JP2009002854A - Watt-hour meter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a watt-hour meter capable of reducing its consumption current. <P>SOLUTION: Current detection means 103, 104 monitor a use current used by a consumer. A frequency division ratio for dividing a frequency signal output from a frequency conversion section 107 is designated to a frequency divider section 108 according to the use current so that a pulse frequency is set within a prescribed low frequency range. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a watt-hour meter that measures the amount of power used by a system under measurement.

Conventionally, watt-hour meters that measure the amount of power used by ordinary households, factories, and offices have become widespread. The watt-hour meter displays a usage amount detecting means for measuring the used power amount of the system to be measured, a control portion for editing the usage amount detected by the usage amount detecting means into data, and data edited by the control portion. And a display unit. (For example, Patent Document 1)
JP 2004-226094 A (page 10, FIG. 2)

An electricity meter that measures the amount of electricity used by each consumer is attached to each house, and the number of popularization is said to be around 70 million units nationwide. In recent years, the amount of power used by each consumer tends to increase, and power supply is tight, and it has become a national level responsibility to realize so-called “energy saving” and “global warming prevention”.

A watt-hour meter that measures the amount of power used by a consumer also consumes power for its operation. The power consumption per unit of energy meter seems to be very small compared to a large household appliance. However, considering the number of watt-hour meters installed throughout the country, it can be said that if the power consumption of each watt-hour meter can be reduced, it can contribute to “energy saving” and “preventing global warming”.

In the conventional watt hour meter, since the pulse directly proportional to the amount of power used calculated by the metering unit is displayed as it is on the display unit, the power consumption of the watt hour meter as a whole has not been reduced.

  An object of this invention is to provide the watt-hour meter which can reduce power consumption in view of the said problem.

In order to achieve the above object, a watt-hour meter according to the present invention comprises a power measuring means for measuring the power of a system under measurement, a frequency converting means for converting the power measured by the power measuring means into a frequency signal, Frequency dividing means for dividing the frequency signal output by the frequency converting means, current measuring means for measuring the current of the system under measurement, and the frequency dividing means according to the magnitude of the current measured by the current measuring means Control means for determining the frequency division ratio, and display means for displaying the frequency division signal output by the frequency division means.

  ADVANTAGE OF THE INVENTION According to this invention, the watt-hour meter which can reduce power consumption can be provided.

  Examples of the present invention will be described below.

  A first embodiment of a watt-hour meter according to the present invention will be described with reference to FIG. FIG. 1 is an internal configuration diagram showing a first embodiment of a watt-hour meter according to the present invention.

  In FIG. 1, 100 is a watt-hour meter main body.

101 is a terminal portion, and a conductive portion made of a conductive metal such as brass or copper is composed of a fixed portion made of a material such as a phenol resin, a PBT resin, or a highly insulating plastic, An external distribution line is connected to the electronic watt-hour meter main body 100. The 1S, 2S, and 3S terminals are connected to a power supply side distribution line that receives power from a power supply company, and the 1L, 2L, and 3L terminals are connected to a load side distribution line that supplies power into the consumer. In this embodiment, a single-phase three-wire electronic watt-hour meter is used.

Reference numeral 102 denotes a power measuring unit that measures and outputs power consumed by a consumer. The interior has the following configuration.

Reference numerals 103 and 104 denote current detection units, each of which includes a circuit that combines a current transformer and an analog-digital converter. The current detection unit 103 generates a current (one-side current) between the terminals 1S-1L of the terminal unit 101. The current detection unit 104 detects the current (3 side current) between the terminals 3S-3L, converts it into digital data that is directly proportional to the current used by the consumer, and outputs it.

Reference numeral 105 denotes a voltage detector, which is composed of a circuit that combines a voltage transformer and an analog-digital converter. The voltage between the terminals 1S-2S and between the terminals 3S-2S (referred to as 1 side voltage and 3 side voltage, respectively). ) Is detected, converted to digital data that is directly proportional to the voltage used, and output.

A power multiplication unit 106 includes a digital multiplication circuit and the like. The digital data signal is directly proportional to the one-side current output from the current detection unit 103 and the digital data is directly proportional to the one-side voltage output from the voltage detection unit 105. The digital data that is directly proportional to the three-side current output from the data and current detection unit 104 and the digital data that is directly proportional to the three-side voltage output from the voltage detection unit 105 are multiplied to obtain digital data that is directly proportional to the power used by the consumer. Convert and output.

