FR2741158A1 - COUNTER TESTER CIRCUIT - Google Patents

Abstract

A meter testing circuit for monitoring watt/hour meters. The circuit has a transducer head attachable to the meter and includes an emitter (L1) and two receivers (Q1, Q2) and an indicator which signifies proper positioning of the head relative to the meter. The circuit detects the presence of an index mark on a disk of a mechanical meter or an indicator light on an electronic meter and provides intensity control for the emitter and an output indicative of detection of the mark or light.

Description

 The present invention relates to a counter tester circuit. The invention relates more particularly to a meter tester circuit and a transducer head for determining the operating accuracy of electrical energy meters.

 There are two main types of electrical energy meters used for household and other purposes. A first type of meter is generally with electromechanical operation and is provided with a rotating disc. The disc is provided with an indexing mark and the number of revolutions per unit of time corresponds to the power consumed by the consumer whose premises are supplied by the electrical energy controlled by this counter. The meter is generally provided with a glass cover extending over a front face of the meter through which the disc and other parts of the meter are visible.

 There are a wide variety of meters of this type, and the type of glass cover, the distance between the glass cover and the disc and other structural characteristics vary considerably from one brand of meter to another. In addition, these meters operate under varying ambient conditions such as heat, light and electrical noise.

 Another type of meter is of electronic construction and is equipped with a flashing light or a flashing light-emitting diode (LED) which provides a visual indication of the level of power consumed.

 It is often necessary to record data in order to provide an indication of the power consumed during a predetermined period for testing or monitoring purposes. A known device commonly used for this purpose comprises a transmitter for directing radiation, generally light or infrared radiation, on the indexing mark located on a rotating disc of a counter, and it is provided with a detector which provides then a response each time the presence of the indexing mark is detected. The device output can be connected to a data logger. When the operation of an electronic type meter is monitored, a transmitter is not required in the monitoring or testing device.

 These known devices are bulky and require precise alignment and reliable attachment to the meter tested. This was often difficult to achieve due to the wide variety of physical structural differences between different brands of meters. The transmitter typically emitted uninterrupted and constant light and its operation was affected by variations in ambient conditions.

 It is an object of the present invention to provide a meter tester circuit and a transducer head which minimizes at least the above-mentioned drawbacks.

 In accordance with one aspect of the invention, there is provided a test transducer head for a meter tester circuit, the head having a rear face, a transmitter and a first receiver in the rear face, and d '' a covered receiver sensitive to the effects of ambient conditions in order to be able to suppress at least some of the environmental influences on the signal received by the first receiver, as well as an indicator intended to provide an indication of the moment when the head is correctly locked in alignment with the meter under test.

 According to another aspect, the invention provides a counter tester circuit comprising a transducer head provided with a transmitter and a receiver, a transmitter controller intended to control the intensity of the output of the transmitter in function of the meter under test and of producing pulses at the output of the transmitter as well as a signal processor intended to receive an output signal from the receiver and to determine, from this output signal, the detection of the presence either of an indexing mark on a rotating disc of the counter, or the flashing of an indicator on the counter.

 The transmitter and receiver can transmit and receive radiation of any suitable type. Preferably infrared radiation is used.

The transmitter may include an infrared emitting diode while the receiver may include a phototransistor.

 The covered receiver or blind receiver is a device identical to the previously mentioned receiver, the two receivers being in close proximity to each other so that both are exposed to the same sources of noise. In this way, the first receiver mentioned provides an output in reaction to both the presence of noise and the presence of the detected infrared radiation, while the blind receiver reacts only to noise. The outputs of these receivers can be subtracted from each other to substantially eliminate the effects of noise.

 The head includes an indicator which provides a visual indicator output each time the presence of the indexing indicator or the flashing indicator is detected. This allows easy and precise alignment of the detection head with respect to the meter tested.

 The signal processor preferably includes a high gain amplifier and a differential amplifier. The high gain amplifier amplifies the outputs of the first mentioned receiver and the blind receiver, while the differential amplifier subtracts one of the outputs from the other to reduce the effects of noise.

 The signal processor preferably includes a filter and a circuit for analyzing the filtered output to allow the signal to indicate detection of the presence of the index mark or flashing light on the meter. The processor may include a rectifier, a level maintaining circuit, and a peak and trough detector.

