DE19600188A1 - Influencing instantaneous power relationship of individual user of user group - Google Patents

Abstract

A correction operation of the switching programme results only with this particular individual user, when the reference limit is exceeded, using a radio control receiver. The reference limit value can be remotely programmed at any time by means of the radio control. The instantaneous power reference of the individual user (7) is represented by a pulse sequence, the frequency of which at any time is proportional to the instantaneous power reference of the individual user. The pulse time intervals of the pulse sequence are compared with a time limit value corresp. to the reference limit value. With a failure to reach this limit value, the correction operation results.

Description

The invention relates to a method for influencing an instantaneous power reference of an individual consumer of a consumer group and on an arrangement for implementation 5. of the method according to the preamble of claims 1 and 5 respectively.

The method and arrangement is preferably used in those countries where a Access to the home of consumers for representatives of an energy supply company is prohibited or even prohibited. Devices of energy supply companies, such as B. Electricity meters and / or ripple control receivers are therefore outside the household arranged, e.g. B. on an outer wall of a building, where it is for the representatives of Power companies are easily accessible. In the event of a temporary Overloading the electrical power grid is known to occur in these countries electrical installations of a consumer each with a thermomagnetic To provide overcurrent switch, which serves as a fuse replacement and one controlled by him Power contactor the electrical power consumption of the consumer in case of overload switches off. The overcurrent switch is usually also outside the household assembled. If the power consumption of the All or part of the consumer is switched off by the overcurrent switch Household residents each after switching off certain electrical loads, e.g. B. one Hot water boilers, turn the overcurrent switch on again by hand, which is what you do Rarely switching off is reasonable, but unacceptable and impractical when switching off frequently is.

The use of ripple control for the purpose of a common global is also known Switching off at certain times of the day for certain consumer groups, such as B. a neighborhood, a Group of single-family houses, factory areas, etc., to avoid network overload. The These consumer groups are either switched off immediately upon receipt of a corresponding one Ripple control command or recently, when using modern ripple control receivers, delayed. In the latter case, the value can generally apply to a group of consumers Time delay remotely programmed from a control center using ripple control and the Network needs to be adjusted in each case. Associated ripple control receivers can thus be programmed that with a simultaneous switch on z. B. the hot water boiler all Consumers of a consumer group are switched off globally together. This has the disadvantage that those consumers in the consumer group who did not use too much power, too be switched off and also on the use of at least part of their electrical Installations have to do without.  

The invention has for its object a method and an arrangement of the aforementioned realizing that allows utilities to consume electricity. Introduce tariff that, depending on the current situation, allows the purchase of electrical Energy and / or performance of the individual consumer of a consumer group individually restrict without a consumer himself having to take any action.

The above-mentioned object is achieved by the characterizing part of claim 1 and 5 respectively specified features solved. Advantageous embodiments of the invention result from the dependent claims.

An embodiment of the invention is shown in the drawing and will be described in more detail below described. The only figure in the drawing shows a basic block diagram of a arrangement according to the invention.