Reference numeral 107 denotes a frequency conversion unit, which includes a counter circuit or the like, and converts digital data directly proportional to the consumer's power output from the power multiplication unit 106 into a frequency signal and outputs the frequency signal. The frequency conversion unit 107 may be configured in the control unit 110 described later.

Reference numeral 108 denotes a frequency dividing unit, which is configured by a counter circuit or the like capable of presetting the frequency dividing ratio. The frequency signal output from the frequency converting unit 107 is divided to obtain a frequency signal having a reduced frequency. Convert and output. The frequency division ratio is instructed by the control unit 110 described later. The frequency conversion unit 107 may be configured in the control unit 110 described later.

Reference numeral 109 denotes a display unit which is configured by a liquid crystal display or the like, and a numerical display unit which displays the amount of power used by the customer as a numerical value, and a pulse display unit which displays the power used by the customer as a pulsed flashing display. It consists of.

A control unit 110 is configured by a microcomputer or the like, and edits digital data that is directly proportional to the power consumption of the customer output from the power multiplication unit 106 and displays it on the display unit 109 as the power consumption. In addition, the control unit 110 receives digital data that is directly proportional to the current used by the consumer from the current detection units 103 and 104. Further, the control unit 110 determines the frequency division ratio and instructs the frequency division unit 108 of the frequency division ratio.

Next, the operation of this embodiment will be described. Conventionally, the display unit of the watt-hour meter has a numerical display unit that displays the amount of electric power used by the customer as a numerical value, and a pulse display unit that displays a pulse-like blinking display having a frequency that is directly proportional to the electric power used by the consumer. It was made up of. The pulse display section is not intended to be confirmed by the naked eye of a consumer or the like, but is read by a dedicated external device to confirm that the watt-hour meter is operating correctly according to the power used. The frequency was directly proportional to the power used, and was output in a pulsed blinking display. The frequency of the pulse-like blinking display differs depending on the electric power used by the consumer, and is a high frequency of about 1000 Hz at maximum and a low frequency of about several Hz at minimum. For this reason, a liquid crystal display that can be expected to achieve low power consumption that can only support a display of about 20 Hz at the maximum cannot be used, and light emitting diodes are used, resulting in high power consumption. If this embodiment is used, it is possible to perform a blinking display in a pulse shape corresponding to the power used by consumers at a low frequency, and a liquid crystal display can be used, so that the power consumption of the watt hour meter can be reduced. Is possible. Further, even when a display device with high power consumption such as a light emitting diode is used, the pulse frequency can be lowered, so that the power consumption of the watt-hour meter can be reduced.

Next, the operation of this embodiment will be described with reference to the program flow diagram of FIG. This program is stored in a program memory (not shown) in the control unit 110 and controls the operation of the control unit 110.

The control unit 110 always edits digital data that is directly proportional to the customer's power consumption output from the power multiplication unit 106 and displays the power consumption amount on the numerical value display unit of the display unit 109. The program flow diagram is shown only for the portion related to the display operation of the pulse display unit of the display unit 109. In addition, a present Example shows about the watt hour meter of a single phase 3 wire type 100V30A rating with a high penetration rate.

The control unit 110 receives digital data that is directly proportional to the current between the current detection units 103 and 104 (1 side current) and the current between 3S and 3L (3 side current), adds them, and adds the two. Is used (step 201). In the watt-hour meter rated for a single-phase three-wire system 100V30A, the maximum value for both the one-side current and the three-side current is 30A. When the consumer's use current A1 is 60A, the voltage is 100V, and the power factor is 1.0, the frequency conversion unit 107 outputs, for example, 1000 Hz.

Next, the control unit 110 determines whether the consumer current consumption A1 calculated in step 201 is 60A or less and 6A or more (step 202). 60A is the maximum operating current of the consumer. 6A is 1/10 of 60A which is the maximum use current of the consumer.

When it is determined that the consumption current A1 of the consumer is 60A or less and 6A or more, the control unit 110 instructs the frequency division unit 108 to divide the output pulse frequency of the frequency conversion unit 107 to 1/1000, and the pulse shape Is displayed on the pulse display section of the display section 109 (step 203).

