Abstract: Load control device, system and method for controlling a state of operation of at least one electrical load by receiving remote load control commands from at least one remote command centre with at least one receiving means of the load control device; and/or generating local load control commands with at least one local control unit of the load control device; and processing a stack of the remote load control commands and/or the local load control commands with at least one command processing unit of the load control device; and implementing an effective load control command containing at least one instruction for the effecting of the load control operations based on the stack for effecting load changing operations influencing the state of operation of the at least one electric load with at least one load interface unit of the load control device based on the at least one instruction.

Abstract: A method of monitoring a functional state of an electricity meter, includes generating at least one temperature signal from which an actual temperature value of the electricity meter can be derived; determining whether the actual temperature value and/or a gradient thereof exceeds at least one threshold value derived from at least one predefined temperature curve representing predefined temperature values of the electricity meter over time according to a modelled thermal behaviour of the electricity meter. Further, a computer program, a computer-readable data carrier having stored thereon a computer program, a data carrier signal carrying a computer program, and an electricity meter configured to carry out the computer program are described. Finally, an electricity metering system, in particular an Advanced Metering Infrastructure, includes at least one electricity meter and/or at least one administration device configured to carry out a method of monitoring a functional state of an electricity meter.

Abstract: A method for manufacturing an enclosure for a utility meter is provided, wherein at least two of a main cover part, an exterior terminal cover part, and an interior terminal cover part are at least partly formed jointly as a cover assembly in an injection moulding device. Further provided is a utility meter with an enclosure manufactured by the method.

Abstract: A conductor connection device with a contact element at one side thereof, a printed circuit board with the conductor connection device, and a utility meter with the printed circuit board are provided. In order to reduce production costs of the conductor connection device without increasing the production costs of the printed circuit board or the utility meter and without affecting operational safety, the conductor connection device comprises a conductor clamping element that is accessible via the second side thereof, and the printed circuit board comprises a through-hole that is aligned with the conductor clamping element.

Abstract: A switching system for an electricity meter, an electricity meter with a switch system and a method of switching switch are provided. In order to improve lifetime of the switch the timing of outputting a switching signal is adjusted based on a time difference between previously outputting the switching signal and achieving a predefined switching state.

Abstract: An enclosure assembly includes a first enclosure portion and a second enclosure portion which in a fully assembled state of the enclosure assembly enclose at least a part of an inner space for accommodating a metering device; and a fixation arrangement for affixing the first enclosure portion to the second enclosure portion in the fully assembled state, wherein the fixation arrangement in a fixation position prevents the first enclosure portion and the second enclosure portion from being separated from each other. The fixation arrangement includes at least one latching element arranged at the first enclosure portion and at least one counter latching element arranged at the second enclosure portion. In the fixation position, the at least one latching element is in engagement with the at least one counter latching element, and a blocking element prevents a disengagement of the at least one latching element and the at least one counter latching element.

Abstract: The present invention relates to a method of determining a reduction of remaining service lifetime of an electrical device during a specific time period. A measurement system is provided comprising a temperature measurement device, a current measurement device and a voltage measurement device. A temperature value, voltage values and current values are measured by using the measurement device. A harmonic load is determined based on the current values. A reduced maximum operating temperature is determined based on the harmonic load. An amount of transient over-voltages is determined based on the voltage values. A transient aging factor is determined based on the amount of transient over-voltages. A temperature dependent aging factor is determined based on the temperature value and the reduced maximum operating temperature. Finally, the reduction of remaining service life is determined based on the specific time period, the transient aging factor and the temperature dependent aging factor.

Abstract: A method of determining a reduction of remaining service lifetime of an electrical device during a specific time period. The method comprising the steps of providing a measurement system comprising a temperature measurement device; a current measurement device and a voltage measurement device; measuring a temperature value, voltage values and current values by using the measurement device; determining a harmonic load based on the current values; determining a reduced maximum operating temperature based on the harmonic load; determining an amount of transient over-voltages based on the voltage values; determining a transient aging factor based on the amount of transient over-voltages; determining a temperature dependent aging factor based on the temperature value and the reduced maximum operating temperature; and determining the reduction of remaining service life based on the specific time period, the transient aging factor and the temperature dependent aging factor.

