DE4109928C2 - Device for measuring the power consumption of a plurality of electrical consumption units - Google Patents

Description

The invention relates to a device for measuring the lei power consumption of a plurality of electrical consumption units specified in the preamble of claim 1 Art.

Such devices for measuring the power consumption are in the power supply by electrical supply companies (EVU) e.g. B. from US 3,906,242. Households and in industrial pantographs are with central measuring devices (ZM) equipped, the power consumption of the household or the industrial customer and in a meter hold on so that the power consumption z. B. billed monthly can be. Such central measuring devices are in today a typical design known to practically everyone and have a rotating disc, the speed of which is the moment tanen power consumption corresponds. Such electricity meters can indeed the integral power consumption over the billing period (e.g. one month) in the form of the last count hold on, but are not capable of the RU and / or  the customer (household or industrial company) an overview about how the electrical power takes time in the household or company, d. H. such as B. in the course of a day or a shift, the elec trical power consumption changes.

In order to observe the temporal development of the electrical power consumption at the customer are so-called collectors are already known in the prior art, together with the above-mentioned central measuring devices Act. For this purpose, the rotating rotor disk mentioned above the central measuring device, e.g. B. optically scanned to a Generate pulse train whose pulse repetition frequency is proportional is the speed of the rotor disc and is therefore a measure of the current power consumption of the entire household or of the entire industrial company, whose power supply from the central measuring device is detected. The individual impulses of Pulse sequences are added up and stored in the collector. The saved values (counting per time interval) are reduced called and z. B. evaluated in a computer (PC) to the time history of power consumption over z. B. a day or graph a work shift. With one The time is recorded on the abscissa (e.g. in units of one minute) and on the ordinate each for this Unit of time counted impulses plotted.

In commercial and industrial customer systems, the more often the question of how the individual consumption units of the customer, e.g. B. certain machines or the like. Or certain production units, production halls or the like in Depends on the time for total electricity consumption of the customer. That from the individual customer with the RU contract to be concluded is usually below the electricity price make it dependent on which consumption peaks occur at the customer. High consumption peaks, i.e. H. a star ke power consumption only for a certain, relatively short time tend to have a higher total electricity price Consequence as a consumption that rela  tiv is even. The customer can, if correspond to him de Measurement results are available, adjust accordingly.

The invention sets itself the task at a front direction of the type mentioned with a central Messein direction, which is the summed current power consumption of all A customer's consumption units are recorded using simple means a way to create the timing of the elec power consumption of different consumption units to be recorded separately.

According to the invention this object is achieved by the patent claim 1 resolved specified features.

This inventive solution to the above problem has the advantage that there is no interference with existing electricity must be carried out by installing measuring equipment, rather, it is possible to use the device according to the invention little effort and inexpensive in addition to the existing ones Measuring devices and in combination with them to use additional information about the electrical power win.

The device according to the invention also has the advantage that beyond the existing measuring devices no white other permanent installations at the customer's premises sen, d. H. in particular, there are no other fixed current meters ler or the like to install.  

Furthermore, the device according to the invention has the advantage that it can be used in many ways. The device can do with little Effort for a large number of customers of the RU for a relative installed for a short period of time (e.g. one day or several days) to be an analysis of this customer's power consumption perform, after which the measuring device then simply demon can be used with another customer etc.

A special embodiment of the invention is in the Unteran saying given.

An exemplary embodiment of the invention is described below the drawing described in more detail. It shows:

Fig. 1 shows schematically a block diagram of the use of a device according to the invention;

Fig. 2 is a block diagram of the measuring device according to Fig. 1 and

Fig. 3 shows details of a measuring device according to FIG. 2.

Fig. 1 shows schematically three individual consumption units I, II, III of the customer of an electricity supply company. For example, the individual consumption units I, II, III can be different manufacturing plants of an industrial company.

The industrial enterprise is supplied with electricity overall via a power supply line 10 . The line 10 runs via a known as such central measuring device ("electricity meter") and via a line 14 to a distributor 12 which distributes the electrical power to the consumption units I, II, III.