The arrangement according to the invention shown in the drawing contains an electricity meter 1 and a ripple control receiver 2 , the two inputs of which are fed by an electrical power supply network 3 and both of which, for. B. are mounted on an outer wall of a building. The power supply system 3 supplies via the electricity meter 1, a first electric load 4, and downstream of a the electricity meters 1 switch contact 5 b of a contactor 5, a second electric load 6 of a common consumer. 7 The latter is part of a consumer group which is provided with the same information by the ripple control and whose electrical loads 4 and 6 are thus all switched on or off simultaneously without the arrangement according to the invention. A coil 5 a of the contactor 5 is fed from a current output 1 a of the electricity meter 1 via a relay contact 8 b of an output relay 8 of the ripple control receiver 2 . The output relay 8 is, for. B. a bistable relay, the relay contact 8 b z. B. is a changeover contact. The current output 1 a of the electricity meter 1 , to which the electrical loads 4 and 6 are directly or indirectly connected via the switch contact 5 b, is, for. B. connected via a make contact of this changeover contact with the coil 5 a of the contactor 5 , the other connection z. B. is ground. The electricity meter 1 is preferably a Ferrari electricity meter provided with an optical reading head or a static electricity meter provided with an optical or electrical pulse output. It measures the energy consumed by the two electrical loads 4 and 6 of the consumer 7 when the ripple control receiver 2 has switched on the electrical load 6 by means of the relay contact 8 b and the contactor 5 . The value of the energy measured by the electricity meter 1 appears in the form of an analog value, but preferably in the form of a digital value or a pulse train at a measuring output 1 b of the electricity meter 1 . The measurement output 1 b is a pulse output in the latter case. Each pulse of the pulse train represents a certain, predetermined and constant energy value, while the frequency of the pulse train is always proportional to a power belonging to the energy consumption. The number of b for a certain time at the measuring outlet 1 appearing pulses of the pulse train in accordance with the related consumer 7 during this time energy. Modern ripple control receivers usually contain a power supply 9 , an input part 10 , a microcomputer 11 , a programmable memory 12 , for. B. a PROM ("Programmable Read Only Memory"), optionally another programmable memory 13 , z. B. an EEPROM ("Electrical Erasable Programmable Read Only Memory"), two amplifiers 14 and 15 and the output relay 8 . In the power supply unit 9 , a DC voltage is generated from an AC voltage, which, which is not shown in the drawing, feeds the electronics contained in the ripple control receiver 2 . In the input part 10 there is a supply voltage monitoring, a voltage control, a so-called "watch dog" for monitoring the operation of the microcomputer 11 , an analog / digital converter and a pre-filter, which dampens the mains frequency signal and its harmonics. The microcomputer 11 performs, inter alia, the function of a highly selective digital filter, with which a ripple control audio frequency signal transmitted via the power supply network 3 is filtered out. The parameter values of the digital filter are stored in the memory 12 . The microcomputer 11 additionally performs the following functions: pulse evaluation of the ripple control telegram with pulse train detection and decoder, interpreter, network synchronization and network failure monitoring.

The input of the ripple control receiver 2 is connected within the latter to a first input and, via the power supply 9, to a second input of the input part 10 , the bus connection of which is connected to the microcomputer 11 via a bidirectional bus connection. The latter is also connected to the memories 12 and 13 via a further bidirectional bus connection. The measuring output 1 b of the electricity meter 1 is routed to an input of a first sub-arrangement 11 a of the microcomputer 11 , the output of which is connected via a unidirectional bus connection to an input of the amplifier 15 , the output of which in turn is connected to an “off” input A of a relay coil 8 a of the output relay 8 is performed. A second sub-array 11b of the microcomputer 11 is connected via a further unidirectional bus to an input of the amplifier 14 whose output is in turn led to an "A" input E of the relay coil 8 a of the output relay. 8

In the drawing, the presence of a single output relay 8 was assumed in the ripple control receiver 2 . In practice, there may be several output relays 8 , which are controlled via one or more addresses depending on priority or delay criteria. In contrast to older ripple control receivers, in modern ripple control receivers, after receiving a ripple control pulse or ripple control code, not only certain output relays 8 are switched on or off, but the received pulse or code causes a switching program to be started, which in turn triggers one or more switching operations of certain output relays 8 immediately or with a delay or another switching program starts. Modern ripple control receivers usually process several different switching programs, of which at least some are usually assigned time functions. The start of these switching programs can be triggered by external events, such as a ripple control broadcast, a power failure, a power recovery or the actuation of a test button operated in pulse mode. Each switching program that is executed triggers one or more on and / or off switching operations or starts another switching program at certain times, which are generally remotely programmable by means of ripple control. With the help of markings, hereinafter called flags, additional conditions can be formed or priorities can be set. This makes it possible to activate, change or stop switching cycles programmed remotely using a ripple control transmission. With the test button or, when replaced by electrical or optical pulse signals, by means of the latter, a defined switching program, for. B. to check and check the functionality of the ripple control receiver 2 . This latter switching program can, however, also preferably be used for the immediate or delayed switching off of one or more output relays 8 , whereupon the same or a different stored switching program later independently takes over the automatic reclosing of the relevant output relays 8 . A pulse input of ripple control receiver 2 , which replaces the test button, then preferably forms an input of a comparison means contained in sub-arrangement 11 a of microcomputer 11 . In the following, the assumption applies that two switching programs are started directly or indirectly from each pulse appearing at this pulse input. In addition, the assumption applies that, for. B. corresponds to a maximum permitted current consumption of 100 amperes a pulse time interval of the pulse train at the measuring output 1 b of 1 second. With a current consumption greater than 100 amperes, the pulse interval of the pulse train is less than 1 second. The first of the two vision programs contains e.g. B. the following program steps:

• 1. Wait for the next pulse to start the first switching program.
• 2. Wait z. B. 20 ms after the start of the first switching program.
• 3. Set a marker F, i.e. H. set the flag F.
• 4. Wait another 980 ms.
• 5. Place the mark F, i.e. H. the flag F back again.
• 6. End of program

The second of the two switching programs z. B. the following program steps:

• 1. Wait for the next pulse to start the second switching program.
• 2. If the flag F, ie the flag F is set, switch off the output relay 8 of the ripple control receiver 2 , otherwise go to the end of the program.
• 3. Wait z. B. 1 minute after switching off the output relay 8 .
• 4. Switch on the output relay 8 of the ripple control receiver 2 again.
• 5. End of program

Both switching programs are started simultaneously by the next pulse of the pulse sequence appearing at measuring output 1 b of the electricity meter 1 .

In normal operation, the current supplied to the consumer 7 is less than 100 amperes and thus the pulse time interval appearing at the output 1 b is greater than 1 second. When a first pulse appears, the flag F is not yet set, so that the second switching program immediately ends when the program ends. 20 ms after the appearance of the first pulse, the first switching program sets the flag F and thus releases the second program for the next pulse. Since this appears in normal operation at the earliest after a further 980 ms, i.e. totally after 1 second from the start of the program, and since the first switching program resets the flag F beforehand, namely after 980 ms, no output relay 8 is switched off by the second Pulse according to the second switching program, since this pulse only appears after the flag F has been reset.

In case of overcurrent, that is, when the consumer 7 supplied current of 100 amperes, and thus the greater the output 1 b appearing pulse interval is less than 1 second, the flag F is again not set at the appearance of the first pulse so that the second switching program again immediately goes to the end of his program. 20 ms after the appearance of the first pulse, the first switching program again sets the flag F and thus releases the second switching program for the next pulse of the pulse train. Since this appears in the event of an overcurrent before the further 980 ms has elapsed, ie totally before the end of 1 second from the start of the program, the flag F is still set at this point, so that this time, in contrast to normal operation, the second switching program will issue a switch-off command for the next program step Output relay 8 of the ripple control receiver 2 triggers. The latter thus switches the electrical load 6 of the consumer 7 for z. B. from 1 minute, after which the output relay 8 is automatically switched on again by the next program of the second switching program.

The ripple control can preferably remotely reprogram the 100-ampere value and the value of 1 second of the pulse interval for certain times of the day stored in the memory 12 and z. B. convert in 1.66 seconds, which corresponds to a current of 60 A instead of 100 A. In this case, the electrical load 6 is switched off during these times of the day when the pulse time interval falls below 1.66 seconds, ie when a current value of 60 amperes is exceeded.

In the inventive method for influencing the instantaneous power reference of the individual consumer of the consumer group 7 of the determined by the electricity meters 1 instantaneous power reference of the individual consumer 7 is thus compared with a current for the entire consumer group reference limit. This is done in the comparison means, which is contained in the sub-arrangement 11 a of the microcomputer 11 . The reference limit is preferably remotely programmable at any time by ripple control. The reference limit value received by the ripple control receiver 2 is e.g. B. stored in the memory 12 , from which it can be accessed at any time by the microcomputer 11 . If the on metering output 1 of the electricity meter 1 b pending measured value an analog value or, preferably, a digital value of the power reference determined by the electricity meters 1, then, the reference level represents an energy value. When exceeding the latter by the determined energy consumption of individual consumers 7 by means of a in the ripple control receiver 2 of the latter stored switching program automatically only with this individual consumer 7 a corrective intervention. If the instantaneous power consumption of the individual consumer 7 determined by the electricity meter 1 is represented by a pulse train, the frequency of which is always proportional to the instantaneous power consumption of the individual consumer 7 , then the pulse time intervals of the pulse train are compared with the time limit value that corresponds to the reference limit value, so if the value is undershot of the time limit, the corrective intervention takes place since a higher power consumption corresponds to a higher pulse frequency and thus a smaller pulse time interval. The corrective intervention in the individual consumer 7 is then preferably in all cases, at least a part, for. B. to switch off the electrical load 6 , the electrical loads 4 and 6 of the individual consumer 7 whose power consumption exceeds the reference limit. The switched off part of the electrical loads 4 and 6 , so z. B. the load 6 , is then either switched on again autonomously after a certain time by the ripple control receiver 2 of the individual consumer 7 itself or by means of the ripple control. The electrical load 6 is switched off in each case via the amplifier 15 by means of the output relay 8 . Later z. B. automatically by the microcomputer 11 according to the rules for the entire consumer group switching program on the sub-array 11 b and the amplifier 14 of the disconnected part of the electrical loads 4 and 6, so the electric load 6, is switched on again by means of the output relay 8, if at this time the power consumed individually by the consumer 7 is no longer too great.