Further, the pulse display portion of the display portion 109 is displayed to indicate that the frequency division ratio is 1/1000 and the maximum current is 60 A (step 204).

The display unit 109 is specifically configured as shown in FIG. The display unit 109 includes a numerical display unit 300 that indicates the amount of power consumed by the consumer, and a pulse display unit 301 that performs pulse-like blinking display at a frequency corresponding to the power used. The pulse display unit 301 further includes display units 302 and 303. , 304, 305, and 306. The display units 302, 303, 304, 305, and 306 are dot displays configured by a liquid crystal display or the like, and the display unit 302 of the pulse display unit 301 receives one of the signals from the frequency conversion unit 107 by the operation of step 203. A pulse-like blinking display with a frequency of / 1000 is performed. Further, the display unit 303 of the pulse display unit 301 that is divided by 1/1000 and indicates that the maximum current is 60 A is turned on by the operation of step 204. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 302 of the pulse display unit 301 can be set to 1 Hz or less.

Next, the control unit 110 determines whether or not the consumer current consumption A1 calculated in step 201 is less than 6A and 0.6A or more (step 205). 6A is 1/10 of 60A which is the maximum use current of the consumer. 0.6 A is 1/100 of 60 A, which is the maximum operating current of the consumer.

When it is determined that the consumption current A1 of the consumer is less than 6A and 0.6A or more, the control unit 110 instructs the frequency division unit 108 to divide the output pulse frequency of the frequency conversion unit 107 by 1/100. Then, a pulse-like blinking display having the divided frequency is displayed on the pulse display unit 301 (step 206).

Further, the pulse display unit 301 is displayed to indicate that the frequency division ratio is 1/100 and the maximum current is 6 A (step 207).

The display unit 302 of the pulse display unit 301 performs a pulse-like blinking display having a frequency 1/100 of the signal from the frequency conversion unit 107 by the operation of step 206. Further, the display unit 304 of the pulse display unit 301 that is divided by 1/100 and indicates that the maximum current is 6 A is turned on by the operation of step 207. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 302 of the pulse display unit 301 can be set to 1 Hz or less.

Next, the control unit 110 determines whether or not the consumer's current consumption A1 calculated in step 201 is less than 0.6A and not less than 0.06A (step 208). 0.6 A is 1/100 of 60 A, which is the maximum operating current of the consumer. 0.06 A is 1/1000 of 60 A, which is the maximum usage current of the consumer.

When it is determined that the consumption current A1 of the consumer is less than 0.6 A and 0.06 A or more, the control unit 110 divides the output pulse frequency of the frequency conversion unit 107 by 1/10 with respect to the frequency division unit 108. The pulse display unit 301 is caused to display a pulse-like blinking display having the divided frequency (step 209).

Further, the pulse display unit 301 is displayed to indicate that the frequency division ratio is 1/10 and the maximum current is 0.6 A (step 210).

The display unit 302 of the pulse display unit 301 performs a pulsed blinking display having a frequency of 1/10 of the signal from the frequency conversion unit 107 by the operation of step 209. Further, the display unit 305 of the pulse display unit 301 that is divided by 1/10 and indicates that the maximum current is 0.6 A is turned on by the operation of step 210. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 302 of the pulse display unit 301 can be set to 1 Hz or less.

Next, the control unit 110 determines whether or not the consumer current consumption A1 calculated in step 201 is less than 0.06 A (step 211). 0.06 A is 1/1000 of 60 A, which is the maximum usage current of the consumer.

When it is determined that the consumption current A1 of the consumer is less than 0.06 A, the control unit 110 instructs the frequency division unit 108 to divide the output pulse frequency of the frequency conversion unit 107 by 1/1, and A pulse-like blinking display having the divided frequency is displayed on the pulse display unit 301 (step 212).

Further, the pulse display unit 301 is displayed to indicate that the frequency division ratio is 1/1 and the maximum current is 0.06 A (step 213).

The display unit 302 of the pulse display unit 301 performs a pulse-like blinking display having a 1/1 frequency of the signal from the frequency conversion unit 107 by the operation of step 212. Further, the display unit 306 of the pulse display unit 301 that is divided by 1/1 and indicates that the maximum current is 0.06 A is turned on by the operation of step 213. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 302 of the pulse display unit 301 can be set to 1 Hz or less.

