BE1027538A1 - Procedure for verifying phase assignments - Google Patents

Abstract

This invention relates to a method for checking a connection of an electronic device connected to a multiphase power network with n phases and the latter for carrying out the method. The electronic device has a voltage measuring device connected to each phase, as well as an amperage measuring device for measuring the time curves of voltages applied to the phases relative to a reference potential or of currents flowing through the phases - with sequential switching on and / or switching off of the voltages or Connection of one consumer per phase to at least (n-1) of the phases. These time courses are compared with one another on a common, calibrated time scale. If a change in a voltage measured by a voltage device provided for connection to a first phase and a current measured by a current measurement device provided for connection to a phase different from the first phase occurs synchronously at a point in time, a faulty connection of the electronic device to the power grid is registered and displayed on the electronic device.

Description

Method for Verifying Phase Assignments The present invention relates to a method for checking the correctness of a connection of an electronic device connected to a multiphase power network, and an electronic device for carrying out the method.

When using electronic devices, in particular measuring devices, in multi-phase power networks, it can happen that cables of the electrical device are incorrectly connected to the individual phases of the multi-phase power network when installing the electronic device. If the electronic device has, for example, an ammeter which is provided for measuring the current flowing through a first phase of the power network, this ammeter can, however, incorrectly not be connected to this first phase, but to a second phase different from the first phase. The current measured by this ammeter is therefore incorrectly assigned to the first phase if the incorrect connection due to the interchanging of the first with the second phase is not known, although the measured current is actually a current flowing through the second phase. If the electronic device also has a voltage measuring device connected to the first phase and a voltage measuring device connected to the second phase for measuring a voltage applied to the first and second phase relative to a reference potential, e.g. to the earth conductor or the neutral conductor, and are these voltage measuring devices correctly connected If the individual phases of the power grid are connected, the current measured by the ammeter is also incorrectly assigned to the voltage of the first phase, although it would have to be assigned to the voltage of the second phase. Such a connection error can lead to incorrect measurement results, especially if the measured values are re-used. If the electronic device described above is, for example, an energy meter, which is provided for measuring the electrical power of the individual phases and measures the currents flowing through the individual phases and the voltages applied to the individual phases relative to a reference potential, it is determined the energy meter in the above example of the incorrectly connected current meter generates an incorrect power measurement value for at least the first and the second phase. It can therefore be very helpful to check whether an electronic device is correctly connected to the phases of a multi-phase power supply system or whether there is at least a reversal of phases.

According to the prior art, there are already methods for checking the phase positions of voltages and currents, which determine the phase relationships of measured currents to measured voltages for the individual phases in a multi-phase power network and compare them with predetermined stored phase relationships. In US2014 / 0253091 A1, for example, a phase relationship between the currents and the voltages, i.e. a phase difference angle between the individual voltages and the individual currents, is determined for the individual phases from the measured voltages and currents. If the phase relationship determined between a voltage and a current of the individual phases or the determined phase difference angle with a preset

If the phase relationship or a preset phase difference angle does not match, an incorrect connection of the cables or an incorrect arrangement of the current transformers is displayed. As a rule, the determined phase difference angle corresponds to the predefined phase difference angle if the determined phase difference angle lies in a specific predefined phase difference angle range.

Such methods for checking the correctness of the connection of an electronic device connected to a multi-phase power network, which are based on the determination of a phase relationship and a comparison of this determined phase relationship with predetermined stored phase relationships, all have the disadvantage that these methods do not all errors with regard to Wiring errors are detected. For example, phase difference angles which lie outside the predefined phase difference angle range can no longer be assigned to a phase. Wiring errors in systems that are connected to a multi-phase power grid and produce a high phase shift between the current and voltage of a phase cannot be found with this method. Another disadvantage of this method is that, for its use, the phase sequence of the voltages and currents must always be known, for example must be stored in the respective electronic device connected to the multi-phase power network.

Accordingly, it is an object of the present invention compared to the prior art to provide a method for checking the correctness of the connection of an electronic device connected to a multi-phase power network and an electronic device for performing the method, with possible connection errors of the electronic device to the individual phases of the power grid can be determined automatically, quickly and easily and without the disadvantages listed above.

The object of the present invention is achieved by the features of claim 1 and configured and further developed by the features of the dependent claims.

In the method according to the invention for checking the correctness of a connection of an electronic device connected to a multiphase power network with a number of n phases, the electronic device has a voltage measuring device connected to each of the phases and a current measuring device connected to each of the phases. According to the method according to the invention, the time profiles of voltages applied to the phases relative to a reference potential are measured by the individual voltage measuring devices and the time profiles of currents flowing through the phases are measured by the individual current measuring devices. These time courses are all compared with one another on a common, calibrated time scale. The above-mentioned steps take place either a) when the individual voltages of the multiphase power supply are switched on and / or switched off sequentially or b) when the voltages are switched on and thus applied to the phases relative to a reference potential,

in this case, one consumer per phase is connected to a number of at least (n-1) phases of the power grid with a time delay. In the case of a change in voltage and current occurring synchronously at a point in time, this voltage being measured by a voltage measuring device provided for connection to a first phase and this current being measured by a current measuring device provided for connection to a phase different from the first phase , a faulty connection of the electronic device to the phases of the power grid is registered. The presence of such a faulty connection is indicated on the electronic device, preferably by means of a display element.

