated measurement value corresponding to each of the plurality of integration periods.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which a measuring device according to the present invention is applied to an integrating wattmeter will be described below with reference to the accompanying drawings.

First, the configuration of the wattmeter 1 will be described with reference to FIG.

As shown in FIG.
Three measuring units 2a and 2b configured identically to each other
(Hereinafter, also referred to as “measurement unit 2” when no distinction is made) and a control unit 3 corresponding to an arithmetic unit in the present invention.
And an operation unit 4 provided with various switches for setting various measurement conditions such as an integration period, and measured values such as measured integrated power, integrated current, voltage value and current value,
And a display unit 5 for displaying various set measurement conditions and the like.

The measuring unit 2 is configured to be capable of measuring measured values as various electric parameters such as power, voltage, current, apparent power, and reactive power in accordance with an input signal. Measurement circuit 1 for measuring values
1 and an analog measurement value measured by the measurement circuit 11 to sample digital data Da (or D
b, Dc), and an A / D converter (analog-digital converter) 12 and a clock oscillator 13 for generating a sampling clock for the A / D converter.
In this case, each clock oscillator 13 in each measurement unit 2
Oscillates a sampling clock in synchronization with a synchronization signal SS output from the control unit 3. The measurement unit 2 includes a clamp-type current measurement sensor 31a (or 31b, 31c) and a voltage measurement probe 32a,
33a (or 32b, 33b, 32c, 33c). With this configuration, in the wattmeter 1, for example,
Single-phase measurement can be performed using the measurement unit 2 individually,
It is possible to perform three-phase three-wire measurement by combining the two measurement units 2 and 2, or to perform three-phase four-wire measurement by combining the three measurement units 2, 2, and 2.

On the other hand, the control unit 3 is actually constituted by a one-chip microcomputer, and controls the synchronous oscillation of the clock oscillator 13 in each measurement unit 2.
Measurement data Da to Dc output from each measurement unit 2
Calculation of various measured values such as integrated power, integrated current, power factor, and phase angle, and display of various measured values on the display unit 5 based on the above. Further, the control unit 3 includes an internal clock 21 for measuring time, a start register 22, an end register 23, and a calculation memory 24 therein. In this case, the start register 22 has, for example, a storage capacity with the same bit length (3 bits in this example) as the number of the measurement units 2. The bits r1a to r1c correspond to the measurement units 2a to 2c in advance, respectively, and the control unit 3 controls the bit r1
The values a to r1c are initialized to 0 when the power is initially turned on, and the value 1 is written when the start time of the integration period for calculating the integrated measurement values such as the integrated power and the integrated current is reached. On the other hand, the end register 23 is
Has the same bit length storage capacity. The bits r2a to r2c of the end register 23 are respectively associated with the measurement units 2a to 2c in advance, and the control unit 3 initializes the value to 0 at the initial power-on, and sets the value at the end time of the integration period. When it reaches, write the value 1. Further, the calculation memory 24 temporarily stores calculation data when calculating the integrated measurement value and the like.

Next, the measurement process when the wattmeter 1 measures the integrated measurement value will be described with reference to FIG.

First, the current measuring sensors 31a, 31
The U phase of the commercial alternating current is clamped by b and 31c. Next, the probes 32a, 32b, and 32c for voltage measurement are connected to the U phase, and the probes 33a, 33b, and 33c are connected to the V phase. In this state, the integration period is set by operating the integration period setting switch of the operation unit 4. In this case, for example, the measurement units 2a, 2b,
2c, the start times are 12:00 and 12
The time is set to 1:30 and 13:00, and the end time is set to 14:00, 15:00 and 16:00. Also,
When the start time and end time of the integration period are to be accurate, the time of the internal clock 21 in the control unit 3 is adjusted by operating a time adjustment switch (not shown) of the operation unit 4.

Next, when the measurement start switch in the operation unit 4 is operated, the control unit 3 refers to the time of the internal clock 21 and whenever the set measurement start time is reached, the control unit 3 Is written to each bit r1a to r1c of the start register 22 associated with the measurement register 2, and each time the set measurement end time is reached, the end register 22 associated with the measurement unit 2
The value 1 is written to each bit r2a to r2c.