In the arrangement according to the invention for carrying out the method, an electricity meter 1 and a ripple control receiver 2 are present at the individual consumer 7 , an electrical or optical output of the electricity meter 1 being connected locally to the input of the comparison means contained in the ripple control receiver 2 for comparison there the power consumption of the individual consumer 7 determined by means of the electricity meter 1 with the reference limit value. An output of the comparison means is effective at a switch-off input A of at least one output relay 8 of the ripple control receiver 2 for the purpose of carrying out the corrective intervention on the individual consumer 7 . The locally stored in the local ripple control receiver 2 shifting program is a power-on input E of the or of the output relays in question 8 of the ripple control receiver 2 for the purpose of a subsequent lifting of the correcting procedure, wherein this cancellation can effectively take place over the round control.

The electricity meter 1 preferably has a pulse output and the comparison means is then a means for comparing the pulse time intervals with the time limit value which corresponds to the reference limit value. The electricity meter 1 and the ripple control receiver 2 preferably both together form a combined ripple control receiver electricity meter and are then internally connected to one another.

Claims (7)

1. A method for influencing an instantaneous power consumption of an individual consumer ( 7 ) of a consumer group, characterized in that the instantaneous power consumption of the individual consumer ( 7 ) is compared with a reference limit value applicable to the entire consumer group and that when it is exceeded by means of a ripple control receiver ( 2 ) of the individual consumer ( 7 ) stored switching program automatically only with this individual consumer ( 7 ) a corrective intervention takes place. 2. The method according to claim 1, characterized in that the reference limit at any time is remotely programmable by ripple control. 3. The method according to claim 1 or 2, characterized in that the current power consumption of the individual consumer ( 7 ) is represented by a pulse train whose frequency is always proportional to the current power consumption of the individual consumer ( 7 ), and that pulse time intervals of the pulse train with a the time limit corresponding to the reference limit value is compared so that the corrective action takes place when it is undershot. 4. The method according to any one of claims 1 to 3, characterized in that the corrective intervention in the individual consumer ( 7 ) preferably consists in switching off at least part ( 6 ) of the electrical loads ( 4 , 6 ) of that individual consumer ( 7 ), whose power consumption exceeds the reference limit value, the switched-off part ( 6 ) of the electrical loads ( 4 , 6 ) either being switched on again autonomously after a certain time by the ripple control receiver ( 2 ) of the individual consumer ( 7 ) itself or by means of the ripple control. 5. Arrangement for performing the method according to one of claims 1 to 4, each with an individual consumer ( 7 ) existing electricity meter ( 1 ) and ripple control receiver ( 2 ), characterized in that an electrical or optical output of the electricity meter ( 1 ) locally with is connected to an input of a comparison means contained in the ripple control receiver ( 2 ) for comparing there the power consumption of the individual consumer ( 7 ) determined by means of the electricity meter ( 1 ) with the reference limit value and that an output of the comparison means to a switch-off input (A ) at least one output relay ( 8 ) of the ripple control receiver ( 2 ) is effective for the purpose of taking corrective action on the part of the individual consumer ( 7 ), while the switching program stored locally in the ripple control receiver ( 2 ) points to a switch-on input (E) of the output relay (s) concerned ( 8 ) the ripple control receiver ( 2 ) is effective for the purpose of later cancellation of the corrective intervention, which cancellation can also take place via the ripple control. 6. Arrangement according to claim 5, characterized in that the electricity meter ( 1 ) has a pulse output and that the comparison means is a means for comparing pulse intervals with a time limit corresponding to the reference limit. 7. Arrangement according to claim 5 or 6, characterized in that the electricity meter ( 1 ) and the ripple control receiver ( 2 ) both together form a combined ripple control receiver and electricity meter and are internally connected.