DE539349C - Measuring device for AC systems, in which two measuring systems, which are influenced by the voltage or the current, are provided with windings and are mutually inducing, display, record, integrate or trigger switching processes as a function of the product volt times amperes - Google Patents

Description

Measuring device for AC systems, where two of the voltage or influenced by the current, provided with windings and mutually inducing lw (measuring systems depending on the product volts times amperes a display, recording, Carry out integration or triggering of switching processes There are no difficulties in an AC system to measure the product of volts and amps when current and voltage are in phase. Such a measurement can be carried out using one of the known designs be carried out by indicating, writing or integrating watt meters, and these known devices can also be used as relays in this case, that respond when the product reaches a certain size, volts times amperes. However, measuring the voltamper becomes a difficult task once in the AC system the phase shift between current and voltage is variable, since the usual In this case, measuring devices do not use the arithmetic product, but the vector product measure, d. H. the arithmetic product multiplied by the cosine of the phase angle.

On the other hand, it is for economic production and distribution the electrical energy in AC systems necessary that the phase shift is kept as small as possible. In order to achieve this goal, one is there now passed the charges for electrical energy from the maximum consumption to make it dependent on kVA instead of the maximum consumption, as has been the case up to now of kW, and there is a need for cheap and reliable equipment for this Purposes. It has proposed kVA meters with an induction regulator or phase regulator work and take action when the power factor changes. Such However, instruments are expensive and usually require compensation facilities. The invention now aims to provide simple and inexpensive means to become dependent a display, integration or recording of the arithmetic product volt times amperes to deliver and to trigger switching processes depending on this product, z. B. with the help of a relay to operate a switch when the product is volts times ampere reaches a certain maximum value in a circuit.

According to the invention, a measuring device is used for this purpose, which has two measuring systems which can be rotated against one another. Each measuring system has a winding these windings induce one another. You will be sent to the concerned AC system connected in such a way that the current in one winding is proportional to the Voltage in the other winding is proportional to the current. One of the two Measuring systems is in a uniform-periodic revolving or oscillating Movement offset, so that the phase shift in the said windings flowing currents is changed periodically. These currents are here at least be in phase once within a period of motion, and will be in this position a maximum torque occurs between the two measuring systems. Will therefore the non-moving measuring system with an increasing proportion to the deflection Provided counterforce, the deflection brought about by the aforementioned torque is be a measure of the maximum value of the arithmetic product volts times amps, independent on the change in the phase shift between current and voltage. Provides the measuring system not set in motion with a pointer or with a writing device, in this way the display or the recording of the volt-amperes is obtained. You can do this Let the measuring system act on a suitable motor or on a clockwork, to integrate the volt-amps over a period of time and in this way kVAh to display. Finally, this measuring system can be used to trigger a relay, to operate a switch depending on the product volts times amps.

The measuring system set in a rotating or oscillating movement can be used with a writing measuring device to measure with the help of a thumb control the movement of the tab, so that the movement of the tab always takes place in a certain phase position. This way you can at the same time the maximum of the kVA, the values of the active and blind kilowatts are recorded, The active and blind kilowatts recorded can be used to determine whether the energy is was delivered to the network or removed from the network.

In a particular embodiment, only one of the two windings is used connected to the AC mains, while the other winding is connected to a measuring winding a measuring device or a relay is connected, the other winding in turn is now connected to the AC network. For this purpose, for example, a Electricity meters are used, its one. Coil as tension coil and whose other coil acts as a current coil. Because the one coil of this counter connected directly to the network and the other coil to said measuring device its display will depend on the product of those present in the network Volts and amps.

In the embodiment described first, the non-rotating or oscillating part the drive for the indicating, integrating or recording Device or relay. In the version described last, the drive of the indicating, integrating, recording or triggering device through the movable Measuring system of the instrument mentioned formed, which under the action of the two Measurement windings are available, one of which is connected to the alternating current network and the other the phase-shifting measuring device is connected.