When it is determined that the consumer's current consumption A1 calculated in step 201 is not within the ranges of steps 202, 205, 208, and 211, the control unit 110 determines that it is outside the measurable range and blinks. The pulse display unit 301 is controlled not to perform.

  In the above embodiment, as shown in FIG. 3, the pulse-like blinking display is displayed on the display unit 302, and the maximum current is displayed on the display units 303, 304, 305, 306, but as shown in FIG. A pulse-like blinking display divided into 1/1000 is displayed on the display unit 402, a pulse-like blinking display divided into 1/100 is displayed on the display unit 403, and a pulse-like blinking display divided into 1/10. The blinking display may be displayed on the display unit 404, and the pulsed blinking display divided by 1/1 may be displayed on the display unit 405.

By using this embodiment, it is possible to perform a pulse-like blinking display that blinks at a frequency corresponding to the power used by the consumer at a low frequency, and it is possible to reduce the power consumption of the watt-hour meter. Since the display frequency of the pulsed blinking display is within the operating speed range of the liquid crystal display, a liquid crystal display operating with low power consumption can be used, and the power consumption of the entire watt-hour meter can be reduced. Even when a light emitting diode or the like is used for the display device, since the display frequency of the pulsed blinking display is low, if the duty is set to shorten the light emission time, the power meter as a whole can be reduced in power consumption. it can.

In addition, if the present embodiment is used, the watt hour meter can reduce power consumption, so that the power meter circuit of the watt hour meter can be downsized and the power source circuit can be made inexpensive. Yes, the watt-hour meter as a whole can be reduced in cost.

  As described above, by using the present invention, a watt-hour meter capable of reducing power consumption can be provided.

  Example 2 of the watt-hour meter according to the present invention will be described. The hardware of the second embodiment has the same configuration as each part of the watt-hour meter of the first embodiment shown in FIG.

  The difference between the second embodiment and the first embodiment is that, in the first embodiment, the control unit 110 measures the current used by the customer, and the frequency signal output from the frequency converter 107 according to the current used by the customer. However, in the second embodiment, instead of this, the control unit 110 detects the frequency of the frequency signal output from the frequency conversion unit 107, and the frequency is Accordingly, the frequency division unit 108 is instructed to the frequency division ratio of the frequency signal output from the frequency conversion unit 107. Therefore, the software configuration stored in a program memory (not shown) in the control unit 110 is different between the first embodiment and the second embodiment.

Next, the operation of this embodiment will be described with reference to the program flow diagram of FIG. This program is stored in a program memory (not shown) in the control unit 110 and controls the operation of the control unit 110.

The control unit 110 always edits digital data that is directly proportional to the power consumption of the customer output from the power multiplication unit 106 and displays the power consumption amount on the numerical display unit of the display unit 109. The program flow diagram is shown only for the portion related to the display operation of the pulse display unit of the display unit 109. In addition, a present Example shows about the watt hour meter of a single phase 3 wire type 100V30A rating with a high penetration rate.

The control unit 110 measures the frequency f1 of the frequency signal that is directly proportional to the data output from the power measurement unit 102 output from the frequency conversion unit 107 (step 501). The frequency f1 is, for example, 1000 Hz when a watt-hour meter rated for a single-phase three-wire system 100V30A is used.

Next, the control unit 110 determines whether the frequency f1 measured in step 501 is 1000 Hz or less and 100 Hz or more (step 502). 1000 Hz is the output frequency of the frequency conversion unit 107 corresponding to the maximum power consumption of the consumer. 100 Hz is a frequency of 1/10 at the time of the maximum power consumption of the consumer.

When it is determined that the frequency f1 is 1000 Hz or less and 100 Hz or more, the control unit 110 instructs the frequency division unit 108 to divide the output pulse frequency of the frequency conversion unit 107 by 1/1000, and the frequency division is performed. A pulse-like blinking display having a frequency is displayed on the pulse display unit of the display unit 109 (step 503).

In addition, a display is made on the pulse display unit 109 to indicate that the frequency division ratio is 1/1000 (step 504).

