JP2774588B2 - Electronic watt-hour meter - Google Patents

Description

Description of the Invention [Object of the Invention] (Field of Industrial Application) The present invention relates to an electronic watt-hour meter, and more particularly, to an electronic watt-hour meter that prevents measurement of the amount of power in a creep state. .

(Prior Art) Generally, an electronic watt-hour meter converts power into a pulse having a frequency proportional to the power by a power-frequency conversion circuit,
This pulse is counted to measure the electric energy. This power-frequency conversion circuit generates a pulse having a wide pulse interval when the load current is zero and only the load voltage is applied.
A so-called creep phenomenon occurs. Therefore, in order to prevent the power from being measured in such a creep state, a creep prevention circuit is provided at the next stage of the power-frequency conversion circuit.

FIG. 5 is a block diagram showing a circuit configuration of such a conventional electronic watt-hour meter. The electronic watt-hour meter shown in FIG. 5 has a voltage detector 24 for detecting a load voltage _VL, and a load current I _L
, A power is calculated from the voltage and the current respectively supplied from the voltage detection unit 25 and the current detection unit 26, and the power is converted into a current or a voltage proportional to the power and output. A power detection circuit 26, a power-frequency conversion circuit 27 for converting an output signal of the power detection circuit 26 into a frequency signal, and a creep prevention circuit for removing a creep output included in an output of the power-frequency conversion circuit 28.
28, a frequency divider that divides the output signal of the power-frequency conversion circuit 27 that has passed through the creep prevention circuit 28 and weights the signal.
29, a counting section 30 for counting the output signal of the frequency dividing section 29, and a display section 31 for displaying the count value of the counting section 30 as a power amount in units of kilowatt hours (kWh).

As shown in FIG. 6, the creep prevention circuit 28 includes an oscillation circuit 32, a differentiation circuit 33, a frequency division circuit 34, and gates 35 and 3,
6, 37, an OR gate 38, and a D-type flip-flop 39.

(Problems to be Solved by the Invention) As described above, in the conventional electronic watt-hour meter, since the creep prevention circuit is composed of a relatively complicated circuit, the number of components mounted on the printed circuit board is large. Therefore, there is a problem that the mounting space and the number of mounting steps are increased, and the price is further increased.

The present invention has been made in view of the above, and an object of the present invention is to provide an electronic watt-hour meter capable of reducing the number of circuit components and achieving downsizing and economy.

[Means for Solving the Problems] To achieve the above object, an electronic watt-hour meter according to the present invention comprises: a power-frequency conversion means for generating a pulse having a frequency proportional to power; -Pulse interval measuring means for measuring the interval between pulses from the frequency conversion means, and the power-
Power pulse counting means for counting power pulses from which pulses in the creep state have been removed from the pulses from the frequency conversion means, and when the power-frequency conversion means generates a pulse in the creep state, the pulse interval measuring means Comparing the pulse interval measured in step 1 with a first predetermined value, and when the pulse interval is greater than the first predetermined value, clears the pulse interval measuring means to maintain the creep state, and sets the pulse interval to the first predetermined value. When the value is equal to or less than a predetermined value, the pulse interval measuring means is cleared to shift to a non-creep state, and the first power pulse counting means is incremented.
Control means, when the power-frequency conversion means generates a pulse in a non-creep state, compares the pulse interval measured by the pulse interval measurement means with a second predetermined value, and determines that the pulse interval is When the pulse interval is smaller than a second predetermined value, the pulse interval measuring means is cleared to maintain a non-creep state, and the power pulse counting means is incremented. A second control unit that clears the measurement unit and shifts to the creep state.