The multiphase power network has n phase conductors or phases, also called outer conductors, for conducting current from the power network, where n describes a natural number greater than 1. In addition, the power grid must also have a neutral conductor or neutral conductor N for carrying power from a consumer back into the power grid. A correct connection of an electronic device to the multiphase power grid is present in the sense of the invention when the voltage measuring devices and current measuring devices of the electronic device are each connected to those phases which the voltage and current measuring devices are each internal to the electronic device, ie from the manufacturer's side electronic device, are given. Such an internal assignment of the phases to the respective voltage and current measuring device on the part of the manufacturer of the electronic device is also used within the scope of the invention as a connection to a specific one

Phase designated voltmeter or ammeter.

According to what has been said above, there is a faulty connection of an electronic device to the phases of the power grid if at least one voltage measuring device or an ammeter is connected to a phase which corresponds to this voltage or current measuring device.

However, the ammeter is not assigned internally.

This can be done, for example, by interchanging two phases with one another when connecting the respective voltage measuring device or current measuring device of the electrical device.

The inventive method is used to check

whether an electronic device which is connected to a number of n phases of a multiphase power network is correctly connected to these n phases within the meaning of the invention.

The electronic device has a voltmeter connected to each of the phases for measuring the voltage between the corresponding phase and a reference potential and an ammeter connected to each of these phases for measuring the current flowing through the corresponding phase.

The reference potential can, for example, be the earth potential, but also the potential of a neutral conductor or

Be the neutral conductor of the power grid.

Either when the individual voltages of the multiphase power network are switched on and / or switched off, i.e. when a potential is applied to the phases of the power network, or when voltages are already applied to the phases relative to a reference potential, the time curves of these voltages are determined by the individual voltage measuring devices and the temporal courses of the

Power lines, currents flowing through the individual power meters are measured and recorded. These time courses are all compared with one another on a common, calibrated time scale. A common, calibrated time scale means that the start time of the measurement and the time unit on which the measurement is based are identical for all measured time curves of the voltages and currents. While in the first case, ie when the individual voltages are switched on and / or switched off, the invention always assumes that the voltages are switched on and / or switched off sequentially in terms of time, in the second case, ie when the phases are already switched on, relative To a reference potential, the voltages present in each case, and thus during operation of the electronic device, to a number of (n-1) of the n phases of the power network to differentiate the phases from each other in a time-shifted manner, ie with a time interval, one consumer per phase switched on. A consumer can be switched on in particular by closing a switch within a circuit of the corresponding phase, with a voltage and an ammeter of the electronic device being connected to the circuit in addition to the consumer.

If, when comparing the temporal progressions of the individual measured voltages and currents, a change occurring synchronously at a point in time between a voltage measured by a voltmeter and a current measured by an ammeter is determined, the voltmeter being connected to a first phase and the ammeter being connected to If a phase different from this first phase is provided, a faulty connection of the electronic device to the phases of the power grid is registered. A change in a voltage and a current occurring synchronously at a point in time means that a significant rise or fall in a voltage and a current can be registered or measured at the same point in time or a clearly recognizable voltage and current signal can be recorded or measured at the same point in time which differs from a background noise in each case noticeably. When the voltages and currents are measured by the respective voltage and current measuring devices, it is fundamentally assumed that there are no errors in the internal wiring of the electronic device, i.e. on the manufacturer's side of the electronic device, but errors relating to the interchanging of phases only on the user's side, namely when connecting the voltage and current measuring devices to the individual phases of the power grid.

Show, for example, a first voltage measuring device, which is provided for connection to a first phase and is therefore assigned to a first phase by the manufacturer of the electronic device, and a first current measuring device, which is also provided for connection to a first phase, each to one certain same point in time a change in the respectively measured temporal voltage curve and current curve, and this specific point in time essentially corresponds to the point in time at which either a voltage is switched on to the first phase or at which a load is connected to the potential already applied to the first phase When the first phase is switched on, a correct connection of the first voltage measuring device and the first current measuring device of the electronic device to the first phase can be inferred.

In contrast, it is, for example, the first

However, the voltage measuring device is not provided by the manufacturer of the electronic device for connection to a first phase, but for connection to a second phase, while the first current measuring device is provided for connection to a first phase, and the measured by the first voltage measuring device is nevertheless changed temporal voltage curve and the temporal current curve measured by the first current measuring device at a specific point in time as described above, the electronic device registers a

Failure to connect the first voltmeter and the first ammeter of the electronic device.

According to the example described, the first voltage measuring device is thus incorrectly connected to the first phase and not to the second phase, which is the first

Voltage measuring device according to the example is assigned by the manufacturer of the electronic device.

After a faulty connection of the electronic device has been registered, as described above, the presence of such a faulty connection is displayed on the electronic device, preferably by means of a display element.

A connection fault can be displayed, for example, by means of an LED with a red light.

Such a connection error can also be displayed on a display element of the electronic device designed as a display screen, for example in the form of an error message.

Also others

Refinements of such a display element are conceivable within the scope of the invention.

An automatic correction of connection errors of the electronic device to the individual phases is not provided within the scope of the invention.

Rather, it should be displayed to the user of the electronic device whether such a connection error, for example a reversal of two phases with one another when connecting to the phases of the

Power grid.

If a connection error is displayed on the electronic device, the user must correct this manually after the user has taken the electronic device out of operation.

When the electronic device is restarted, the

Voltages are applied sequentially to the individual phases, i.e. a potential is applied to the individual phases at a time interval from one another, and a renewed check for connection errors of the electronic device to the individual phases takes place according to the method described above.

According to a further development of the method according to the invention, the method also includes the step of checking for each individual phase of the power network by the electronic device whether the voltage measuring devices and the current measuring devices of the electronic device are correctly connected to the respective phases.