The measuring device described here with the two provided with windings and mutually rotatable measuring systems. of course nothing to do with the long-known phase regulators, induction regulators or phase indicators. The subject of the invention differs from these known devices especially because in this one between the two measuring systems is uniform periodic rotating or oscillating relative movement is generated so that the Phase shift between the currents flowing in the two windings runs through a full cycle from 0 ° to 36o ° or at least one such part of the full cycle that the currents at least in one position in the course of a Period of motion have the phase shift o. With this arrangement accordingly the vectors of voltage and current within each movement period brought to congruence, i.e. they are phased once within a period. For this reason, the measuring device described here can usefully be used as a "coordinator" are addressed, and for the sake of abbreviation, this term is used in the made use of the following description.

The coordinator can use a measuring device in various ways or control unit work together. Embodiments of this type are described in the following described and illustrated.

The periodic movement imparted to one measuring system of the coordinator can be uniformly circumferential or within a fixed or variable area be oscillating. Any suitable motor can be used for the drive.

As a result of the reaction of the flowing in the windings of the coordinator Currents , a torque is exerted on the movable measuring system, so that it tries to turn. This torque can be increased or decreased are made by changing the resistance and reactance of the windings. The circumferential Movement can take place under the action of a counterforce, an inhibition or a brake.

The connection of the windings to the alternating current network can be done via 'transformers or impedances or a combination of both, and a single coordinator can be used to display a number of gauges or triggering of C monitoring equipment as a function of the product of volts and amperes bring to.

Exemplary embodiments are shown in the figures to explain the concept of the invention shown.

Fig. I shows a schematic representation of a coordinator in connection with a measuring device, e.g. B. a wattmeter.

Fig. 1A is a partial view of a relay with the coordinator can be associated.

Fig. 2 shows the circuit diagram of a coordinator in connection with a Electricity meter.

2A is a partial view of a ratchet mechanism for controlling a Maximum pointer.

Fig.3 shows the circuit diagram of a coordinator in connection with a Electricity meter, a relay, a pendulum meter, a writing wattmeter, an indicating and an integrating wattmeter.

Fig .I shows the partial view of a registration strip.

The remaining figures show the circuit diagrams and the details of a Series of embodiments which are described in more detail below.

In all figures, A denotes the part of the rotated part of the Coordinator, B the controlled part, C the control mechanism and D the measuring system of the counter. These parts are explained in the various exemplary embodiments distinguished a number that corresponds to the number of the figure in question.

In Fig. I Al and BI are the two measuring systems of the measuring device, which is referred to here as the coordinator. Each part Al and BI has a winding, whereby both windings induce each other. These two parts can be relative to each other are moved so that the mutual induction between a maximum and a minimum can be continuously adjusted to any value. Appropriate the two parts Al and B1 are arranged coaxially. In most embodiments Al rotates evenly and in one direction, so that it is called "the revolving part" referred to as. However, the part Al can also be non-uniform in one or in rotated in both directions or uniformly, but moved in alternating directions will.

The part BI is expediently designed to be freely rotatable, however prevented from rotating by the pin cl, which engages in the slot b1 will.

In the arrangement shown, the product of the currents supplied should be , l1 and N are measured. The multiphase stream 14T is passed through the rotating part the polyphase line a2 supplied. Dl is a multi-phase counter of the common ones Type, which is the product of two measuring currents, multiplied by the cosine of their phase shift, measures. The currents coming from the part BI are passed to the counter Dl through the multiphase line b = fed. The currentsN are fed to the counter Dl through the polyphase line dl.

The windings on the parts Al and BI are designed so that they generate a rotating field with suitable excitation, whereby the number of poles of both rotating fields is equal to. When the winding of the rotating part Al is energized i induced the resulting rotating field in the winding of part B1 currents. The phase shift of this induced current versus the phase of the supplied currents AZ becomes one have a certain size between o ° and 36o °, depending on the position of the parts Al and take BI against each other. This position is defined by the angle Z between the starting point a 'and the corresponding starting point b'. The points al and b3 are so that the supplied currents M with the induced currents in Phase when the angle Z = o. It follows that the phase shift between the induced currents and the supplied currents 1.Z according to the respective size of the angle Z can have any value between 0 ° and 36o ° and that a position of the rotating part must be possible in which this phase shift has a certain value.