Next, as shown in FIG. 2, the control unit 3 starts the start register 2 corresponding to the measuring unit 2a.
It is determined whether or not the measurement start time of the measuring unit 2a has been reached by referring to the bit r1a of step 2 (step 41). When the value 1 is written to the bit r1a, the control unit 3 determines that the measurement start time has been reached, and starts the integration operation based on the measurement data Da (Step 4).
2). In this case, the integrated power WT is a power value based on the measurement data Da sequentially output from the measurement unit 2a.
1, W2..., Is calculated according to the following equation. WT = (W1 + W2 +. + Wn) / (number m of measured data per hour) formula

After starting the integration calculation or when it is determined in step 41 that the measurement start time has not been reached, the control unit 3 refers to the bit r2a of the end register 23 corresponding to the measurement unit 2a. Then, it is determined whether or not the measurement end time of the measurement unit 2a has been reached (step 43). When the value 1 is written to the bit r2a, the control unit 3 determines that the measurement end time has been reached, stops inputting the measurement data Da, and ends the integration calculation (step 44).

Subsequently, when the integration operation is completed in step 44 described above or when it is determined in step 43 that the measurement end time has not been reached, the control unit 3 is made to correspond to the measurement unit 2b. By referring to the bit r1b of the start register 22, it is determined whether or not the measurement start time of the measurement unit 2b has been reached (step 45). When the value 1 is written to the bit r1b, the control unit 3 determines that the measurement start time has been reached, and starts the integration operation based on the measurement data Db (step 46). Also in this case, the control unit 3
The integrated power is calculated according to the above equation. After the start of the integration operation or when it is determined in step 45 that the measurement start time has not been reached, the control unit 3 sets the end register 2 associated with the measurement unit 2b.
It is determined whether or not the measurement end time of the measurement unit 2b has been reached by referring to the bit r2b of 3 (step 47). When the value 1 is written to the bit r2b, the control unit 3 determines that the measurement end time has been reached, stops inputting the measurement data Db, and ends the integration calculation (step 48).

Next, when the integration operation is completed in the above-described step 48, or when it is determined in the above-described step 47 that the measurement end time has not been reached, the control unit 3 starts the operation corresponding to the measurement unit 2c. It is determined whether or not the measurement start time of the measurement unit 2c has been reached by referring to the bit r1c of the register for use 22 (step 49). When the value 1 is written to the bit r1c, the control unit 3 determines that the measurement start time has been reached, and starts an integration operation based on the measurement data Dc (step 50). Also in this case, the control unit 3
The integrated power is calculated according to the above equation. After starting the integration calculation or when it is determined in step 49 that the measurement start time has not been reached, the control unit 3 sets the end register 2 associated with the measurement unit 2c.
It is determined whether or not the measurement end time of the measurement unit 2c has been reached by referring to the bit r2c of 3 (step 51). When the value 1 is written to the bit r2c, the control unit 3 determines that the measurement end time has been reached, stops inputting the measurement data Dc, and ends the integration calculation (step 52). Thereafter, when the integration operation is completed in the above-described step 52, or when it is determined in the above-described step 51 that the measurement end time has not been reached, the measurement described above is performed until the measurement is started and completed for all the measurement units 2. Step 41 to Step 5
Repeat 2.

After starting the measurement, the control section 3 displays on the display section 5 that the measurement is being performed and the integrated power being measured, and displays the end of the measurement and the integrated power as the measurement result when the measurement is completed. Display on the part 5.

As described above, in the wattmeter 1, the control unit 3
Are the measurement data Da to D output from the measurement unit 2.
By integrating the power values based on c, each integrated power is measured in a plurality of independent integration periods corresponding to each of the measurement units 2a to 2c. Therefore, the integrated power corresponding to each of the plurality of integration periods can be measured only by using one power meter 1. In addition, the control unit 3 sets the measurement data D measured by the measurement units 2a to 2c in accordance with the measurement result of the internal clock 24.
By inputting a to Dc and calculating the integrated power, 1
By simply setting the times of the two internal clocks 24, the measurement can be started accurately and reliably at the measurement start time of each integration period, and the measurement can be accurately and reliably ended at each measurement end time.