 The transmitter controller not only guarantees that the transmitter provides a pulsed output, it also controls the intensity of the output based on the meter tested. It is thus possible to control the power consumed by the transmitter. The duty cycle of the transmitter pulses is preferably low and generally of the order of 0.8%. The pulse frequency is relatively high compared to the speed of rotation of the rotating disc or the frequency of flashing of the indicator of the electronic counter.

 The processor preferably compares the amplitude of the signal received by the receiver with a reference in order to provide a signal for controlling the intensity of the transmitter.

A particular preferred embodiment of the invention will now be described by way of example in which
Figures 1, 2 and 3 are front, side and rear projection views of a transducer head of an embodiment of the invention
Figure 4 is a block diagram of a meter tester circuit incorporating the transducer head of Figures 1, 2 and 3
Figure 5 is a detailed block diagram of the circuit used in the transducer head
Figure 6 is a detailed block diagram of another part of the detailed circuit used in the block diagram of Figure 4
Figure 7 is a detailed block diagram of another part of the detailed circuit used in the block diagram of Figure 4; and
FIG. 8 is a block diagram of a microprocessor used in the block diagram of FIG. 4.

 Referring to Figures 1, 2 and 3, a transducer head 10 is illustrated. The head 10 has a rear face 11 on which are fixed two suction cups 12, 13 which facilitate the fixing of the head on a glass cover of an electric energy meter.

A radiation emitter and a radiation receiver are located on the rear side and are directed towards the glass cover of the meter on which the head can be fixed. The transmitter and receiver are not shown in these views.

 The head has a cylindrical body 14 and a front face 15. The front face 15 is provided with an indicator, generally a light-emitting diode (LED) 16.

When the head 10 is properly positioned relative to the counter, the LED 16 flashes each time the receiver detects the presence of the indexing mark on a rotating disc of the counter.

When the counter is of the electronic type instead of being fitted with a rotating disc, the receiver can detect the flashing of an indicator on the counter, and when the head is properly aligned with respect to such a counter, the indicator 16 flashes each time the indicator on the meter flashes.

 An electric wire 17 connects the head to the rest of the meter tester circuit.

 Figure 4 shows a block diagram of the meter tester circuit of the invention. The receiver 20, generally a phototransistor with an amplifier, is sensitive to radiation coming from a rotating disc or from an LED indicator of an electric energy meter. The amplified output fixed to the receiver 20 is an indication of the detection of the indexing mark on the rotating disc or of the flashing of an LED on an electronic electric energy meter.

The circuit has two operating modes
1. Mechanical counters
2. Electronic counters
The differential output of the receiver is conditioned by the differential amplifier and the filter 21. The filter is typically a high-pass filter and the output of the filter is applied to a gain control module 22. The output of module 22 is applied to the peak blocking circuit 23 and to the comparator. The output of the peak blocker 23 feeds an analog / digital converter (ADC) 24. The output of the ADC is a digital signal representative of the output of the peak blocker circuit 23.

 The following describes the operation for mechanical counters.

 A comparison is made between the output of the analog / digital converter 24 and a reference signal to control the output of the digital / analog converter 26 for an initial period, to calibrate the circuit on the meter to be tested. The output of the DAC 26 is converted into a pulsed current by the voltage / current converter 27. The converter 27 is activated by the microprocessor 25. The output of the voltage / current converter 27 drives the transmitter circuit 28 with pulses having a typical cyclic ratio 0.8%. The transmitter pulses occur at a frequency significantly higher than the normal rotation speed of the disc in a mechanical electrical energy meter.

 The following describes the operation of an electronic counter.

 The voltage / current converter 27 is deactivated by the microprocessor 25 via an output on the PEO terminal, in order to stop any transmission from the transmitter 28. A comparison is made between the output of the analog / digital converter 24 and a reference which controls the input of the digital / analog converter 26.

 The output of the digital / analog converter 26 is compared to the output of the gain control module 22 by the comparator 29. The PCO output of the microprocessor 25 controls the output amplitude of the gain control module 22. An output of the comparator 29 is applied to the terminal PA2 of the microprocessor 25 where it is compared with programmed thresholds, and the output of the analog / digital converter is applied to the level of the terminal PD2 of the microprocessor 25.