The central measuring device ZM is of a conventional type, as described above, and z. B. a rotating rotor disc, which is scanned via infrared probes to generate a pulse train in Im whose pulse repetition rate is a measure of the instantaneous power consumption, which is detected by the central measuring device ZM, ie the total on all consumption units I, II, III together. The infra red probe (not shown in detail, since it is known as such) generates on line 38 the pulse repetition frequency mentioned, which is entered into a collector 20 . The collector 20 is a conventional component. As such, it typically has several channels, which have independent inputs and can each count pulses from different consumers. In the embodiment according to FIG. 2, the collector 20 has three Kanae le 20 a, 20 b and 20 c on. The pulse sequence generated with the central measuring device ZM is, for. B. entered into the channel 20 b of the collector 20 .

At the collector 20 is a data processing system, for. B. a personal computer PC connected. To create a performance / time diagram of the load profile of the electricity system, the stored data of the collector are retrieved by means of a PC and shown graphically, which is shown in FIG. 1 below.

The measuring device of the central ZM, the channel 20 b of the collector 20 and the PC generated power distribution over time is shown in the diagram of the curve A, that is, with Runaway solid line to FIG. 1. The curve A thus shows the temporal course (with a temporal resolution in e.g. minute units) of the integral power consumption.

The central measuring device ZM is regularly fixed at the customer, d. H. permanently installed. The collector can be permanently installed if necessary be liert, since it enables low costs, depending because the total power consumption over specified periods of time capture. Such collectors are traditionally included equipped with several channels (e.g. DIMAS collector from NZR Energy systems; or collectors from PRAZISA- Energietechnik, MEREAN-KWBO series). Conventionally, however, the under different channels of such collectors at most to difference Liche central measuring devices ZM connected, so that a relatively large expenditure on equipment is to be carried out because  usually only one measuring device in the customer system is installed.

The invention now provides to determine the time course of the individual NEN electrical consumption units I, II and III by the fact that on individual feed lines to the individual United consumption units, so in Fig. 1, the leads 16 , 18 , so-called current clamps are applied. Such clamps current transformers are also known under the names "Stromzange" or "Zan genanleger". They inductively tap the current flowing through conductors 16 and 18 and generate a corresponding signal. The forceps feeder can be mounted and dismantled on lines 16 and 18 with a simple hand.

Referring to FIG. 1, two current clamps 22, 24 are provided in the illustrated embodiment. The current clamp transformers 22 , 24 are each connected to a measuring transducer 28 and 32 via lines 26 , 30 . The transducers 28 , 32 generate a pulse train on the lines 34 and 36, respectively, the pulse repetition frequency is a measure of the power consumption of the associated electrical consumption unit I or III.

In Fig. 2, the transducer 28 is described in more detail as an example. It consists of components 28 a- 28 e.

The current clamp transformer inductively taps a signal from line 16 which is proportional to the power consumption. The current signal is entered via a line 26 in a power meter 28 a. From the assigned consumption unit I is just tapped if the instantaneous voltage and also entered via a line 48 into the power measurement part 28 a. The voltage input is led to a voltage divider, while the current input reaches a preamplifier V. The preamp ker V has the task of amplifying the low input voltages of the current clamp transformer (an mV / A). The current and voltage values are then passed to an integrated multiplier M, which generates a DC voltage that corresponds to the momentarily consumed power of the consumption unit I.

If the system shown is a conventional three-phase system, three power measuring parts 28 a are provided, ie each phase of the three-phase current is assigned its own power measuring part 28 a. Accordingly, the DC voltages occurring at the outputs A of three such power measuring parts 28 a are inputted together into an adder 28 b, which adds the three input voltages to a total voltage. This total voltage signal is proportional to the momentarily consumed power of the consumption unit I.

The output signal of the adder 28 is input into a voltage frequency converter 28 c, which converts the output voltage of the adder into a rectangular pulse train. The voltage-frequency converter 28 c is set so that its output frequency per KW is 500 Hz.