Further, since the clock oscillation by each clock oscillator 13 in the measuring unit 2 is synchronized with the synchronizing signal SS output from the control unit 3, it is necessary to accurately measure, for example, the conversion efficiency of the inverter device. Can be. Specifically, the current measurement sensor 31a of the measurement unit 2a is connected to the U-phase
2a and the probe 33a are connected to the U-phase and V-phase of the commercial AC, respectively. Also, the current measuring sensor 31b of the measuring unit 2b is connected to one output line of the inverter device, and the probe 32b and the probe 33
b is connected to one output line and the other output line of the inverter device, respectively. In this state, the control unit 3 starts measuring the integrated power at the same time based on the measurement data Da and Db output from the measuring units 2a and 2b, and ends the measurement at the same time. This makes it possible to measure the integrated power input to the inverter device and the integrated power output from the inverter device during the same integration period, so that the conversion efficiency of the inverter device can be accurately determined based on the integrated input power and the integrated output power. And it can be easily measured.

The present invention is not limited to the configuration shown in the above embodiment of the present invention. For example, in the embodiment of the present invention, an example in which the start register 22 and the end register 23 have the same number of bits as the number of the measurement units 2 has been described. It can also be constituted by the number of bits. In such a case, the integrated power in a plurality of independent integration periods can be calculated using one measurement unit 2. Further, in the present embodiment, an example has been described in which the integrated power between the U-phase and the V-phase of the commercial AC is measured. However, each of the measurement units 2a to 2c has different inter-phase integrated power (for example, Of course, the integrated power between the V phase and the W phase can be measured. Further, the present invention is not limited to the measurement of the integrated power, and can be applied to a measuring device that measures an integrated measured value of an arbitrary measured value such as an integrated current. Further, in the embodiment of the present invention, the example of the wattmeter 1 configured by arranging three measurement units 2 has been described. However, it is possible to configure by arranging two or four or more measurement units 2. Can also.

[0029]

As described above, according to the measuring apparatus of the first and second aspects, one measuring apparatus is used by measuring integrated measurement values respectively corresponding to a plurality of independent integration periods. By itself, the integrated measurement value corresponding to each of the plurality of integration periods can be calculated. Thereby, the cost of the measurement system can be reduced.

According to the measuring device of the third aspect,
The control unit inputs the measured value according to the measurement result of the timer circuit and calculates the integrated measurement value, so that if the time of one of the timer circuits is set, the measurement start time of each integration period can be accurately and reliably set. The measurement can be started, and the measurement can be accurately and reliably ended at each measurement end time. This makes it extremely easy to accurately set the integration period, and it is possible to accurately measure the integrated measurement values respectively corresponding to the plurality of integration periods.

[Brief description of the drawings]

FIG. 1 is a block diagram of a wattmeter according to an embodiment of the present invention.

FIG. 2 is a flowchart illustrating a measurement process performed by the power meter according to the embodiment of the present invention.

FIG. 3 is a system diagram of a measurement system using a conventional power meter.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Wattmeter 2a-2c Measurement unit 3 Control part 21 Internal clock 22 Start register 23 End register

Claims (3)

[Claims] 1. A measuring apparatus for measuring an integrated measured value by integrating and calculating a measured value measured based on an input signal, wherein the integrated measured value corresponding to each of a plurality of independent integration periods can be measured. A measuring device characterized by being performed. 2. A plurality of measurement units capable of independently measuring the measurement values, and the plurality of integrations set for each of the measurement units based on the measurement values respectively measured by the plurality of measurement units. The measurement device according to claim 1, further comprising a calculation unit that calculates the integrated measurement value corresponding to each period. 3. A timer circuit for measuring each of the set plurality of integration periods, wherein the arithmetic unit calculates the measured values of the plurality of measurement units according to a measurement result of the timer circuit. The measuring device according to claim 2, wherein the integrated measurement value is calculated by inputting.