If the phase shift between the supplied currents @ 11 and N = 0, the phase shift between the induced currents and the supplied currents 11 will be equal to the angle Z. The phase shift of the supplied currents' 31 and N is referred to as the "imposed phase shift" and the phase shift between the supplied currents 11 and the currents induced in BI as "corrected phase shift", it can be seen that when the phase shift is imposed (p, the corrected phase shift is zero when the angle Z = -9). When the phase shift between the currents N and the currents induced in B 'is zero, the reading of the counter is a maximum, and it is proportional to the product of the currents N and the induced currents, the latter again being proportional to the currents M. If the imposed phase shift is unknown, the product of the currents M and N can be obtained by slowly rotating the rotating part until it reaches a position in which the display of the meter D ', which can be an ordinary indicating wattmeter, is a Maximum reached.

Fig. IA shows the partial view of an embodiment in which the coordinator, not shown, is used to control a relay. The relay expediently has a measuring system in the manner of a multiphase induction wattmeter d2. The currents N are fed to this through the multi-phase line d ', while on the other hand it is connected to the part BI of the coordinator through the multi-phase line b2. The measuring system d2 drives a metal disk d3, which is under the action of the pendulum lever Cl. This pendulum lever is practicing his. maximum torque when it is in the horizontal position. This torque is called the "critical" torque. If the measuring system d2 acts on the disk with a torque which is less than the critical torque, the disk cannot perform a complete revolution. If, on the other hand, the torque is greater than the critical torque in one of both directions, the disc will rotate evenly and thereby trigger the linkage d $ by lifting the locking lever d ' with the thumb d °, which in turn is lifted by the gears d4 and d5 is driven. In this embodiment, the rotating part A ″ is expediently set in slow rotation by a motor or other suitable drive means.

FIG. 2 shows a coordinator similar to that in FIG. 1, in which the currents are fed to an integrating measuring device, the phase shift running through all values. In the example shown, the product volt times amps times time is measured in a three-phase network. The coordinator again consists of parts A2 and B2, as in the example shown in FIG. The currents 1112 are taken from the current transformers H2, the currents N2 from the voltage transformers J =. Both groups of transducers are connected in the same way as is usual for a measurement in a three-phase network. D2 is a multi-phase induction counter in which the rotating system d2 is influenced by the brake magnet C and the revolution counter d3. drives via a ratchet lock d4. One group of the coils of the counter D2 is connected to the voltage converter by the line d ', while the other group of coils is connected to B2 via the lines b2. The rotating part A2 is driven uniformly in one direction by the drive motor F2. This drive device consists of the motor f5, which drives the rotating part via the gears f1 to f4. However, the part A2 can also be moved back and forth by suitable means within a certain range, which is expediently 360 ° in each direction.

Within each movement period, the angle Z and thus also the corrected phase shift run through all values between 0 ° and 36o °. The torque of the counter D2 is therefore also all values between one assume a positive maximum and a negative maximum. The speed of the revolving counter system is also all values between a positive Assume maximum and a negative maximum, so that the circulating measuring system of the Counter makes as many revolutions in one direction as in the other. However, with the help of the ratchet lock, only the revolutions in one direction of rotation are made transferred to the counter of the meter. The number of revolutions registered is therefore proportional to the average value of the product volts times amperes times the cosine of the corrected phase angle times time, where the corrected phase angle can have a value between -f- 9o ° and -9o °.

If it is desired that the maximum value of the apparent power instead of the volt-ampere hours is registered, the transfer to the counter can be done with With the help of the devices partially reproduced in Fig. AA. The counter's reciprocating measuring system carries a ratchet wheel d4 with a single one Tooth. The movement of this wheel d4 is in one direction with the help of the pawl d ° and the ratchet wheel d ". The counter is set up so that its largest The deflection is less than a full turn. At the first rash if the counter is driven by the pawl over an angle, the corresponds to the measurement in question, with the measurement system returning to its starting position returns and the ratchet wheel d 'with the counter at the maximum deflection d °' leaves behind. The ratchet wheel d 'is then not moved any further as long as the counter not reached a major peak, and within one working period it will then the distance traveled by the ratchet wheel d 'will be proportional to that achieved Maximum apparent power.

FIG. 3 shows an embodiment of a device similar to that in FIG Figs. 1, 1A and 2 described. Here, a plurality of measuring circuits is on a single coordinator attached. Such an application is e.g. B. at Distribution systems applicable.

