The relevant requirements of Annex I, the specific requirements of this Annex and the conformity assessment procedures listed in this Annex, apply to active electrical energy meters intended for residential, commercial and light industrial use.
Electrical energy meters may be used in combination with external instrument transformers, depending upon the measurement technique applied. However, this Annex covers only electrical energy meters but not instrument transformers.
An active electrical energy meter is a device which measures the active electrical energy consumed in a circuit.
I | = | the electrical current flowing through the meter; |
In | = | the specified reference current for which the transformer operated meter has been designed; |
Ist | = | the lowest declared value of I at which the meter registers active electrical energy at unity power factor (polyphase meters with balanced load); |
Imin | = | the value of I above which the error lies within maximum permissible errors (MPEs) (polyphase meters with balanced load); |
Itr | = | the value of I above which the error lies within the smallest MPE corresponding to the class index of the meter; |
Imax | = | the maximum value of I for which the error lies within the MPEs; |
U | = | the voltage of the electricity supplied to the meter; |
Un | = | the specified reference voltage; |
f | = | the frequency of the voltage supplied to the meter; |
fn | = | the specified reference frequency; |
PF | = | power factor = cosφ = the cosine of the phase difference φ between I and U. |
The manufacturer shall specify the class index of the meter. The class indices are defined as: Class A, B and C.
The manufacturer shall specify the rated operating conditions of the meter; in particular:
The values of fn, Un, In, Ist, Imin, Itr and Imax that apply to the meter. For the current values specified, the meter shall satisfy the conditions given in Table 1;
Class A | Class B | Class C | |
---|---|---|---|
For direct-connected meters | |||
Ist | |||
Imin | |||
Imax | |||
For transformer-operated meters | |||
Ist | |||
Imin | a | ||
In | |||
Imax |
The voltage, frequency and power factor ranges within which the meter shall satisfy the MPE requirements are specified in Table 2. These ranges shall recognise the typical characteristics of electricity supplied by public distribution systems.
The voltage and frequency ranges shall be at least:
power factor range at least from cosφ = 0,5 inductive to cosφ = 0,8 capacitive.
The effects of the various measurands and influence quantities (a, b, c,…) are evaluated separately, all other measurands and influence quantities being kept relatively constant at their reference values. The error of measurement, that shall not exceed the MPE stated in Table 2, is calculated as:
When the meter is operating under varying-load current, the percentage errors shall not exceed the limits given in Table 2.
When a meter operates in different temperature ranges the relevant MPE values shall apply.
The meter shall not exploit the MPEs or systematically favour any party.
As electrical energy meters are directly connected to the mains supply and as mains current is also one of the measurands, a special electromagnetic environment is used for electricity meters.
The meter shall comply with the electromagnetic environment E2 and the additional requirements in points 4.2 and 4.3.
The electromagnetic environment and permissible effects reflect the situation that there are disturbances of long duration which shall not affect the accuracy beyond the critical change values and transient disturbances, which may cause a temporary degradation or loss of function or performance but from which the meter shall recover and shall not affect the accuracy beyond the critical change values.
When there is a foreseeable high risk due to lightning or where overhead supply networks are predominant, the metrological characteristics of the meter shall be protected.
a In the case of electromechanical electricity meters, no critical change values are defined for harmonic contents in the current circuits and for DC and harmonics in the current circuit. | |||
Critical change values for disturbances of long duration | |||
---|---|---|---|
Disturbance | Critical change values in percent for meters of class | ||
A | B | C | |
Reversed phase sequence | 1,5 | 1,5 | 0,3 |
Voltage unbalance (only applicable to polyphase meters) | 4 | 2 | 1 |
Harmonic contents in the current circuitsa | 1 | 0,8 | 0,5 |
DC and harmonics in the current circuita | 6 | 3 | 1,5 |
Fast transient bursts | 6 | 4 | 2 |
Magnetic fields; HF (radiated RF) electromagnetic field; Conducted disturbances introduced by radio-frequency fields; and Oscillatory waves immunity | 3 | 2 | 1 |
any output intended for testing the accuracy of the meter does not produce pulses or signals corresponding to an energy of more than the critical change value,
and in reasonable time after the disturbance the meter shall:
recover to operate within the MPE limits, and
have all measurement functions safeguarded, and
allow recovery of all measurement data present prior to the disturbance, and
not indicate a change in the registered energy of more than the critical change value.
The critical change value in kWh is
(m being the number of measuring elements of the meter, Un in Volts and Imax in Amps).
When the voltage is applied with no current flowing in the current circuit (current circuit shall be open circuit), the meter shall not register energy at any voltage between and 1,1 Un.
The meter shall start and continue to register at Un, PF = 1 (polyphase meter with balanced loads) and a current which is equal to Ist.
The electrical energy measured shall be displayed in kilowatt-hours or in megawatt-hours.
The conformity assessment procedures referred to in Article 17 that the manufacturer can choose between are:
B + F or B + D or H1.