GB1569087A

GB1569087A – Meter for recording consumption of electrical energy
– Google Patents

GB1569087A – Meter for recording consumption of electrical energy
– Google Patents
Meter for recording consumption of electrical energy

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Publication number
GB1569087A

GB1569087A
GB9550/78A
GB955078A
GB1569087A
GB 1569087 A
GB1569087 A
GB 1569087A
GB 9550/78 A
GB9550/78 A
GB 9550/78A
GB 955078 A
GB955078 A
GB 955078A
GB 1569087 A
GB1569087 A
GB 1569087A
Authority
GB
United Kingdom
Prior art keywords
digital
signal
analog
proportional
voltage
Prior art date
1977-04-18
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Expired

Application number
GB9550/78A
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Allen Bradley Co LLC

Original Assignee
Allen Bradley Co LLC
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1977-04-18
Filing date
1978-03-10
Publication date
1980-06-11

1978-03-10
Application filed by Allen Bradley Co LLC
filed
Critical
Allen Bradley Co LLC

1980-06-11
Publication of GB1569087A
publication
Critical
patent/GB1569087A/en

Status
Expired
legal-status
Critical
Current

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Classifications

G—PHYSICS

G01—MEASURING; TESTING

G01R—MEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES

G01R21/00—Arrangements for measuring electric power or power factor

Description

PATENT SPECIFICATION ( 11) 1 569 087
t 17 ( 21) Application No 9550/78 ( 22) Filed 10 Mar 1978 ( 19) _ y ( 31) Convention Application No 788111 ( 32) Filed 18 Apr 1977 in,A ( 33) United States of America (US)
( 44) Complete Specification Published 11 Jun 1980
1 I) ( 51) INT CL 3 GOIR 21/06 Y ( 52) Index at Acceptance G 1 U BE ( 54) METER FOR RECORDING CONSUMPTION OF ELECTRICAL ENERGY ( 72) We, ALLEN-BRADLEY COMPANY, a Company organized and existing under the laws of the State of Wisconsin, United State of America of 1201 South Second Street, Milwaukee, Wisconisn 53204, United States of America, do hereby declare the invention, for which we pray that a Patent may be granted to us, and the method by which it is to be performed, to be particularly described in and by the following statement: 5
This invention relates to meters for recording consumption of electrical energy.
hr nf known wattmeters and watt-hour meters constructed of solid state -the, magnitude of the voltage (E) and the -anl oroportional to l ERRFATUM SPECIFICATION NO 1569087
Page, line 16,after Patent delete NO 3/8, 7 &, & /8 insert No 3,794917 THE PATENT OFFICE 7 & 1/8 7/8 insert No3,794,917 515 July 1980 Bas 77376/I 9 which generates an outpu L “b circuit, said output signal being converted in t _ frequency proportional to the magnitude of said product the pulses U Ci, a_ subtracted from a pulse count in a counter of the meter in dependence upon the polarity of 23 the said product, whereby the count in the counter is representative of the electrical energy consumed.
According to another aspect of the invention a meter for recording the electrical energy flowing through a set of power lines comprises means for sensing the current flowing in said power lines and generating a signal whose amplitude is proportional thereto; means for 30 sensing the voltage across said power lines and generating a signal whose amplitude is proportional thereto; multiplier means connected to receive at input terminals the signals generated by said current and voltage sensing means said multiplier means being operable to generate an analog output signal whose magnitude is proportional to the product of the amplitude of the signals applied to its input terminals: polarity detector means having an 35 input terminal connected to receive the analog output signal from said multiplier means and being operable to generate a digital output signal the polarity of which corresponds with the polarity of the analog signal applied to its input terminal: converter means having an input terminal coupled to receive the analog output signal from said multiplier means, said analog-to-digital converter means being operable to generate digital pulses at an output 40 terminal at a rate which is proportional to the absolute magnitude of the analog signal applied to its input terminal; and a digital counter connected to the outputs of said polarity detector means and said analog-to-digital converter means, said digital counter being operable to store a number which represents the sum of the digital pulses generated by said analog-to-digital converter means when the output of said polarity detector means has one 45 PATENT SPECIFICATION ( 11) 1 569 087 t ( 21) Application No 9550/78 ( 22) Filed 10 Mar 1978 ( 19), o ( 31) Convention Application No 788111 ( 32) Filed 18 Apr 1977 in /.
( 33) United States of America (US) 4 ( 44) Complete Specification Published 11 Jun 1980 ( ‘