The method preferably also comprises the step of displaying a correct or incorrect connection for each individual phase on the electronic device.

In relation to the example mentioned above, this means that either a potential is applied to the individual phases at a time interval during the switch-on process or the individual phases are switched potential-free during the switch-off process or, if voltages are already applied to the phases relative to a reference potential, to each of the phases at least (n-1) phases a consumer is switched on at a time interval. Thus, for each phase individually and sequentially, it is checked whether the respective voltage measuring device and current measuring device provided for connection to the corresponding phase is actually connected to this phase. If this is the case, the electronic device must register a change in a voltage curve and a current curve at a specific point in time, as described above. This specific same point in time is either the point in time at which a potential is applied to this corresponding phase or this phase is switched potential-free or at which a consumer is switched on. In addition, this voltage curve must be measured by a voltmeter and this current curve by an ammeter, whereby the voltmeter and the ammeter must be provided for connection to the same phase, i.e. must be assigned to the same phase by the manufacturer of the electronic device.

In addition, there is preferably a display for each individual phase on the electronic device as to whether a correct connection of a voltage measuring device and an amperage measuring device of the electronic device to the respective phase is present. In particular, the electronic device can have a display element for this purpose. The display element can, for example, consist of two LEDs per phase,

a first LED showing a red light for a wrong connection and a second LED showing a green light for a correct connection. Furthermore, for example, a digital display can also be designed as a display element on the electronic device, which displays a correct or incorrect connection for each phase with the aid of words or merely outputs an error message.

In the steps of measuring and comparing the time profiles of the individual voltages and currents, the common calibrated time scale can be based either on real time or on averaged time intervals, in particular averaged over a period.

As a result, the voltages and currents of the respective phases to be recorded over time are output by the individual voltage and current measuring devices of the electronic device either in real time or in the form of mean values, in particular of effective values, i.e. as square mean values averaged over a period. In addition, a further development of the method provides the step of storing parameters in a storage device of the electronic device, these parameters including at least one assignment of the individual voltages and currents to the respective phases of the power grid that has already been checked by the electronic device and evaluated as correct. Should a renewed check of the phase assignments of the individual voltages and currents measured by the voltage and current measuring devices not be possible for any reason, then the in the

Storage device stored parameters are accessed.

The electronic device can be according to a

Embodiment of the invention to be a measuring device, in particular an energy measuring device.

Energy measuring devices are often used when electrical energy and power measurements are to be made on the individual phases of a power grid.

According to one embodiment, the multiphase power grid has, in particular, exactly three phases.

A three-phase power grid is used, among other things

Application in the field of electrical

Energy technology for the transport and distribution of electrical energy in power grids.

For example, supra-regional three-phase high-voltage transmission networks, low-voltage networks in the area of local power supply or three-phase machines that are used to drive elevators or in electrically powered vehicles are basically three-phase.

Preferably, the current measuring devices each include current sensors, the current sensors preferably as

Current transducers are formed.

Current sensors have the advantage that they can measure the current without contact, in particular on the basis of a magnetic flux density triggered by electrical currents.

This enables a defective current sensor to be replaced without the electronic device having to be taken out of service.

In addition to the method according to the invention, the present invention also relates to an electronic device for

Carry out the procedure described above.

The electronic device provided for connection to a multiphase power supply system with a number of n phases has terminals connected to each of the phases

Voltage measuring devices for measuring the voltages applied in each case to the phases relative to a reference potential, as well as current measuring devices connected to each of the phases via connections for measuring the currents flowing through the phases.

Furthermore, the electronic

Device an evaluation device which is designed in such a way that it compares the time curves measured by the voltage measuring devices and current measuring devices of the voltages applied to the individual phases relative to a reference potential and the currents flowing through the phases on a common calibrated time scale.

This takes place either with a) a temporally sequential switching on and / or switching off of the individual voltages of the multiphase power network, ie with a temporally sequential application of a respective potential to the individual phases of the power network, or b) when switched on and thus in each case to the phases relative to voltages applied to a reference potential, with a number of at least (n-1) of the phases of the

Power grid, one consumer, i.e. one load, is switched on with a time delay for each phase.

The evaluation device is also set up and designed to register a faulty connection of the electronic device to the phases of the power network and to display this faulty connection on the electronic device, preferably by means of a display element.

Such a connection error is detected by the evaluation device of the electronic device in the event of a change in voltage and current occurring synchronously at a point in time, this voltage being measured by a voltage measuring device provided for connection to a first phase relative to a reference potential and this current being measured by a voltage measuring device for connection to a first phase Connection to a current measuring device provided different from the first phase is measured, registered, as has been described in detail using the method according to the invention.

Further advantages, features and possible applications of the present invention will become clear from the following description of embodiments thereof and the associated figures.

FIG. 1: shows an embodiment of the method according to the invention when an electronic device is started up as a result of a voltage being applied by switch S1.

Figure 2: shows an embodiment of the method according to the invention when connecting a load to a phase of the power network while an electronic device is in operation; Figure 3: shows a block diagram for connecting voltage measuring devices and current measuring devices of an electrical device to a multi-phase power network in the correct connection configuration.

FIG. 4: shows time profiles of the individual voltages and voltages measured by the voltage measuring devices and the current measuring devices of the electronic device

Currents as a result of voltage switching in the connection configuration according to FIG. 3. FIG. 5: shows a block diagram for connecting voltage measuring devices and current measuring devices of an electrical device to a multiphase power network in an incorrect connection configuration (interchanging the cables of two voltage measuring devices).