Abstract: An electronic electricity meter (102) for monitoring electrical power consumption due to a plurality of loads, comprising electric power sensor (506A, 506, 502, 504, 508) configured to register, optionally in a substantially real-time fashion, data indicative of aggregate power demand (202) of a number of loads coupled to a common electrical power source, such as one or more phases of a polyphase system, load tracker (506B, 506, 502, 504) configured to detect the effect of individual loads on the basis of distinctive load patterns in said data, wherein the tracker is configured to utilize a distinctive load pattern detected in said data as at least a basis for a reference pattern (304, 306, 308) for subsequent detections (304a, 306a, 308a) of the effect of the same load in the data, accuracy analyzer (506C, 506, 502, 504) configured to, on the basis of comparisons of subsequent detections with the corresponding references, determine (312, 314, 316) whether the comparisons relating to at least two, preferably

Abstract: In a radio network having a low power consumption—a so-called Low Rate Wireless Personal Area Network (LR-WPAN)—a first network unit is arranged above a first physical transmission unit and a first data link unit connected thereto, a first network link having a first switch having echo suppression based on the Low Rate Wireless Personal Area Network being arranged between the first data link unit and the first network unit, and being connected to a second network link having a second switch having echo suppression based on the Low Rate Wireless Personal Area Network via a subsequent connection structure. In this arrangement, this connection structure connects a second network unit to the first network unit for the purpose of communication based on the Low Rate Wireless Personal Area Network.

Abstract: In an antenna coupler, a multilayer printed-circuit board has conductor levels which are electrically isolated from one another in the depth direction. A first radio-frequency line coupled to the antenna is arranged in a first conductor level, while a second radio-frequency line coupled on the appliance side is arranged in a second conductor level of the board. The board has an electrically insulating core layer, with the first and second conductor levels extending on the same of the two faces of the core layer and with the second radio-frequency line at a greater distance from the core layer than the first radio-frequency line. Furthermore, the second radio-frequency line is arranged on an outer surface of the board. The antenna coupler comprises an electrically conductive shielding structure designed to shield the first radio-frequency line and appliance-side metal parts, which are not part of the antenna coupler, against interaction with radio-frequency signals.

Abstract: In an antenna coupler, a multilayer printed-circuit board has conductor levels which are electrically isolated from one another in the depth direction. A first radio-frequency line coupled to the antenna is arranged in a first conductor level, while a second radio-frequency line coupled on the appliance side is arranged in a second conductor level of the board. The board has an electrically insulating core layer, with the first and second conductor levels extending on the same of the two faces of the core layer and with the second radio-frequency line at a greater distance from the core layer than the first radio-frequency line. Furthermore, the second radio-frequency line is arranged on an outer surface of the board. The antenna coupler comprises an electrically conductive shielding structure designed to shield the first radio-frequency line and appliance-side metal parts, which are not part of the antenna coupler, against interaction with radio-frequency signals.

Abstract: A control apparatus (1) for controlling an electrical load (2) has a housing (28), a plug (12) mounted to the housing (28) for connecting the control apparatus (1) to the power outlet (4), a socket (10) mounted to the housing (28) for connecting the control apparatus (1) to the electrical load (2), and a receiver unit (6) mounted within the housing (28) and coupled to the plug (12) and the socket (10). In use, the receiver unit (6) receives a control signal that is indicative of an impending congestion period. Upon receipt of the control signal, the receiver unit (6) interrupts supply of power to the socket (10) and, hence, switches the electrical load (2) off.

Abstract: The invention relates to a circuit configuration for compensating for the changes in a transfer ratio of a magnetic field sensor arrangement. According to one embodiment of the invention, a control loop for effecting this compensation is provided in the form of an integrated circuit whereby the change in transfer ratio is compensated by means of a control signal variation. This circuit configuration includes a series configuration of an A/D converter, a digital controller and a D/A converter exhibiting high precision and high control speed. A control that is significantly more precise and faster than that of the prior art is achieved by virtue of the fact that only a variable portion of regulating variables is fed through the digital controller after which a constant portion of regulating variables for the actual regulating variable used for compensation is added.

Abstract: A measuring circuit arrangement (1) for an electricity meter for direct connection is respectively connected, to an input (3) for voltage measurement and an input (4) for current measurement of a measuring chip (2) for each phase of a three phase supply. Upstream of the input (3) for voltage measurement is a voltage divider (R1,R2) provided in order to match the voltage level, and upstream of the input (4) for current measurement is a voltage transformer (5) with measuring shunt (RSH) installed according to the invention. The voltage transformer (5) is so arranged that its ohmic resistance towards the measuring shunt (RSH) on the one hand sufficiently limits standard direct-current impingement of the voltage transformer (5) and on the other hand this ohmic resistance is also small enough so that, together with the inductance of the current transformer (5), it displays no more than standard angle error.

Abstract: The invention relates to a compensation circuit for the phase shift between a first input (3) for a voltage determination and a second input (4) for a current determination in electric meters for direct connection, whereby a DC-tolerant converter (5), for current transformation, is arranged before said second input (4) and a high pass filter (R1, C) is arranged before the first input (3), for a first equalisation of the non-frequency-dependant phase compensation. A further equalisation of the phase compensation occurs by means of a correction device (5) in a measuring chip (2), which is connected in series with the inputs (3, 4) for voltage determination and current determination.