UI} ( 51) INT CL 3 GOIR 21/06 $ ( 52) Index at Acceptance G 1 U BE ( 54) METER FOR RECORDING CONSUMPTION OF ELECTRICAL ENERGY ( 72) We, ALLEN-BRADLEY COMPANY, a Company organized and existing under the laws of the State of Wisconsin, United State of America, of 1201 South Second Street, Milwaukee, Wisconisn 53204, United States of America, do hereby declare the invention, for which we pray that a Patent may be granted to us and the method by which it is to be performed, to be particularly described in and by the following statement: 5
This invention relates to meters for recording consumption of electrical energy.
There are a number of known wattmeters and watt-hour meters constructed of solid state electronic components Such meters sense the magnitude of the voltage (E) and the magnitude of the current (I) and multiply them together to provide a signal proportional to their product (EI) However, the power factor (cos 0, where O is the phase angle between 10 the voltage and current waves) is not always taken into consideration in such meters and is instead assumed to be one This is often not the case particularly in industrial situations where large numbers of reactive load devices are employed The accuracy of these prior meters thus leaves much to be desired.
A watts transducer constructed of solid state devices which does take into consideration 15 the power factor is disclosed in U S Patent NO -/s 7/8 &’/2 ‘& 7/ According to one aspect of the present invention there is provided a meter for recording consumption of electrical energy in a circuit, the meter comprising a current sensor for generating a first signal the amplitude of which is proportional to the current in the circuit, a voltage sensor for generating a second signal the amplitude of which is proportional to the 20 voltage across the circuit, and a multiplier to which the first and second signals are fed and which generates an output signal representing the product of the current and voltage in the circuit, said output signal being converted in the meter into a pulse train having a pulse frequency proportional to the magnitude of said product the pulses being added to or subtracted from a pulse count in a counter of the meter in dependence upon the polarity of 25 the said product, whereby the count in the counter is representative of the electrical energy consumed.
According to another aspect of the invention a meter for recording the electrical energy flowing through a set of power lines comprises means for sensing the current flowing in said power lines and generating a signal whose amplitude is proportional thereto; means for 30 sensing the voltage across said power lines and generating a signal whose amplitude is proportional thereto; multiplier means connected to receive at input terminals the signals generated by said current and voltage sensing means said multiplier means being operable to generate an analog output signal whose magnitude is proportional to the product of the amplitude of the signals applied to its input terminals: polarity detector means having an 35 input terminal connected to receive the analog output signal from said multiplier means and being operable to generate a digital output signal the polarity of which corresponds with the polarity of the analog signal applied to its input terminal: converter means having an input terminal coupled to receive the analog output signal from said multiplier means, said analog-to-digital converter means being operable to generate digital pulses at an output 40 terminal at a rate which is proportional to the absolute magnitude of the analog signal applied to its input terminal; and a digital counter connected to the outputs of said polarity detector means and said analog-to-digital converter means said digital counter being operable to store a number which represents the sum of the digital pulses generated by said analog-to-digital converter means when the output of said polarity detector means has one 45 -3 2 1 569087 polarity minus the digital pulses generated by the analog-to-digital converter means when the output of said polarity detector means has the opposite polarity The present invention relies on the use of a watt-second transducer circuit which generates a digital number in the counter that indicates total energy consumed Total 5 energy (E) is defined as follows: 5 T E = f e(T(I(t)dt 0 O 10 O 10 where: e(t) = instantaneous value of sensed voltage.
i(t) = instantaneous value of sensed current 15 and T = time interval during which energy is measured 15 If the current and voltage are in phase (power factor = I) their product e(t)i(t) will always be positive and the above equation is solved by calculating the area under the curve P(t) = e(t)i(t) When current and voltage are not in phase however the product P(t) will be 20 negative during part of the cycle The above equation is then solved by subtracting the area 20 under the negative part of the curve P(t) from the area under the positive part of the curve P(t).
The preferred embodiment of the present invention provides a reliable transducer which 25 will generate an accurate indication of the electrical energy consumed during a time period.