 The microprocessor is programmed to differentiate peaks and valleys of the signal from the receiver and, when the difference between peaks and valleys exceeds a predefined value, an output is provided by the microprocessor on terminal PC3 to signal the detection of '' an index mark on the disc or a flashing signal supplied by an LED on an electronic electric energy meter. This output can be connected to a data logger (not shown).

 Figure 5 illustrates in more detail the circuit used in the transducer head.

The transmitter consists of a light-emitting diode (LED) L1. When the circuit of the invention is used with an electric energy meter provided with a rotating disc, a transmitter of this type is used to direct radiation on the disc. This makes it possible to detect the presence of the indexing mark on the disc each turn of the disc. When the meter tested is an electronic meter fitted with a warning light
LED whose flashing frequency indicates the power consumed, the L1 transmitter is not necessary.

Two receiving phototransistors Q1 and Q2 are used to detect the indexing mark on the rotating disc in a counter or on the flashing LED of an electronic counter. The Q2 receiver is covered and is only sensitive to noise and ambient conditions and other factors not associated with the presence of an indexing marker or a flashing LED. Receivers Q1 and Q2 are linked as shown to provide the SIGL signals and
SIGH which can be subtracted to eliminate the effects of noise. The amplifier UllA is connected to a comparator which derives its inputs from Q1 and Q2 and which controls Q1 so as to prevent it from saturating under ambient light conditions.
U12A and B provide a differential output with low impedance. The output of the follower U12A is high when the transistor Q2 tends to close and the output of the follower Ul2B is low when the transistor Q1 tends to open. The transistor Q3 operates with its associated components as a constant current source, ensuring that the transistors Q1 and Q2 do not open at the same time.

Figure 6 illustrates the outputs of the trackers
U12A and B applied to the respective high-pass filters composed of the capacitor C1 and the resistor R1, and the capacitor C2 and the resistor R2. The outputs of the filters are applied to the differential amplifier U1A. These filters and the amplifier U1A form the block 21 illustrated in FIG. 4. The field effect transistor (FET) TR4 and the amplifier U1B form the gain control block 22 illustrated in FIG. 4. The amplifier U1B has a gain of 10. When the FET TR4 drives, it has a gain of 1/10. The FET TR4 is made conductive by the PCO signal from the microprocessor 25 (see Figure 4).

 The amplifier U2A, the diode D1 and the capacitor C5 act as peak detector and form the peak blocking unit 23 of FIG. 4. The capacitor C10 and the resistor R14 decouple the peak detector from the amplifier U1B. The transistor TR1 is used to periodically discharge the capacitor C5. This occurs when the signal PC1 opens the transistor TR1.

The amplifier U2B is configured as a buffer to connect the output of the peak detector to the analog / digital converter 24 of FIG. 4.

 FIG. 6 illustrates the signal PC2 coming from the microprocessor 25. This signal drives the transistor TR2 to supply a signal called INDLED, intended to control the LED 16 of FIG. 1 in order to indicate that the head 10 has been positioned correctly relative to to a counter. The signal PC3 controls the transistor TR3 to provide an output indicating the detection of the indexing mark on the disk or of a flashing signal supplied by an LED of an electronic electric energy meter.

 U2C is the comparator 29 in FIG. 4. The pinout of connectors 1 and 2, shown schematically in FIG. 6, is illustrated at the bottom left of FIG. 6.

 FIG. 7 illustrates the supply circuits for the meter tester circuit of the invention. The regulator U3 supplies regulated voltages of +10 V and -10 V as illustrated. The US regulator supplies a regulated voltage of -5 V. The regulators U6 and U4 respectively supply a regulated voltage of 10 V and 5 V. The filter capacitors C28, C29, C17, C18 and C19 are associated with the voltage regulators.