The display unit 109 is specifically configured as shown in FIG. The display unit 109 includes a numerical display unit 600 that indicates the amount of power consumed by the consumer and a pulse display unit 601 that performs pulse-like blinking display at a frequency corresponding to the power used. The pulse display unit 601 further includes display units 602, 603, 604, 605, and 606. Display units 602, 603, 604, 605, and 606 are dot displays configured by a liquid crystal display or the like. The display unit 602 performs a 1/1000 frequency of a signal from the frequency conversion unit 107 by the operation of step 503. A blinking display with a pulse shape. Further, the display unit 603 of the pulse display unit 601 indicating that the frequency has been divided by 1/1000 is turned on by the operation of step 504. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 602 of the pulse display unit 601 can be set to 1 Hz or less.

Next, the control unit 110 determines whether the frequency f1 measured in step 501 is less than 100 Hz and 10 Hz or more (step 505). 100 Hz is a frequency of 1/10 at the time of the maximum power consumption of the consumer. 10 Hz is a frequency that is 1/100 of the maximum power consumption of the consumer.

When it is determined that the frequency f1 is less than 100 Hz and 10 Hz or more, the control unit 110 instructs the frequency division unit 108 to divide the output pulse frequency of the frequency conversion unit 107 by 1/100, and the frequency division is performed. A pulse-like blinking display having a frequency is displayed on the pulse display unit 601 (step 506).

Further, it is displayed on the pulse display unit 601 to indicate that the frequency division ratio is 1/100 (step 507).

The display unit 602 of the pulse display unit 601 performs a pulsed blinking display having a frequency of 1/100 of the signal from the frequency conversion unit 107 by the operation of step 506. Further, the display unit 604 of the pulse display unit 601 indicating that the frequency has been divided by 1/100 is turned on by the operation of step 507. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 602 of the pulse display unit 601 can be set to 1 Hz or less.

Next, the control unit 110 determines whether the frequency f1 measured in step 501 is less than 10 Hz and 1 Hz or more (step 508). 10 Hz is a 1/100 frequency at the time of the maximum power consumption of the consumer. 1 Hz is a frequency that is 1/1000 of the maximum power consumption of the consumer.

When it is determined that the frequency f1 is less than 10 Hz and 1 Hz or more, the control unit 110 instructs the frequency division unit 108 to divide the output pulse frequency of the frequency conversion unit 107 by 1/10, and the frequency division is performed. A pulse-like blinking display having a frequency is displayed on the pulse display unit 601 (step 509).

Further, it is displayed on the display unit 605 of the pulse display unit 601 to indicate that the frequency division ratio is 1/10 (step 510).

The display unit 602 of the pulse display unit 601 performs pulse-like blinking display having a frequency of 1/10 of the signal from the frequency conversion unit 107 by the operation of step 509. Further, the display unit 605 of the pulse display unit 601 indicating that the frequency has been divided by 1/10 is turned on by the operation of step 510. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 602 of the pulse display unit 601 can be set to 1 Hz or less.

Next, the control unit 110 determines whether the frequency f1 measured in step 501 is less than 1 Hz (step 511). 1 Hz is a frequency that is 1/1000 of the maximum power consumption of the consumer.

When it is determined that the frequency f1 is less than 1 Hz, the control unit 110 instructs the frequency dividing unit 108 to divide the output pulse frequency of the frequency converting unit 107 into 1/1, and the frequency divided is used as the frequency f1. The pulse display unit 601 is caused to display the pulse-like blinking display it has (step 512).

Further, the pulse display unit 601 is displayed to indicate that the frequency division ratio is 1/1 (step 513).

The display unit 602 of the pulse display unit 601 performs a pulse-like blinking display having a 1/1 frequency of the signal from the frequency conversion unit 107 by the operation of step 512. Further, the display unit 606 of the pulse display unit 601 indicating that the frequency has been divided by 1/1 is turned on by the operation of step 513. By this operation, the blinking frequency of the pulse-like blinking display of the display unit 602 of the pulse display unit 601 can be set to 1 Hz or less.

When it is determined that the frequency f1 measured in step 501 is not within the ranges of steps 502, 505, 508, and 511, the control unit 110 determines that the frequency f1 is outside the measurable range and does not perform blinking display. The pulse display unit 601 is controlled.