The circuit of the preferred embodiment measures energy consumed during a time interval 25 as defined by the above equation, and it thus takes into consideration the power factor The circuit is constructed primarily of solid state components which are relatively inexpensive and highly reliable The preferred meter provides a digitall readout of the total energy 30 consumed The total energy is stored Ias a digital number in a counter and this can be decoded and coupled directly to a visual display 30 A meter forming a preferred embodiment of the invention will now be described by way of example, with reference to the accompanying drawings in which:Figure 1 is a block diagram of the meter.
Figures 2 a to 2 e are waveforms which appear at various points in the meter of Figure 1, and 35 Figures 3 and 4 are electrical circuit diagrams of the meter of Figure 1.
Referring to Figures 1 and 2, the preferred meter includes a voltage sensor I which is coupled to the power lines and generates an analog signal e(t) fed to one input of a multiplier 2 A current sensor 3 is also connected to the power lines and generates an analog signal i(t) fed to a second input on the multiplier 2 The signal c(t) is proportional to the 40 instantaneous value of the voltage across the power lines and such signal is illustrated by the sine wave in Figure 2 a The signal i(t) is proportional to the instantaneous value of the current flowing in the power lines and it is illustrated by the sine wave in Figure 2 b The multiplier 2 generates an analog signal at its output which is proportional to the product, 45 P(t), of the two applied input signals e(t) and i(t) This output signal P(t) is illustrated by the 45 sine wave in Figure 2 c and it is applied both to the input of an absolute value circuit 4 and to the input of a polarity detector 5 The absolute value circuit 4 full-wave rectifies the applied signal P(t) to invert any negative portions thereof The resulting signal lP(t)i is illustrated 50 by the waveform in Figure 2 d and it is applied to the input of a voltageto-frequency (V/F) converter 6 The polarity detector 5 is a high gain amplifier whose output saturates at a logic 50 high voltage when the applied waveform P(t) is negative and saturates at a logic low voltage when the applied waveform P(t) is positive This resultin L waveform S(t) is applied to the up/down terminal of a digital counter 7.
The voltage-to-frequency converter 6 generates a pulse train which is fed to the clock terminal of the dieital counter 7 The rate (i e the frequency) at which such pulses are 55 generated is directly proportional to the amplitude of the applied analog signal l P(t)l Each pulse clocks the digital counter 7 and the digital number stored in the counter is either incremented or decremented one count depending on the polarity of the signal S(t) applied to the counter up/down terminal The stored count is incremented by a received pulse when 60 the signal S(t) is negative and the count is decremented by a received pulse when the signal 60 S(t) is positive Each pulse generated by the V/F converter 6 represents an increment of area under the curve defined by the signal lP It)I The total count in the digital counter 7 is the sum of the pulses which are generated whenl the product signal P(t) is positive minus the total number of pulses which are generated when the signal P(t) is negative The digital 65 number in the counter 7 thus represents the net positive area beneath the curve P(t) and is 65 3 1 569 0873 2 proportional to the total consumed energy This number is coupled to a display 8 which provides a visual indication of the electrical energy which has been consumed.
A more detailed description of the above described elements of the meter will now be made with reference to Figures 3 and 4 Referring particularly to Figure 3, the voltage sensor 3 includes a transformer 10 which has its primary winding connected across power 5 lines 11 and a secondary winding which has one terminal connected to signal ground A parasitic suppression network comprised of a resistor 12 and a capacitor 13 is connected across the secondary winding of the transformer 1 ( 1 a bias resistor 14 is connected in parallel with the parasitic suppression network, and the free lead on the secondary winding of the transformer 10 is connected to a Y input on a four-quadrant multiplier 15 which 10 forms part of the multiplier circuit 2.
The current sensor 3 includes a current transformer 16 having a secondary winding which is magnetically coupled to one of the power lines 11 One terminal on the winding of the transformer 16 is connected to signal ground and its other terminal is connected to an X input on the four-quadrant multiplier 15 A parasitic suppression network comprised of 15 resistor 17 and capacitor 18 is connected across the current transformer secondary winding 16 and a bias resistor 19 is connected in parallel therewith.