(Operation) In the electronic watt-hour meter of the present invention, when a pulse is output from the power-frequency conversion unit in the creep state, the pulse interval measured by the pulse interval measurement unit is set to the first value.
When the pulse interval is larger than the first predetermined value, the pulse interval measuring means is cleared to maintain the creep state, and when the pulse interval is equal to or less than the first predetermined value, the pulse interval measuring means is cleared. Is cleared and the state shifts to the non-creep state, and the power pulse counting means is incremented.When the pulse is output from the power-frequency conversion means in the non-creep state, the pulse interval measured by the pulse interval measuring means is Is compared with a second predetermined value, and when the pulse interval is equal to or less than the second predetermined value, the pulse interval measuring means is cleared to maintain the non-creep state, the power pulse counting means is incremented, and the pulse interval is increased. When it is larger than the second predetermined value, the pulse interval measuring means is cleared and the state shifts to the creep state.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of an electronic watt-hour meter according to one embodiment of the present invention. The electronic watt-hour meter shown in FIG. 1 includes a power-frequency conversion circuit 1 that converts power into a pulse having a frequency proportional to the power and outputs the pulse. The pulse output from the power-frequency conversion circuit 1 The pulse is counted by the pulse counter 3 and supplied to the CPU 5 via the bus line 15. The CPU 5 is interrupted by a predetermined timing pulse output from the oscillator 7,
As a result, the CPU 5 performs an interruption process of the electric energy measurement having the creep prevention function.

The CPU 5 is connected to a memory 9 via a bus line 15, and the memory 9 is provided with a pulse interval counter 11 and a power pulse counter 13. The pulse interval counter 11 is a counter for measuring the interval between pulses output from the power-frequency conversion circuit 1, that is, the cycle of the output pulse, and the power pulse counter 13 is a power-frequency converter for removing pulses in a creep state. This is a counter for measuring the power pulse from the circuit 1, and the result counted by the power pulse counter 13 is displayed as a power amount on a display device (not shown).

Next, the operation will be described with reference to the state transition diagram of the electronic watt-hour meter shown in FIG. 1 shown in FIG.

In the state transition diagram of FIG. 2, the state that is creep
There are 100 and non-creep 200, but first,
Assuming that the electronic watt-hour meter is in the case of creep at 100, the CPU 5 is interrupted by the timing pulse from the oscillator 7 in this state, and the interrupt processing is started. When the interrupt processing is started, first, the pulse count value of the pulse counter 3 is read, and whether or not this count value is greater than the previously read count value, that is, the output pulse from the power-frequency conversion circuit 1 is output. Check if it is detected. As a result, when the count value has increased (step 80), the count value of the cycle of the output pulse of the power-frequency conversion circuit 1 measured by the pulse interval counter 11 is compared with a predetermined value N2. If the value is larger than the value N2 (process 120), the increment of the pulse counter 3, that is, the detected pulse is determined to be a creep pulse, the pulse interval counter 11 is cleared, and the creep state 100 is maintained (process 120). 130). On the other hand, when the count value measured by the pulse interval counter 11 is smaller than the predetermined value N2 (step 90), it is determined that the power pulse is normal without creep, and the power pulse counter 13 is updated by the increment of the pulse counter 3. At the same time, the pulse interval counter 11 is cleared (processing 105), and the state 200 shifts to the non-creep state 200 (processing 110).

If the count value of the pulse counter 3 has not increased (step 140), the pulse interval counter 11 is updated (step 150).

Next, as described above, after shifting to the non-creep state 200 through the process 110, the count value of the pulse counter 3 is read, and whether or not the count value is larger than the count value read last time is determined. If the value is increased (step 160), the count value measured by the pulse interval counter 11 is compared with a predetermined value N1. If the value is larger than the predetermined value N1, the pulse interval counter 11 is cleared,
The state returns to the creep state 100 (processing 170). If the count value measured by the pulse interval counter 11 is equal to or smaller than the predetermined value N1 (step 180), it is determined that the power pulse counter 13 is a normal power pulse without a creep state, and the power pulse counter 13 is incremented by the pulse counter 3, that is, detected. At the same time, the pulse interval counter 11 is cleared and the non-creep state 200 is maintained (step 190).

If the count value of the pulse counter 3 has not increased (process 200), the pulse interval counter 11 is updated,
The count value of the pulse interval counter 11 is compared with a predetermined value N1 (process 210). As a result of this comparison, the pulse interval counter 11
If the count value of the pulse interval counter 11 is equal to or less than the predetermined value N1, the non-creep state 200 is maintained without any operation (step 220). Return to state 100 (process 230).

A timing pulse is output from the oscillator 7 and the above processing is performed each time an interrupt processing to the CPU 5 is performed, so that only a normal power pulse which is not in the creep state as described above can be counted. The predetermined values N1 and N2 are defined from a graph in which the horizontal axis represents the output frequency of the power-frequency conversion circuit 1 and the vertical axis represents the output pulse of the creep prevention circuit, as shown in FIG. Things.