Figure 8 illustrates the detail of a U10 microprocessor. A reset signal (RESET) from the microprocessor U10 is provided by the device U8. The amplifier U2D and the transistor TR5 form a voltage / current converter. The inputs PBO to PB7 at resistors R19 and R24 to R31 are derived from the microprocessor U10. This network of resistors forms the digital / analog converter 26 illustrated in FIG. 4. The voltage / current converter is represented by block 27 in FIG. 4. The IRLED output controls the emitting LED L1 in FIG. 5 and provides an output to variable current dependent on the meter tested. The transistor
TR6 is controlled by the PEO input derived from the microprocessor U10, which transistor TR6 controlling the voltage / current converter is made active. In this way, the source is controlled so that the transmitter L1 (figure 5) can be deactivated in order to allow the circuit of the invention to be used with an electronic electric energy meter.

 The microprocessor 25 illustrated in block diagram in Figure 4 and in more detail by U10 in Figure 8 operates as follows. The PEO terminal is connected to a pulling resistance at the +5 V pole. To use the circuit of the invention in mechanical counter mode, the connection of PEO to the FET TR6 is at the +5 V pole and the FET TR6 connects the potential of ground (GND) at one end of the resistor R30 to allow the voltage / current converter to operate. When the PEO terminal is connected to ground potential, TR6 does not conduct and the voltage / current converter is deactivated.

 The operation of the microprocessor is initially calibrated so as to define the amplitude of the depressions (for the mechanical counter mode) and of the peaks (electronic counter mode). The duration of a trough or a crest is defined in the same way. When the microprocessor is then put into operation for a test, only the peaks or troughs located within the desired acquisition thresholds and occurring during the desired periods cause an output at the PC3 terminal for application to a data logger. This information provides an indication of the meter reading accuracy.

Claims (13)

1. transducer head (10) for a meter testing device and a circuit, characterized in that it has a rear face (11), a transmitter and a first receiver in the rear face as well as a second receiver (20) sensitive to the effects of ambient conditions in order to make it possible to suppress at least some of the environmental influences on the signal received by the first receiver, as well as an indicator (16) intended to supply an indication of when the head is correctly locked in alignment on a meter tested. 2. Head according to claim 1, characterized in that the emitter is an infrared light emitting diode and the receivers are identical photodiodes or phototransistors. 3. Head according to claim 1, characterized in that the indicator is a light-emitting diode located on a front face (15) of the head. 4. Head according to claim 1, characterized in that it comprises one or more suction cups (12, 13) on the rear face in order to fix the head (10) on the counter with the rear face (11) directed towards the counter . 5. Meter tester circuit comprising a transducer head according to any one of claims 1 to 4, characterized in that it additionally comprises a circuit intended to supply a DC signal whose amplitude is indicative of the signal in from the first receiver and a microprocessor (25) capable of operating so as to select the operation of the test circuit, in order to test a mechanical counter when the transmitter is activated and that its intensity is controlled, and in order to deactivate the transmitter for test an electronic meter. 6. Counter tester circuit according to claim 5, characterized in that the microprocessor (25) operates so as to detect the dips indicating the detection of an indexing mark on a rotating disc of the mechanical counter and the peaks indicating an indication visual of an electronic meter, detecting dips or peaks occurring during a predetermined period. 7. Meter tester circuit according to claim 6, characterized in that the microprocessor (25) provides an output intended to be connected to a data recorder. 8. Meter tester circuit according to claim 6, characterized in that it comprises a filter (21) and an amplifier connected to the first receiver and to the second receiver, the output of the second receiver being thus subtracted from the output of the first receiver in the amplifier to reduce the effects of noise and environmental conditions on the first receiver. 9. Counter tester circuit according to claim 8, in which the output of the amplifier is connected to a gain control module (22), the gain of which is controlled by the microprocessor. 10. Meter tester circuit according to claim 9, comprising a peak blocking circuit (23) connected to the gain control module (22) in order to supply the DC signal. 11. Meter tester circuit according to claim 10, comprising an analog / digital converter (24) in order to convert the DC signal into a digital signal and to connect the digital signal to the microprocessor (25). 12. Meter tester circuit according to claim 11, comprising a digital / analog converter (26) controlled by the microprocessor and connected to the transmitter in order to control the intensity of the output of the transmitter. 13. Meter tester circuit according to claim 12, in which the output of the DAC is compared with the output of the gain control module in a comparator and the output of the comparator is connected to the microprocessor (25) and compared with thresholds programmed to allow to adjust the intensity of the transmitter.