The main elements of the multiplier circuit 2 are the four-quadrant multiplier 15 and an operational amplifier 20 The four-quadrant multiplier 15 generates a current at an output terminal 21 which is proportional in magnitude to the product of the voltages applied to the 20 X and Y inputs This output terminal 21 is connected to the inverting input on the operational amplifier 20 and through a feedback resistor 22 to the output of the amplifier The operational amplifier 20 serves as a current-to-voltage converter, and it generates an analog voltage at its output 23 which is proportional to the magnitude of the product of the voltages applied at the X and Y inputs of the four-quadrant miultiplier 15 25 The voltage gain of the multiplier 2 is determined in part by a pair of resistors 24 and 25 which are connected to terminals on the four-quadrant multiplier 15 and in part by the feedback resistor 22 The voltage at the operational amplifier output terminal 23 is given by the following expression:
30 2 R 22 e(t)i(t) P(t) = Kle(t)i(t) R 24 R 25 ( 5 x 10-3) where: K = scale factor = 1/1 ( O in the preferred embodiment 35 Three potentiometers 26, 27 and 28 are connected to the four-quadrant multiplier 15 to provide offset adjustments for the X and Y inputs and the output 21 The wiper on the potentiometer 28 is connected to the non-inverting input on the operational amplifier 20 and it is adjusted to provide zero voltage output at the terminal 23 when zero voltage is 40 applied to both the X and Y inputs The wiper on potentiometer 27 is adlusted to provide zero current at output terminal 21 when zero voltage is applied to the X input and a five-volt peak-to-peak sine wave is applied to the Y input The wiper on the potentiometer 26 is adjusted to provide zero current at the output terminal 21 when zero voltage is applied to the Y input and a five-volt peak-to-peak sine wave is applied to the X input 45 The four-quadrant multiplier 15 is an integrated circuit such as the Model MIC 1594 L commercially available from Motorola, Inc For a more detailed description of this device and the multiplier 2, reference is made to The Secii-Coutlttctor Darta Library Series A, Volume VI, published by Motorola Inc in 1975.
Referring to Figure 3, the polarity detector 5 includes an operational amplifier 3 ( 1 having 50 its inverting input coupled through a resistor 31 I to the output 23 of the multiplier operational amplifier 20 The non-inverting input on the operational amplifier 30) is connected to signal ground through a resistor 32 and its output terminal is connected to the base of an NPN transistor 33 through a resistor 34 The emitter of transistor 33 is connected to signal ground and its collector is connected to a positive d-c supply terminal 35 through a 55 load resistor 36 The collector of transistor 33 is also connected to an inverting Schmitt trigger 37.
Without feedback the voltage gain of the operational amplifier 3 ( 1 is exceedingly high with the result that its output saturates at either the positive or negative supply terminal voltage depending on the polarity of the signal applied to its inverting input The transistor 33 is 60 driven by the operational amplifier 30 ( 1 and is thus switchied on and off in response to polarity changes in the waveform P(t) applied to the input of the operational amplifier 3 ( O The transistor 33 drives the Schmitt trieler 37 which in addition to inverting the logic level applied to its input, serves to filter out momentary changes in logic state clue to noise.
The absolute value circuit 4 includes a first operational amplifier 40) and a second 65 1 569 087 4 1 569 087 4 operational amplifier 41 The inverting input on the first operational amplifier 4 ( O is connected to the multiplier output through a coupling resistor 42 and its noninverting input is connected to signal ground through a resistor 43 A feedback network, comprised of a resistor 44 and two diodes 45 and 46, connects the output of the operational amplifier 40 to its inverting input, and the cathode of diode 46 is connected through a coupling resistor 47 5 to the inverting input on the second operational amplifier 41 The inverting input on the second operational amplifier 41 is also connected to the output of the multiplier 2 through a coupling resistor 48 and its noninverting input is connected to signal ground through a resistor 49 A feedback resistor 50 connects the output of the second operational amplifier 41 to its inverting input The output of the amplifier 41 serves as the output of the absolute 10 11 value circuit 4.
When the output waveform P(t) generated by the multiplier 2 is positive, the diode 45 in the feedback network of the first operational amplifier 4 ( O is forward biased As a result, the output of the first operational amplifier 40 is held at virtual ground and no signal is coupled through the coupling resistor 47 The positive portion of the waveform P(t) is coupled 15 1 through the resistor 48 to the second operational amplifier 41 where it is inverted and generated at its output terminal The values of the coupling resistor 48 and the feedback resistor 50 are identical so that unity gain is achieved during positive portions of the applied waveform P(t) When the output waveform P(t) of the multiplier 2 goes negative, however, the diode 45 in ihe feedback network for the first operational