In such a case it is appropriate to do the job of the voltage converter to move to the coordinator. The winding of the rotating part A 'is through the connection dl is connected directly to the alternating current network. The circulating one Part is driven by the clockwork F "via the gears f 1 to f4. The induced Part B3 is with the various measuring instruments through the common busbars b = connected. The following measuring instruments are provided: a kVAh counter dl and a maximum consumption relay d °, a single-phase pendulum meter d ', a kVA consumption recorder d4 with two measuring elements, a kVA indicator d ', a counter 0, which kVA and kW recorded and integrated kVAh, as shown in Fig. 13 in detail.

dl is a three-phase induction meter with a ratchet lock, similar to that shown in FIG.

d = is a three-phase kVA relay, similar to that shown in FIG.

d` is a pendulum counter, in which the count value: via a ratchet lock is driven.

d4 is a maximum consumption recorder for recording the maximum consumption at kVA in a three-phase network. The maximum consumption recorder is useful from a writing induction wattmeter with two measuring elements, the two Current coils are connected to the power lines via current transformers and the two Voltage coils energized by two phases of the induced part B ° of the coordinator will. The deflection of this device will move back and forth around the value zero and assume a maximum value which corresponds to the kilowatts. the one with the power factor 1 would be transferred. The record obtained in this way is shown in FIG which is the amplitudes of the deviations calculated from the zero line, the kVA play back within the relevant time.

The single-phase volt ampere indicator cdi is expediently in the form of a indicating wattmeter (dynamometric or induction wattmeter) at which the current coil is placed in one phase of the network. The period of fluctuations must be long enough to allow an accurate reading of the maximum deflection to enable.

The writing and integrating meter d6 is in its details shown in FIG. A is the umlaut part of the coordinator, B the fixed part 'for sale. F is the drive motor. The measuring instrument I) consists of a three-phase Induction device dl, which is under the action of the spring c. It owns one Pointer d'2, which makes records on the recording strip d`. The registration strip is moved with the help of the release d ', which in turn is controlled by the thumbs a1 and a = is operated by the coordinator. The thumb a1 is placed in such a place, that the release is activated when the coordinator assumes a position, in which watts are recorded. The thumb a. = Is arranged so that the release is operated at a position of the coordinator in which negative watts are recorded will. The steps with which the recording strip moves due to the trigger are alternately larger and smaller.

The record thus obtained is similar to that in FIG Figures 13A to 13D are shown. The points a1 at which the curve turns are Points belonging to the watt curve, while points b1 on the volt-ampere curve lie. The shape of the curve with respect to the axis associated with the record the watt and volt-ampere give both over the phase shift and over the respective direction of energy exposure.

Fig. 13A shows the recording with positive energy direction and lagging current. Fig. 13B shows the recording when the energy direction is positive and leading current. 13C shows the recording with negative energy direction and lagging current.

Fig. 13D shows the recording in the negative energy direction and leading current. If you want to record the reactive power, you can this can be achieved in a simple manner that the coordinator with another The thumb is given in the position in which the reactive power is registered. if only * a thumb is provided and the release with constant steps occurs, the recording is reproduced as shown in Fig. 13E. The amplitudes of the The deflections of the measuring system d 'are added by the ratchet mechanism with the pointer d = is coupled by the joint d ', so that the sum through the pointer of the counter d7 is displayed.

dg is a locking lever which is supported at d ° and an adjusting screw dl ". When the kVA exceed a certain maximum value, the pointer moves d ° the lever d ', so that the contact arm d ", which closes the contact d'2, is released will.

In order to be able to operate the coordinator by hand, a lever f ' intended.

Fig. 6 shows a further embodiment in which the coordinator is united with the counter or the relay. A ° and B ° are the two parts of the Coordinator, which the rotating part and the induced part of the first described Design correspond to: BG is expediently mounted coaxially with the rotating part. It can be rotated freely, but is prevented from rotating by the stop Ca, which engages in the slot d '. The windings generate through when excited two different currents each with a rotating field, whereby the circuit is made in such a way that that the direction of rotation of the two fields is the same. For further explanation is the arrangement shown in which the currents from a current transformer H ° and can be taken from a voltage converter I ° of a three-phase network.