Next, the operation described above will be described more clearly with reference to FIG.

FIG. 4 (a) shows the waveform of the output pulse of the power-frequency conversion circuit 1, and FIG. 4 (b) shows the waveform of the output timing pulse of the oscillator 7. The CPU 5 is interrupted each time it occurs, and the above-described processing is performed. First, as shown at times t0 and t1 in FIG. 4A, when the output pulse of the power-frequency conversion circuit 1 is wide, that is, in the creep state, the timing shown in FIG. In the processing started by the pulse, the pulse counter 3 is updated because the pulse counter 3 does not increase, that is, the pulse is not detected, and the updated count value is equal to the predetermined value N2.
When the output pulse of the power-frequency conversion circuit 1 is detected at the time t1, the count value of the pulse interval counter 11 is larger than the predetermined value N2. I do. At this time, the state is a creep state. Also, from time t1 to t2
Since the output pulse of the power-frequency conversion circuit 1 is wide during the period, the operation is the same as that described above.

Further, after detecting the time t2, the output pulse from the power-frequency conversion circuit 1 is detected at the time t3 before the count value of the pulse interval counter 11 exceeds the predetermined value N2, so that there is no creep state. It is determined that the power pulse is normal, the power pulse counter 13 is updated, and the state shifts to the non-creep state.

[Effects of the Invention] As described above, according to the present invention, when a pulse is output from the power-frequency conversion unit in the creep state, the pulse interval measured by the pulse interval measurement unit is set to the first value. When the pulse interval is larger than the first predetermined value, the pulse interval measuring means is cleared to maintain the creep state, and when the pulse interval is equal to or less than the first predetermined value, the pulse interval measuring means is compared with the predetermined value. In addition to clearing and shifting to a non-creep state, the power pulse counting means is incremented, and when a pulse is output from the power-frequency conversion means in the non-creep state, the pulse interval measured by the pulse interval measuring means is calculated. When the pulse interval is equal to or less than the second predetermined value and the pulse interval measuring means is cleared to maintain the non-creep state, In both cases, the power pulse counting means is incremented,
When the pulse interval is larger than the second predetermined value, the pulse interval measuring means is controlled so as to clear and shift to the creep state. Therefore, it is possible to realize by a software instead of a circuit. The configuration can be reduced, and downsizing and economy can be achieved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the configuration of an electronic watt-hour meter according to one embodiment of the present invention, FIG. 2 is a state transition diagram showing the operation of the electronic watt-hour meter of FIG. 1, and FIG. A graph in which the axis represents the output frequency of the power-frequency conversion circuit and the vertical axis represents the output pulse of the creep prevention circuit. FIG. 4 is a power-frequency conversion circuit used in the electronic watt-hour meter of FIG. FIG. 5 is a block diagram showing a configuration of a conventional electronic watt-hour meter, and FIG. 6 is a block diagram showing a creep prevention circuit used in the electronic watt-hour meter of FIG. FIG. 3 is a block diagram illustrating a configuration. 1 ... power-frequency conversion circuit 3 ... pulse counter 5 ... CPU 7 ... oscillator 11 ... pulse interval counter 13 ... power pulse counter

Claims (1)

(57) [Claims] A power-frequency conversion means for generating a pulse having a frequency proportional to the power; a pulse interval measurement means for measuring a pulse interval from the power-frequency conversion means; Power pulse counting means for counting a power pulse from which a pulse in a creep state has been removed among the pulses, and a pulse interval measured by the pulse interval measurement means when the power-frequency conversion means generates a pulse in a creep state. Is compared with a first predetermined value,
When the pulse interval is greater than a first predetermined value, the pulse interval measuring means is cleared to maintain the creep state, and when the pulse interval is equal to or less than the first predetermined value, the pulse interval measuring means is cleared. A first control unit that shifts to a non-creep state and increments the power pulse counting unit; and a pulse interval measurement unit that measures a pulse when the power-frequency conversion unit generates a pulse in a non-creep state. The pulse interval is compared with a second predetermined value, and when the pulse interval is equal to or less than the second predetermined value, the pulse interval measuring means is cleared to maintain a non-creep state, and the power pulse counting means is incremented. When the pulse interval is larger than a second predetermined value, the pulse interval measuring means is cleared and the state shifts to a creep state. Electronic electricity meter, characterized in that it comprises a second control means.