amplifier 4 ( O becomes reverse 20 2 ( biased and the feedback resistor 44 becomes effective The values of the coupling resistor 42 and the feedback resistor 44 are identical and the gain of the first operational amplifier 40 is, therefore, unity The signal appearing at the cathode of diode 46 is an inversion of the input signal P(t) and it is applied to the second operational amplifier 41 through the coupling resistor 47 The value of coupling resistor 47 is one-half that of the feedback 25 2 ‘ resistor 50, and as a consequence, when summed at the inverting input of amplifier 41 with the signal of opposite polarity coupled directly through the resistor 48 it predominates The net result is that the negative going portions of the applied waveform P(t) appear at the output of the second operational amplifier 41 with the same polarity and magnitude The applied waveform P(t) is effectively full-wave rectified withouit the creation of any 30 3 ( “deadband” around zero volts which might otherwise occur if a bridge rectifier circuit were employed.
Referring to Figure 4, the V/F converter 6 is a precision voltage-tofrequency converter which includes a voltage-to-frequency converter (VFC) circuit 51 and an operational amplifier 52 The VFC 51 is an integrated circuit such as the model RM 4151 commercially 35 35 available from Raytheon Semiconductor and the Operational amplifier is a model RC 4131 also commercially available from Raytheon Semiconductor The signal lP(t)I from the absolute value circuit 4 is applied to inputs on the VFC 51 and operational amplifier 52 through a coupling resistor 53 The output of the operational amplifier 52 is coupled through a resistor 54 to a second input 55 on the VFC 51 and a feedback circuit comprised 40 40 of diode 56 and capacitor 57 connects the output of the amplifier 52 to the inverting input of the amplifier 52 The non-inverting input on the operational amplifier 52 is connected to signal ground through a resistor 58 and an offset adjust potentiometer 59 is connected to offset adjustment terminals on the amplifier 52 Thle operational amplifier circuit serves to integrate the applied waveform IP(t)l and to maintain input 60 ( on the VFC 51 at zero volts 45 45 to improve linearity of the conversion.
The VFC 51 is connected to positive d-c supply terminals 61 and 62 and to signal ground through resistors 63-66 and a capacitor 67 A full scale trim potentiometer 68 also connects the VFC 51 to signal ground An output terminal 69 on the VFC 51 serves as the output of the V/F converter 6 and it is connected to a clock terminal 7 ( O on the digital counter 7 The 50 50 frequency (f,) of the pulse train generated at the output terminal 69 is proportional to the amplitude of the voltage lP(t)l applied to coupling resistor 53 and is defined by the following equation:
f, = KlP(t)l K Hz 55 55 The duration of each pulse is determined by the values of capacitor 67 and resistor 66 (t = 1.1 R(,,C 67) The potentiometer 68 is adjusted to provide a 10 K Hz output when IP(t)l has a value of 10 volts and the potentiometer 59 is adjusted to provide an output of 10 (Hz when l(P(t)l has a value of 1 Om V For a more detailed description of the V/F converter 6 60 60 reference is made to R My 4 151 data sheet publislhed 1 W Rax theon Semiconductor.
The digital counter 7 includes a plurality of commercially available BCD up/down counters which are interconnected to form a counter 71 Pulses from the V; F converter 6 are received at a common clock terminal 7 ( O and a common up/down\l terminal 73 is connected through a lead 74 to the output of the polarity detector 5 The counter 71 is 65 65 4 5 1 569 087 5 comprised of four or more cascade connected four-bit counters such as the model MC 14510 B commercially available from Motorola Semiconductor, Inc Their preset inputs are connected to signal ground and the “carry out” terminal 75 on the last four-bit counter is coupled through an inverter gate 76 and an OR gate 77 to the common preset enable 5 terminal 78 on the counter 71 A reset pushbutton 79 connects a positive d-c supply terminal 5 to a second input on the OR gate 77, and when depressed, the counter 71 is preset to zero It should be apparent that larger counters may be desirable in applications where the total energy consumption is to be measured over long periods of time.
The sixteen most significant digit outputs on the counter 71 are connected through a cable 10 81 to four BCD-to-seven-segment decoder/driver circuits 82 This circuit is comprised of 10 four integrated circuits such as the model MC 1451 l B which is commercially available from Motorola Semiconductor, Inc The output terminals of each of the four integrated circuits are connected through a cable 83 to the input circuit of a seven segment display circuit 84.
Seven segment displays such as the model 5082-773 () which is commercially available from 15 Hewlett-Packard Inc can be employed, and it should be apparent tfiat any number of these 15 may be employed with a corresponding number of decoder/drivers 82 to provide the desired resolution.