The arrangement of the windings is such that if the currents flowing in the rotating part A ° and in the part B ° are in phase, no torque occurs between these two parts when the rotating part is in the position indicated by the fixed mark n3. If the rotating part is rotated by an angle S (FIG. 6A), a torque is produced, the magnitude of which depends on the currents in parts A 'and B1; and depends on the angle S between these two parts. The windings are expediently designed in such a way that the torque is proportional to the product of the two currents times the cosine of the angle S. If the rotating part is rotated uniformly, the torque takes all values between a positive and a negative maximum proportional to that Product of the currents flowing in both. Assuming that the currents flowing in the two windings are in phase, the angular displacement between the two rotating fields generated by these currents will be equal to the angle S. However, if these currents are not in phase, but shifted in phase by an angle T the angular displacement between the two rotating fields is no longer the same. be the angle S, but it will be equal to the angle S + T. The torque occurring between the two parts is then no longer proportional to the product of the currents times the cosine of the angle S, but proportional to the product of the two currents times the cosine of the angle S -; - T. If the rotating part is rotated uniformly, so the cosine of the angle S and the cosine of the angle S - [- T will assume all possible values with one complete revolution of the rotating part. With all positive values of the angle T, the torque occurring between the two parts will reach a maximum value once within each complete revolution of the rotating part, which is proportional to the product of the currents flowing in both parts. If the rotating part is set in rotation uniformly, the product of the currents flowing in both parts results from the force which is exerted by part B ° on the stop C °. Appropriately, you will restrict the movement of part B ° by a spring or a similar counterforce. An embodiment of this type is shown in FIGS. 7 and 7A.

A7 is the rotating part of the coordinator who, as described above, carries a winding. Bz also has a winding and is under the effect a spring C 'such that the deflection, which the part B' under the action the torque between the two parts on the one hand and the spring on the other is a known function of this torque. This angle will be his Reach maximum value when the maximum torque is exerted on part B ' will. The mode of operation of the arrangement is thus exactly as described above, with however, the angle S - * - T is the relative displacement angle between the two Parts A 'and B' forms.

There is a fixed mark a3 on part A 'and a fixed mark on part B7 Mark h3 attached. Fig.7 shows the relative position of the two parts when the currents are in phase and there is no torque between the two parts. The part B 'is located is in the zero position, in which the counterforce of the spring is also zero. The biggest The deflection from the zero position reaches part B7 when the applied torque has its greatest value, and this occurs once in each direction when the orbiting Part opposite part B @ one complete revolution of 36o ° executes. It is advisable to attach a fixed stop C3 to part B7, which rests against the fixed stop C4 by one revolution in one direction To prevent beyond the zero position. The position of the maximum torque is shown in Figure 7A. The part B 'has covered an angle [r] and the circumferential part forms an angle S + T - L '. Since the maximum delimoment of depends on the product of the applied currents and not on their phase shift is dependent, since the deflection of the part Bi is also a function of the torque it follows that the deflection of part B 'is also a function of the product of the imposed currents is.

An embodiment in which the rotating part is set in rotation by a motor and the other part is under the action of a counterweight and damping is shown in FIGS. 8 and 8A. The rotating part here consists of a yoke a1, a core a2, which can be made of magnetic or non-magnetic material, also of a winding a3, which generates a rotating field when connected to the network in question, and finally of drive means for the part As, which suitably consist of a gear a1 which forms one piece with the yoke a1. B 'consists of a shaft b1, a core b2, which can be made of magnetic or non-magnetic material, and a winding b °, which generates a rotating field when connected to the relevant network. C3 forms the counterforce and consists of a mass cl which is fastened to a screw c = held on the shaft b1 by the hub c3. The distance between the center of gravity of this mass and the shaft axis can thus be adjusted as required. D3 is the indicator, which consists of a pointer dl, which also sits on the hub c3, and a dial d, 2, on which a suitable scale division is attached to indicate the angular deflection of part B3 when compared with the pointer. It is an attenuator consisting of a small eddy current brake with the brake disc egg and the permanent magnet e2, which is arranged in such a way that the magnetic flux cuts the disc and causes eddy currents in it when this disc rotates. F1 is the drive device, which in this embodiment consists of any suitable motor fl, which works on a gear f2, f3, f- ', and drives the already mentioned gear a4, which forms a piece of the rotating part a1. The intermediate gears f2, f3 are freely rotatable on the shaft il, while this shaft f ° is fastened in the housing of the measuring device. G8 is the frame that carries the various parts. The rotating fields generated by both windings have the same number of poles and the same direction of rotation. The spatial distribution of the magnetic field can have any shape and is suitably sinusoidal. The device shown in Fig. Ä is connected via the current transformer H ', from which the current is fed to the part BR via the slip rings b1. The current is fed to the rotating part A 'from the voltage converter J3.