FIG. 6: shows temporal progressions of the individual voltages and currents measured by the voltage measuring devices and the current measuring devices of the electronic device as a result of a voltage switch-on in the connection configuration according to FIG. 5.

FIG. 1 shows a basic circuit diagram for the execution of the method according to the invention when an electronic device 2 is put into operation as a result of switching on the voltage, i.e. switching on the energy supply, of a multiphase power supply network 1.

A voltage connection within the scope of the invention always provides that potentials are applied sequentially in time, i.e. with a time offset relative to one another, to the individual phases L ;, I ;, L3. After the voltage has been switched on, voltages U ,, U ;, U3, which result from the potential difference between the potential applied to the respective phase L ;, L ;, L3 and a reference potential, for example an earth conductor or a neutral conductor or neutral conductor N, can result, can be measured at the individual phases Lı, Ls, L3.

The multiphase power grid 1 shown in FIG. 1 consists, for example, of three phase conductors or phases L ;, L », L3 and a neutral conductor N. The number of phases and consequently“ n ”in this exemplary embodiment is thus 3. The power grid 1 can, however In further exemplary embodiments, even if this is not explicitly shown in the figures, it can also be designed in two phases or else have more than three phases. An electronic device 2 is already connected to the three phases Li, Ls, L3 of the power grid 1 in such a way that it can be connected to each of the phases L ,, L », L3 of the power network 1 has respective connected voltage measuring devices 3 and current measuring devices 4 via connections. The voltage measuring devices 3 consequently serve to measure the respective voltages, which are expediently present as alternating voltages, and the current measuring devices 4 are used to measure the respective electrical currents or currents, which are expediently present as alternating currents. In the embodiment according to FIG. 1, the current measuring devices 4 comprise current sensors 8 connected to them, which measure the respective currents I ,, Is, I; For example, non-contact measurement using a magnetic flux density triggered by the currents. The current sensors 8 are expediently alternating current sensors and, as shown in FIG. 1, are designed as current transformers W 1, W 1, W3. The voltage measuring devices 3 of the electronic device 2 are used to measure the time profiles of the voltages Ui, U ;, U3 applied to the phases L ,, Ls, L3 relative to a reference potential, and the ammeters 4 are used to measure the time profiles of the respective through the Phases Li, Lo, L3 flowing currents I ,, Is, I3.

If switch S2 in FIG. 1 is now closed, contacts K4, K5 and K6 of switch S2 connected to phases L ;, L ;, L3 close and consumers R ;, R ,, R3 are consequently connected to power network 1. However, there is still no current flowing through the loads R ;, R ;, R3, since switch S1 is not yet closed. Switches S1 and S2 are exemplified in Figure 1 as three-pole switches and can in particular be a contactor. If switch S1 is now closed, so that the contacts Kl, K2 and K3 of switch S1 applied to phases L1, L2, L3 are closed, voltage is applied and, consequently, current flows through the individual phases L,;, L2, L3 to the electronic device 2 and the consumers R1, Ro, R3. The switching on of voltage or the closing of the individual contacts Kl, K2, K3 of the switch S1 is to be regarded as sequential in terms of time within the scope of the present invention, because switching delays occur due to contact bouncing.

Contact bouncing describes mechanically triggered interference effects in electromechanical switches and buttons, through which the switch is opened and closed several times. The contacts Kl, K2, K3 therefore do not all close at the same point in time, but with a time offset from one another, that is to say sequentially in time. The present invention makes use of precisely this time offset when the voltage is applied in order to check whether the electronic device 2 is correctly connected to the individual phases L ;, I ;, L3.

Instead of three-pole switches according to FIG. 1, however, a single-pole switch can also be used per phase. The three single-pole switches, like the contacts Kl, K2, K3 of the switch S1, would also have to be closed with a time offset to one another, either automatically or manually, in order to use the method according to the invention.

To check the correctness of the connection of the electronic device 2 to the individual phases L ;, L », L3 of the power network 1, the time courses of the individual voltages U ,, U ,, U3 and the individual currents I ,, I2, I3 of the Voltage measuring devices 3 or measured by the current transformers W 1, W 1, W3 of the current measuring devices 4 on a common calibrated time scale and preferably compared with one another on this common calibrated time scale by means of an evaluation device 5 of the electronic device 2. A common, calibrated time scale means that the starting time of the measurement and the time unit on which the measurement is based are identical for all measured time profiles of the voltages U ,, U », U3 and currents Ii, I ,, I3.

The common calibrated time scale can either be based on real time or based on averaged time intervals, in particular averaged over a period. As a result, the voltages U ,, U ,, U3 and currents I ,, Is, I; of the individual phases L ;, Ls, L3 either as real-time values or as averaged values, in particular as effective values, i.e. as root mean square values averaged over a period, output by the voltage measuring devices 3 and current measuring devices 4 of the electronic device 2. Can the respective voltages U ,, U ,, U3 and currents I ,, I2, I; of the individual phases L; L2, L3 detect a change in a voltage and a current occurring synchronously at a specific point in time, and this voltage is measured by a voltage measuring device 3 provided for connection to a first phase relative to a reference potential and this current by one for connection Measured at a current measuring device 4 provided from the first phase, the electronic device 2 registers a faulty connection of the electronic device 2 to the phases L;, L2, L3 of the power network 1. As a result, such a faulty connection or one is displayed Connection fault on the electronic device 2. The electronic device can have a display element 7 to display the faulty connection. Such a display element 7 can, among other things, be an LED that displays a red light or also a display with the display of a connection error by means of words, for example by means of an error message.