Claims (7)

WHAT WE CLAIM IS:-

1 A meter for recording consumption of electrical energy in a circuit, the meter 20 comprising a current sensor for generating a first signal the amplitude of which is 20 proportional to the current in the circuit, a voltage sensor for generating a second signal the amplitude of which is proportional to the voltage across the circuit and a multiplier to which the first and second signals are fed and which generates an output signal representing the product of the current and voltage in the circuit, said output signal being converted in 25 the meter into a pulse train having a pulse frequency proportional to the magnitude of said 25 product, the pulses being added to or subtracted from a pulse count in a counter of the meter in dependence upon the polarity of the said product, whereby the count in the counter is representative of the electrical encrgyv consumed.

2 A meter for recording the electrical energy flowing through a set of power lines, 30 comprising means for sensing the current flowing in said power lines and generating a signal 30 whose amplitude is proportional thereto: means for sensing the voltage across said power lines and generating a signal whose amplitude is proportional thereto: multiplier means connected to receive at input terminals the signals generated by said current and voltage sensing means, said multiplier means being operable to generate an analog output signal 35 whose magnitude is proportional to the product of the amplitude of the signals applied to its 35 input terminals; polarity detector means having an input terminal connected to receive the analog output signal from said multiplier means and being operable to generate a digital output signal the polarity of which corresponds with the polarity of the analog signal applied to its input terminal; 40 converter means having an input terminal coupled to receive the analog output signal 40 from said multiplier means said analog-to-digital converter means being operable to generate digital pulses at an output terminal at a rate which is proportional to the absolute magnitude of the analog signal applied to its input terminal: and a digital counter connected to thile outputs of said polarity detector means and said 45 analog-to-digital converter means, said digital counter being operable to store a number 45 which represents the sum of the digital pulses generated by said analo,to-digital converter means when the output of said polarity detector means has one polarity minus the digital pulses generated by the analog-to-digital converter means when the output of said polarity detector means has the opposite polarity.
50

3 A meter according to claim 2, wherein the converter means includes an absolute 50 value circuit which full-wave rectifies the analog output signal received from said multiplier means and a voltage to frequency converter circuit which generates said digital pulses in response to the magnitude of the full-wave rectified signal.

4 A meter according to claim 2 wherein display means is coupled to said digital 55 counter and is operable to display said stored number in digital form 55 A meter for recording the electrical energy flowing through a set of power lines, comprising:
a current sensor connected to one of said power lines and being operable to generate a current signal i(t) whose amplitude is proportional to the instantaneous amplitude of the 60 current flowing in said one power line: 60 a voltage sensor connected across a pair of said power lines and bcing operable to generate a voltage signal e(t) whose amplitude is proportional to the instantaneous amplitude of the voltage across said pair of power lines:
a multiplier connected to receive said current signal i(t) and said voltage signal e(t) and 65 being operable to generate an analog output signal P t) which is proportional to the product 65 6 6 6 1 569 087 6 of said current signal i(t) and said voltage signal e(t):
a polarity detector circuit connected to receive the multiplier analog output signal P(t) and generate digital output signal S(t) which has one logic state when the analog output signal P(t) is positive and the opposite logic state when the analog output signal P(t) is negative;

5 an absolute value circuit connected to receive the analog output signal P(t) and being operable to full-wave rectify that signal to generate an analog output signall lP(t)I of one polarity; an analog-to-frequency converter circuit connected to receive said analog output signal lP(t)l and being operable to generate a digital pulse train the frequency of which is 10 proportional to the magnitude of the applied analog signal lP(t)l; and a digital up/down counter connected to receive at an input terminal the digital pulse train generated by said analog-to-frequency converter circuit and connected to receive at an up/down terminal the digital output signal S(t) from said polarity detector circuit, said digital up/down counter being operative to accumulate and store as a digital number the 15 total number of pulses received at its input terminal when the digital signal S(t) applied to its up/down terminal is in one logic state and to subtract from said stored digital number the total number of pulses received at its input terminal when the digital signal S(t) has the opposite polarity.