  In the above embodiment, as shown in FIG. 6, the pulse-like blinking display is displayed on the display unit 602, and the division ratios are displayed on the display units 603, 604, 605, and 606. As shown, the pulse-like blinking display divided by 1/1000 is displayed on the display unit 702, and the pulse-like blinking display divided by 1/100 is divided by 1/10 on the display unit 703. A pulse-like blinking display may be displayed on the display unit 704, and a pulse-like blinking display divided by 1/1 may be displayed on the display unit 705.

By using this embodiment, it is possible to perform a pulse-like blinking display that blinks at a frequency corresponding to the power used by the consumer at a low frequency, and it is possible to reduce the power consumption of the watt-hour meter. Since the display frequency of the pulsed blinking display is within the operating speed range of the liquid crystal display, a liquid crystal display operating with low power consumption can be used, and the power consumption of the entire watt-hour meter can be reduced. Even when a light emitting diode or the like is used for a pulsed flashing display device, the display frequency of the pulsed flashing display is low. Power consumption can be reduced.

In addition, if the present embodiment is used, the watt hour meter can reduce power consumption, so that the power meter circuit of the watt hour meter can be downsized and the power source circuit can be made inexpensive. Yes, the watt-hour meter as a whole can be reduced in cost.

  As described above, by using the present invention, a watt-hour meter capable of reducing power consumption can be provided.

The internal block diagram which shows the structure of Example 1 of the watt-hour meter by this invention The program flow figure which shows the program of Example 1 by this invention The figure which shows the structure of the display part of Example 1 of the watt-hour meter by this invention. The figure which shows the structure of the display part of Example 1 of the watt-hour meter by this invention. Program flow diagram showing a program of the second embodiment according to the present invention The figure which shows the structure of the display part of Example 2 of the watt-hour meter by this invention. The figure which shows the structure of the display part of Example 2 of the watt-hour meter by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Power meter main body 101 Terminal part 102 Power measurement part 103 Current detection part 104 Current detection part 105 Voltage detection part 106 Power multiplication part 107 Frequency conversion part 108 Frequency division part 109 Display part 110 Control part 300 Numerical value display part 301 Pulse display part 302, 303, 304, 305, 306 Display unit 400 Numerical display unit 401 Pulse display unit 402, 403, 404, 405 Display unit 600 Numerical display unit 601 Pulse display unit 602, 603, 604, 605, 606 Display unit 700 Numerical display Section 701 Pulse display section 702, 703, 704, 705 Display section

Claims (8)

Power measuring means for measuring the power of the system under measurement;
Frequency conversion means for converting the power measured by the power measurement means into a frequency signal;
Frequency dividing means for dividing the frequency signal output by the frequency converting means;
Current measuring means for measuring the current of the system under measurement;
Control means for determining a frequency dividing ratio of the frequency dividing means according to the magnitude of the current measured by the current measuring means;
A watt hour meter comprising: first display means for displaying a frequency-divided signal output by the frequency dividing means. The watt-hour meter according to claim 1, further comprising second display means for displaying a frequency division ratio of the frequency-divided signal output by the frequency dividing means. The said 1st display means consists of a some display part, The frequency-divided signal output by the said frequency-dividing means is displayed on these display parts for every frequency division ratio. Electricity meter. The watt-hour meter according to any one of claims 1 to 3, wherein the first display means is a liquid crystal display device. Power measuring means for measuring the power of the system under measurement;
Frequency conversion means for converting the power measured by the power measurement means into a frequency signal;
Frequency dividing means for dividing the frequency signal output by the frequency converting means;
A frequency measuring means for measuring the frequency of the frequency signal output by the frequency converting means; a control means for determining a frequency dividing ratio of the frequency dividing means according to the magnitude of the frequency measured by the frequency measuring means;
A watt-hour meter comprising: third display means for displaying a frequency-divided signal output by the frequency dividing means. 6. The watt-hour meter according to claim 5, further comprising fourth display means for displaying a frequency division ratio of the frequency-divided signal output by the frequency dividing means. The said 3rd display means consists of a some display part, The frequency-divided signal output by the said frequency-dividing means is displayed on a said some display part for every frequency division ratio. Electricity meter. The watt-hour meter according to any one of claims 5 to 7, wherein the third display means is a liquid crystal display device.

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