When checking the correctness of the connection of the electronic device 2 to the individual phases L :, L ;, L3 of the power network 1, the electronic device 2 preferably checks for each individual phase L ;, L », L3 of the power network 1 whether its voltage measuring devices 3 and whose current transformers W ,, W ;, W3 of the current measuring devices 4 are correctly connected to the individual phases Li, I ;, L3. Preferably, for each individual phase L ;, L ;, L3 on the electronic device 2, a display element 7 indicates whether the voltage measuring device 3 connected to the respective phase and / or the current transformer Wi, W ,, W3 connected to the respective phase is correct or incorrectly connected. For example, two LEDs, one LED with green light and one LED with red light, can be assigned to each phase on the display element 7. The LED with green light is activated or switched on when both the voltmeter 3 and the current transformer W ,, W ,, W; 3 are correctly connected to the corresponding phase. However, if a

Voltage measuring device 3 and / or a current transformer Wi, W ;, W3 is incorrectly connected to the corresponding phase, the LED is activated or switched on with a red light.

However, any alternative configurations of such a display element are also conceivable.

If the electronic device 2 now detects a connection error and shows it by means of a display element 7, the user of the electronic device 2 should first shut it down according to FIG. 1 by opening the switch S1 and manually check and correct the connections of the electronic device 2 .

This is shown in FIG. 1 by a hand and a dashed oval, with the user having to correct an incorrect interchanging of the connections of the current transformers W and W3 measuring the currents I and I3 in FIG.

Accordingly, the electronic device 2 must both a simultaneous change in a voltage U applied to the second phase L, relative to a reference potential, and a current

I3, which, however, is measured by an ammeter provided for connection to the third phase L3, as well as a simultaneous change in a voltage U applied to the third phase L3 relative to a reference potential; and a current I »flowing through the third phase L3,

which, however, is measured by an ammeter provided for connection to the second phase L2.

It should be noted that the designation of an ammeter in the case of a current transformer as in Figure 1 refers to a current measurement on the secondary side of the

Current transformer and the measured current is therefore a secondary current.

An automatic correction of a faulty connection of the electronic device 2 to the individual phases L 1, L2, L3 of the power grid 1 is not provided within the scope of the present invention.

After the manual correction has been made by the user, the electronic device 2 can be put into operation again.

By closing the switch S1, voltage is applied sequentially over time, as described above, and a renewed check for connection errors in the electronic device 2 takes place in accordance with the method described above.

FIG. 2 shows a basic circuit diagram of an embodiment of the method according to the invention when a

Consumers or a load R3 to a phase, here by way of example to the third phase L3 of the power grid 1, namely during the ongoing operation of an electronic device 2. The power grid 1, as in FIG.

Phases L 1, L 2, L3 and also a neutral conductor, although only the third phase L3 and the neutral conductor N are shown in FIG. 2 for the sake of clarity.

The electronic device 2 shown in FIG. 2 is designed, for example, as an energy measuring device and is used in the power network 1 to measure energy and power.

For this purpose, the energy measuring device 2 is connected to the phases L 1, L 2, L3 and to the neutral conductor N of the power network 1 and has connections to each of the phases L 1, L2, L3 via connections of the energy measuring device 2

Voltage measuring devices 3 and current measuring devices 4.

For the sake of clarity, however, FIG. 2 shows only one connection of the energy measuring device 2 to the third phase L3 and to the neutral conductor N via the connections T1, T2, T3, T4.

The current measuring devices 4, of which the current measuring device 4 connected to the third phase L3 is shown as an example in FIG. 2, comprise current sensors 8 in FIG. 2 and are connected to the power network 1 via the current sensors 8.

The current sensors 8 enable a non-contact current measurement of the currents I ,, I », I3 flowing through the individual phases. The voltage measuring device 3, which is connected to the third phase L3 by way of example in FIG. 2, measures the potential difference between the third phase L3 and the neutral conductor N, ie the voltage U3, which also applies to those connected to the first and second phases L ;, Ls, respectively , voltage measuring devices 3, not shown, applies.

If a defect occurs in at least one current sensor 8 during ongoing operation of the energy measuring device 2, the at least one defective current sensor 8 must be replaced. By means of the contactless current measurement of the current sensor 8, this can also take place while the energy measuring device 2 is in operation. In the event of a defective current sensor 8, an exchange of all current sensors 8 on the part of the user is often considered, so that connection errors in the newly connected current sensors 8 can occur after the current sensors 8 have been exchanged. During operation of the energy measuring device 2, ie with the switch S1 closed, the correctness of the connection of the energy measuring device 2, in particular the current sensors 8, to the individual phases L;, Ls, L3 of the power network 1 cannot be checked on the basis of a time-sequential voltage connection, such as described with reference to Figure 1, take place. Therefore, according to Figure 2, the procedure is such that the time delay when switching on the voltage, so to speak, by one consumer per phase,

which is switched on with a time delay to at least two of the three phases L1, L2, L3, is replaced.

This is done as follows: First, also as described with reference to FIG. 1, the temporal progressions of the individual to the

Phases L ,, L », L3 relative to the neutral conductor N applied voltages U ;, U ,, U3 and the individual currents I ,, Is, I3 flowing through the phases L, L2, L3 from the corresponding voltage measuring devices 3 and the current measuring devices 4 , which each include the current sensors 8, evaluated on a common calibrated time scale and compared these time courses with one another.

This evaluation takes place in FIG. 2 in an evaluation device 5 of the energy measuring device 2. In a first phase, shown in FIG. 2 by way of example with reference to the third phase L3,

a consumer R3 is now switched on by closing the switch S2 and thus connected to the energy measuring device 2.