6 A meter according to Claim 5, wherein a digital display is connected to said digital 20 up/down counter and displays a number which is representative of the digital number stored in said up/down counter.

7 A meter for recording consumption of electrical energy, the meter being constructed and arranged substantially as herein particularly described with reference to the accompanying drawings 25 HUSTWITT & CO.
Chartered Patent Agenits.
Ludaltc House.
1 1 ( Fleet Street 30 London EC 4 A 2 AB.
Printed for Her Majeslyhs Stationcr) Office by Croydon Printing Company Limited Croydon, Surrey, 1980.
Publiched by The Patent Office, 25 Soulhampton Buildings London WC 2 A l AY from which copies may be obtained.

GB9550/78A
1977-04-18
1978-03-10
Meter for recording consumption of electrical energy

Expired

GB1569087A
(en)

Applications Claiming Priority (1)

Application Number
Priority Date
Filing Date
Title

US05/788,111

US4079313A
(en)

1977-04-18
1977-04-18
Digital watts transducer

Publications (1)

Publication Number
Publication Date

GB1569087A
true

GB1569087A
(en)

1980-06-11

Family
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Application Number
Title
Priority Date
Filing Date

GB9550/78A
Expired

GB1569087A
(en)

1977-04-18
1978-03-10
Meter for recording consumption of electrical energy

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US
(1)

US4079313A
(en)

CA
(1)

CA1084116A
(en)

DE
(1)

DE2815253A1
(en)

FR
(1)

FR2388282A1
(en)

GB
(1)

GB1569087A
(en)

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Appalachian Technologies Corporation
Electronic thermal demand module

GB2221313B
(en)

*

1988-07-26
1993-02-24
Omega Electric Ltd
Instantaneous multiplier for use in power measurement systems

ES2040012T3
(en)

*

1989-12-14
1993-10-01
Landis & Gyr Business Support Ag

PROVISION FOR THE DETERMINATION OF VALUES OF ELECTRICAL MAGNITUDES, WHICH CAN BE DEDUCTED FROM MEASURING VALUES OF AT LEAST TWO ELECTRICAL MAGNITUDES OF ENTRY OF THE DISPOSITION.

US5164660A
(en)

*

1991-08-12
1992-11-17
Shell Oil Company
True, power, RMS current, and RMS voltage measuring devices

CN1314971C
(en)

*

2003-06-04
2007-05-09
重庆电力科学试验研究院
Power electric energy meter of 1/4 digital squre multiplier

JP6152969B2
(en)

*

2013-03-27
2017-06-28
パナソニックIpマネジメント株式会社

Power meter

Family Cites Families (3)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US3470471A
(en)

*

1968-05-31
1969-09-30
Canadian Patents Dev
Polarity coincidence correlation method and apparatus for measuring electrical energy

US3794917A
(en)

*

1972-03-09
1974-02-26
Esterline Corp
Electronic watt transducer

US3976941A
(en)

*

1974-09-13
1976-08-24
General Electric Company
Auto-ranging system for an electronic energy meter

1977

1977-04-18
US
US05/788,111
patent/US4079313A/en
not_active
Expired – Lifetime

1977-12-08
CA
CA292,685A
patent/CA1084116A/en
not_active
Expired

1978

1978-03-10
GB
GB9550/78A
patent/GB1569087A/en
not_active
Expired

1978-04-08
DE
DE19782815253
patent/DE2815253A1/en
not_active
Withdrawn

1978-04-12
FR
FR7810767A
patent/FR2388282A1/en
active
Granted

Also Published As

Publication number
Publication date

CA1084116A
(en)

1980-08-19

FR2388282B3
(en)

1980-11-28

US4079313A
(en)

1978-03-14

DE2815253A1
(en)

1978-10-19

FR2388282A1
(en)

1978-11-17

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Legal Events

Date
Code
Title
Description

1980-08-28
PS
Patent sealed [section 19, patents act 1949]

1986-11-12
PCNP
Patent ceased through non-payment of renewal fee

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