The voltage-frequency converter 28 c is followed by a divider 28 d in which the square-wave voltage of the voltage-frequency converter is divided by 1800. This results in a counting constant of 100 pulses per kilowatt hour (500 Hz × 3600 sec in one hour gives 1,800,000 pulses, divided by 18,000 gives 100 pulses per kilowatt hour).

This calibration by means of the divider 28 d results in a calibration of the type that the pulse train generated on line 34 ( FIG. 1) is standardized so that its pulse repetition frequency gives the same measure of the electrical power as that generated by the central measuring device ZM Pulse train on line 38 .

The splitter 28 is an optical coupler d of FIG. 2 tet 28 e nachgeschal, which has the task to disconnect the pulse output from the galvanic measuring wertumformer 28 a.

The transducer 32 according to FIG. 1 is constructed in accordance with the transducer 28 described above.

Thus, the collector 20 receives in its channels 20 a, 20 c pulse trains, the frequencies of which are a measure of the instantaneous power consumption in the consumption units I and III.

The computer PC calculates an ordinate value for the diagram indicated in FIG. 1 below from the summed pulse numbers. The curve A b generated with the channel 20 of the diagram is already explained above. The curve B corresponds to the channel 20 a, ie the time course of the power consumption of the consumer unit I. The curve C corresponds to the time course of the power consumption of the consumption unit III. Since curve A represents the sum of the total power consumption of all consumption units, the consumption curve of the consumption unit II results from a subtraction of curves B and C from curve A and it is therefore not necessary in the illustrated embodiment for the consumption unit II a separate one Clamp current transformers to use. In a fourth curve, the time profile of the electrical power consumption of the consumption unit II could thus be determined and represented in a simple manner, such that the sum of the curves B and C is subtracted from the curve A.

The assemblies described above consisting of the elements 22 , 24 , 26 , 28 , 30 , 32 , 34 , 36 can be assembled and disassembled as a mobile measuring device relatively short periods (a day or the like.) At a customer. No intervention in the customer's existing electrical supply and measurement system is required. The computer PC and the collector 20 are also part of the mobile Meßvorrich device according to the invention.

Fig. 3 shows details of the wiring of the transducer 28 , which is already explained in Fig. 2 with reference to a block diagram. Fig. 3 shows details of the wiring including the resistors and capacitors and the types of processors used for the individual functions. The circuit of the power measurement part 28 a, the adder 28 b, the voltage-frequency converter 28 c, the divider 28 d and the opto coupler 28 e are readily apparent to the person skilled in the art from FIG. 3.

Claims (2)

1. A device for measuring the power consumption of a number of electrical consumption units (I, II, III), each of which is supplied with power via supply lines ( 14 , 16 , 18 ) and which are connected to a central measuring device, which the The sum of the power consumed by the consumption units is determined and an electrical pulse train is generated, the pulse repetition frequency of which is a measure of the total instantaneous power consumption of all consumption units, the pulse train being transmitted to a collector ( 20 ) having a plurality of measuring channels ( 20 a, 20 b, 20 c). is entered, the pulses for each of the individual channels added up and a signal ( 40 ) generated, which corresponds to the total power consumption of all consumption units per time interval, characterized in that Zangenstromwand ler ( 22 , 24 ) for investment in at least part of the supplier supply lines ( 16 , 18 ) to the individual consumption units (I, III) are provided nd that the output signals of the current transformer clamps are entered together with the voltage of the associated consumption unit in a separate transducer ( 28 , 32 ), which generates a signal corresponding to the current power consumption of the assigned consumption unit, which by means of a conversion circuit ( 28 b- 28 e ) is converted into a pulse sequence, and that the pulse sequences thus generated are entered into channels ( 20 a, 20 c) of the collector ( 20 ). 2. Apparatus according to claim 1, characterized in that output signals of the channels ( 20 a, 20 b, 20 c) of the collector ( 20 ) simultaneously recorded in a common performance / time diagram who the.