The switching on of the consumer Rs causes a change in the temporal course of the through this phase, i.e. in Figure 2 through the third phase,

flowing current I3, which is measured by the current sensor 8 connected to the third phase.

Due to the change in the current, in particular in the form of a current jump, there is also a direct voltage jump as a function of a source resistance

Ro and a line resistance R ,, i.e. a simultaneous change in the voltage U3 applied between the third phase L3 and the neutral conductor N. Now show both the current sensor 8 provided for connection to the third phase L and that for connection to the third

Phase L3 provided voltage measuring device 3 in each case a change in the time profile of the current I3 or the voltage U3 immediately at the point in time at which the consumer R3 was connected to the third phase L3, the energy measuring device 2 does not register any connection errors with regard to the third phase L3. However, in contrast, show, for example, one provided for connection to the first or second phase L ;, L »

Current sensor 8 as well as the voltage measuring device 3 provided for connection to the third phase L3. In each case a change in the time profile of a current I ,, I; or the voltage U3 immediately at the point in time at which the consumer R3 was connected to the third phase L3, the energy measuring device 2 registers a connection error in relation to the third phase L3. Shortly after the consumer R3 has been switched on to the third phase L; 3, but with a time lag, another consumer R, or R, is switched on accordingly to the first or second phase L ;, L by closing a switch.

If the energy measuring device 2 detects a simultaneous change in a voltage and a current at the point in time when the additional consumer R, or R, is connected, this voltage is measured, for example, by a voltage measuring device 3 provided for connection to the first phase L, and this current is measured by a current sensor 8 provided for connection to the second phase L is measured, the energy measuring device 2 registers a faulty connection in

Reference to the phase to which the consumer Rı or R; was switched on.

After two consumers have been connected to one phase each, the energy meter can already make a statement as to whether there is a general connection error of the energy meter 2 to the phases L ,, L », L3 of the power grid 1 or not, regardless of which of the three phases L ,, Ls, L3 a faulty connection was registered. However, each individual phase L 1, L 1, L3 is preferably checked for possible connection errors in the current sensors 8 and voltage measuring devices 3 connected to the individual phases L 1, Ls, L3. Furthermore, the energy measuring device 2 preferably also displays such a connection error for each individual phase I 1, Ls, L3. Various configurations are conceivable here. For example, the energy measuring device 2 can only display in each case, for example, by means of an LED with a red light or a text on a display that a connection error has been registered either as a whole or in relation to a specific phase. However, embodiments are also conceivable in which the energy measuring device 2 also indicates to the user that the energy measuring device 2 is correctly connected to the phases Li, Lo, L3, likewise either overall in relation to the energy measuring device 2, with then in relation to all three phases there must be a correct connection, or in relation to a specific phase.

The energy measuring device 2 shown in FIG. 2 evaluates the voltages Ui, U ,, U3 and currents I, I », I3 of the respective phases L ;, L ;, L3 to be recorded over time, for example in the form of effective values. The rms values correspond to the root mean square values of the voltages and currents that vary over time, with an average value being calculated over the period. However, in an alternative embodiment, an evaluation in real time or over a specific time interval which does not correspond to the period duration is also conceivable. In addition, the method explained by way of example according to FIG. 2 preferably provides that a storage of parameters, which at least one of the

Energy measuring device 2 checked and evaluated as correct assignment of the individual voltages Ui, U ,, U3 and currents I, I2, I3 to the respective phases L 1, L 1, L3 of the power grid 1 include. In order to make this possible, the energy measuring device 2 according to FIG. 2 has a storage device 6. Should the phase assignments of the individual voltages U ,, U ,, U3 and currents I ,, I ,, I; If it is not possible for any reason, the parameters stored in the memory device 6 of the energy measuring device 2 can be accessed.

FIG. 3 shows a connection example of an electronic device 2 which has voltage measuring devices 3 and current measuring devices 4 connected to the individual phases L ;, L ;, L3 of a three-phase power network 1. In FIG. 3, the current measuring devices 4 include, for example, current sensors designed as current converters Wi, W ;, W3, via which the current measuring devices 4 are connected to the respective phases L 1, Ls, L3 of the power network 1. The current transformers Wi, W ;, W3 each measure secondary currents which are essentially proportional to the primary currents flowing through the individual phases L 1, L 1, L3. The voltage measuring devices 3 measure the potential difference between the individual phases L ;, L ;, L3 and the neutral conductor N, i.e. the voltages U ;, Us, U3. As can be seen in Figure 3, both the three current transformers Wi, W ;, W; as well as the three voltage devices 3 of the electronic device 2 correctly connected to the individual phases Li, Ls, L3 of the power grid 1.

FIG. 4 shows the voltage and current curves measured by the voltage measuring devices 3 and the current transformers W 1, W 1, W 3 of the current measuring devices 4 of the electronic device 2 in the connection configuration according to FIG , U3 and currents I ,, I2, I3 can each be measured as effective values.

If, within the scope of the method according to the invention, voltage is applied sequentially in time, the contact Kl of a switch SI, as shown in FIG. 1, closes at time t7, contact K2 of switch S1 closes at time t8 and contact K3 of switch S1 closes at When time t9 closes, with a correct connection configuration of the electronic device 2 according to FIG. 3, at time t7 there is initially a simultaneous increase in voltage U; and of the current I}, at time t8 then a simultaneous increase in voltage U and current I, and finally at time t9 a simultaneous increase in voltage Us and current I; 3. On the other hand, if the electronic device 2 were in operation, for example at time t7, a consumer Rı would be in the first phase L, and at time t8 a consumer R2 would be in the second phase L; are switched on, there would be a simultaneous jump in current and voltage in current I and voltage U; in the time curves of voltages U ,, U ,, U3 and currents I ,, Is, I3 at time t7. and at time t8 a simultaneous current and voltage jump in current I and voltage U can be determined. However, this is not evident from the figures. If no connection fault has been registered with respect to the first and second phases I 1, L, it automatically emerges from this that there can be no connection fault in the electronic device 2 with respect to the third phase L3 either.

FIG. 5 shows a connection example of an electronic device 2, which is connected to the individual phases L ;, L ;, L3 of a three-phase power network 1

Has voltage measuring devices 3 and current measuring devices 4.

In FIG. 5, the current measuring devices 4 include, by way of example, current transformers W 1, W 1, W, via which the current measuring devices 4 determine the currents Ii, Is, I; measure up.

In contrast to the connection example shown in FIG. 3, the connections of two voltage measuring devices 3 are now interchanged.

The connection to the first phase I; The voltage measuring device provided is incorrectly connected to the second phase L, and accordingly measures one between the second phase L, and the

Neutral conductor N applied voltage V, instead of, as provided, one between the first phase L; and the voltage Vi applied to the neutral conductor N.

In addition, this is for connection to the second phase L; the intended voltage measuring device wrongly connected to the first phase L,

connected and consequently measures a voltage V applied between the first phase L and the neutral conductor N, and not, as provided, a voltage V- ,, applied between the second phase L and the neutral conductor N

FIG. 6 shows, corresponding to FIG. 4, the voltage and current curves measured over time t by the voltage measuring devices 3 and the current transformers WW, W 1, W 3 of the current measuring devices 4 of the electronic device 2 in the connection configuration according to FIG.

The respective

Voltages Vi, V ,, V3 and currents I ,, I ;, Is; are each measured as effective values.

If, within the scope of the method according to the invention, with the present connection configuration according to FIG. 5, voltage is applied sequentially in time, in which the contact Kl of a switch S1, as shown in FIG. 1, closes at time t7, contact K2 of switch S1 closes at time t8 and the Contact K3 of switch S1 closes at time t9, then in the connection configuration of electronic device 2 according to FIG. 5, at time t7, there is initially a simultaneous one

Rise in voltage V 1 and in current I 1 at time t8, then a simultaneous increase in voltage V 1 and current I, and finally at time t9 a simultaneous increase in voltage V3 and current I3. Based on the chronological order of the increase in

Voltages Vi, Vs, V3 compared with the respective simultaneous increases in currents I ,, I », I; it is determined on the basis of FIG. 6 that there must be a connection error with regard to phases L 1 and L 1.

However, within the scope of the method according to the invention, it is not possible to determine whether the voltage devices 3 of the electronic device 2 provided for connection to phases L and L, which measure voltages Vi and V, or those for connection to the phases L, and L, provided current transformers W ;, W ;, W3 of the electronic device 2, which measure the currents I, and I, are connected incorrectly.

On the other hand, if the connection configuration of the electronic device 2 shown in FIG.

FIG. 4 describes a consumer R at time t7, for the first phase L; and at time t8 a consumer R, are connected to the second phase L », then in the time curves of voltages Vi, V, and currents I ,, I, at time t7 there would be a simultaneous current and voltage jump in current I; and the voltage V; as well as a simultaneous jump in current and voltage in current I and voltage V at time t8; detectable. However, this is not evident from the figures. As a result, in this case too, it is concluded that there must be a connection fault with regard to phases L1 and L. Since there is obviously an exchange only with regard to the phases L; and L »is present, there can be no connection fault of the electronic device 2 with regard to the third phase L3.

However, with a connection configuration (not shown) of the electronic device 2 during its operation and with a corresponding connection of the loads Rı, Rs to the phases L1, Ls, as described above, for example in the time curves of the voltages Vi, V2, V3 and currents I, , I2, I; At time t7 a simultaneous current and voltage jump in current I and voltage V3 and at time t8 a simultaneous current and voltage jump in current I and voltage V can be determined, then there would be a connection error in electronic device 2 with respect to all of them three phases In, Ls, L3 before.

It is pointed out that all features that are apparent to a person skilled in the art from the present description and the figures, even if these features have only been described in connection with certain further features, both individually and in any combination with others of those in the present invention disclosed features or feature groups can be combined, unless this has been explicitly excluded or technical conditions make such combinations impossible or meaningless.

For the sake of brevity and legibility of the description, a comprehensive, express description of all possible combinations of features has been avoided.

The scope of protection of the present invention defined by the claims is not limited by the embodiments of the invention which are shown in detail in the description and the drawings and are only used as examples

Invention limited.

Modifications of the disclosed embodiments will be apparent to those skilled in the art from the drawings, the description and the appended claims.

The word "having" recited in the claims includes other elements or

Steps not out.

The indefinite article "a" or "a" does not exclude a plurality.

The combination of features that are claimed in different patent claims is not excluded.

LIST OF REFERENCE NUMERALS 1 multi-phase power network 2 electronic device 3 voltage measuring device (s) 4 current measuring device (s) 5 evaluation device 6 storage device 7 display element 8 current sensor (s) Li, Lo, L3yz.

Ln phases N neutral Ui, Ua, Us, Un voltages Vi, Vo, V3 voltages | Ti, Io, I3,… In rivers | SI, S2 switch | Kl,… K6 contacts Wi, Wa, War ... Wa Current transformers Ri, Ro, Ray.

Rn consumer, load Ro source resistance Rı line resistance Ti, T2, T3, T4 connections of the electronic device Pi, P2 connections current transformer on primary side Sır S2 connections current transformer on primary side t7, te, to times

Claims (8)

Claims 1. A method for checking the correctness of a connection of an electronic device (2) connected to a multiphase power supply system (1) with a number of n phases (L ;, Lo, L3, ..., Lp), the electronic device (2) being a a voltage measuring device (3) connected to each of the phases (Li, Lo, L3; +, Ls) of the power grid (1) and an ammeter (4) connected to each of the phases (Li, La, L3, ..., Lan) of the power grid ), with the following steps: - Measuring the temporal progressions of the voltages (U, U2, Us, ..., Un) applied to the phases (Li, Lo, L3 ;, ... La) relative to a reference potential by the individual voltage measuring devices (3 ) as well as of the currents (I ,, I », I3, ... In) flowing through the phases (LI ,, L», L3, ..., Ls) through the individual ammeters (4) and comparing these time profiles on a common calibrated Time scale either a) with sequential switching on and / or switching off of the individual voltages (U ,, U ;, Us, ..., Un) of the power supply system (1) or b) when the voltages (U, Us, Us) are connected to the phases (Li, Lo, L3, ..., In) relative to a reference potential , ..., Un), with a number of at least (n-1) phases (L;, Ls, La, ..., Ln) of the power network (1) each having a consumer (R3) per phase switched on with a time delay, - in the case of a change in voltage and current occurring synchronously at a point in time, this voltage being measured relative to a reference potential by a voltage measuring device (3) provided for connection to a first phase and this current being measured by one for connection to one of the first phase The current measuring device (4) provided in the different phase is measured: Registering a faulty connection of the electronic device (2) to the phases (L;, Ls, L3, ..., Ln) of the power supply system (1) and displaying the faulty connection on the electronic device ( 2), preferably by means of a display element. 2. The method according to claim 1, characterized by the step of checking for each individual phase (L ;, L ;, La, ..., Lp) of the power grid (1) by the electronic device (2) whether the voltage measuring devices (3) and the current measuring devices (4) of the electronic device (2) are correctly connected to the respective phases, and preferably the display of a correct or incorrect connection for each individual phase (L1, Lo, L3, ..., Ls) on the electronic device (2) . 3. The method according to claim 1 or 2, characterized in that in the steps of measuring and comparing the time curves of the voltages (U, Uz, Us, ... p Un) and currents (Ii, Is, I3, ... In) the common calibrated time scale is based either on real time or on averaged time intervals, in particular averaged over a period. 4. The method according to any one of the preceding claims, characterized by the further step of storing parameters which contain at least one assignment of the individual voltages (U, Uz, Us, "7 Un) that has already been checked by the electronic device (2) and evaluated as correct. and currents (I1, Is, I3, ... In) for the respective phases of the power grid (1) in a storage device (6) of the electronic device (2). 5. The method according to any one of the preceding claims, characterized in that the electronic device (2) is a measuring device, in particular an energy measuring device. 6. The method according to any one of the preceding claims, characterized in that the multiphase power grid (1) has exactly three phases (L ;, L ,, L3). 7. The method according to any one of the preceding claims, characterized in that the current measuring devices (4) comprise current sensors (8), wherein the current sensors (8) are preferably designed as current transducers (Wi, W ;, W3, ... W,). 8. Electronic device (2) for connection to at least a number of n phases (L1, La, L3, ..., Ln) of a multiphase power network (1), the electronic device (2) being connected to each of the phases (Li, Lo, L3, ... Ls) Voltage measuring devices (3) connected via connections for evaluating the voltages (U, U, Us, ..., Un) applied to the phases (Li, Ls, L3, ..., La, N) relative to a reference potential. as well as current measuring devices (4) connected to each of the phases (L ;, Ls, L3, ..., La) via connections for measuring the currents (L ;, Ls, L3, .., La, N) flowing through the phases (L ;, Ls, L3, .., La, N). I ,, Is, I3, ..., In, In), characterized in that the electronic device (2) furthermore has an evaluation device (5) which is designed in such a way that it contains the voltage measuring devices (3) and current measuring devices ( 4) measured temporal progressions of the voltages (U, U », Us, etc.) applied to the individual phases (L ;, La, L3, ..., Ln, N) relative to a reference potential …, Up) and the currents (I ,, Iz, I3,… yp Ia; In) a) flowing through the phases (L ;, Ls, L3,…, Ln, N) in the case of a chronologically sequential switch-on and / or Switching off the individual voltages (U, U ;, Us, ... Un) of the multiphase power grid (1) or b) when the voltages are switched on and are therefore applied to the phases (Li, Lo, L3, ..., La) relative to a reference potential, with a number of at least (n-1) of the Phases (I;, Ls, L3, ..., Ln) of the power grid (1) one consumer (R3) per phase to a number of at least (n-1) of the phases (L ;, Ls, La, ..., Lp) of the power grid (1) one consumer (R3) per phase is switched on with a time delay , is compared with one another on a common calibrated time scale, and the evaluation device (5) also in the case of a synchronous change in a voltage and a current occurring at a point in time, this voltage being provided by one for connection to a first phase Voltage measuring device (3) is measured relative to a reference potential and this current is measured by a current measuring device (4) provided for connection to a phase different from the first phase, is set up and designed to detect a faulty connection of the electronic device (2) to the To register phases (L ;, Ls, L3, ... y, Ly, N) of the power network (1) and to display them on the electronic device (2), preferably by means of a display element.