In the embodiment shown in FIGS. S and S A can the measuring device, as shown in Fig. 8 B and 8 C, drive a counter. The part Bs is under the action of the spring cl attached to the shaft b1 with the housing is attached. He is also facing your stop g2, which through the housing is held. The spring and the stop can be adjusted so that the Pressure that part BI exerts on the stop has any value and also zero can be. The rotation of this part is such that it moves under the action of the Torque moved away from the stop against the spring force. When the counter torque the spring is greater than the torque acting on the part BI, outweighs the Spring force and turns part B $ back into its starting position against the stop. The angle covered by the part B3 is proportional to the product of the printed Currents as described above. The movement of the part Ba is on the counter transferred with the help of the gear train d4 to d8 with the assistance of the ratchet mechanism dl and cT =, which is housed in the housing (d3. The latch mechanism can be set up in this way be that it transmits the movement of part B $ in one or both directions, however, only the backward movement will preferably be transmitted to the counter. The amount of movement is determined by the balance of the acting and the counteracting torque during the forward movement of part B8, and since this part does not drive the counter during the outward movement, the setting of the Equilibrium takes place under the most favorable conditions and without external influences. Since, in addition, between every two outward movements of part B8 the one exerted between A8 and BI Torque is reversed, the reversed torque is the return of the part Ensure Bs in its initial position against the stop even if that Counter rotation the spring is only small at this point.

Fig.9 shows an embodiment in which the coordinator the Affected phase shift in the voltage circuit of an induction watt hour meter. Since the torque is changing, you can use an ordinary eddy current brake on the counter load, or the brake can expediently be replaced by an increased one Flywheel. The amplitude of the reciprocating motion of the measuring system is known Function of the volt-amperes impressed on the meter.

In Fig. 9, Au and B 'is the coordinator, with the circumferential part A3 is driven by the Svnchroiimotor F 'at a constant speed. Itl and lag are the current transformers; dl and d2 are two single-phase drive systems of the known type which are fixed to the frame G 'and which are fixed on the axis d4 Drive drive pulley dg. A flywheel d12 is also attached to the axis d4, which, as shown, can form one piece with the drive pulley.

The revolutions of the axis are on the counter d5 through the gearbox d ', to d' ° and the worm d11 transferred. The wheels d 'and d1 ° have a ratchet mechanism, which only transmits the torque in one direction. When the axis is clockwise rotates, the movement is transmitted to the counter through the gears d6 and d '; when it rotates counterclockwise, the movement is made by the gears d9, d 'and d1 ° are transmitted, with d running' empty '. The frequency of the back and forth movement of the flywheel is given by the speed at which the coordinator is driven. The torque acting on the flywheel can be divided into two components be decomposed, one of which is in phase with the movement, to the friction to overcome, while the other hurries ahead by a quarter of a period to the flywheel to accelerate. Because these two components are out of phase and there is the mode of action of the counter is primarily determined by the acceleration component a small change in the friction component, which in itself is already small in comparison to the acceleration component, to the information of the counter a negligible Effect.

FIG. 10 shows an embodiment similar to that in FIGS. 6 and 7 shown. Here, however, the part B1 ° is freely rotatable, and under the Counteraction of the pendulum C1 ° and can be used as a relay. So long the maximum torque exerted on BIO by the rotating part A '° is less than the maximum counterforce, is the mode of operation of the device similar to that described in the embodiment according to FIGS. However, if that said torque is greater than the maximum counter torque, then the Part B10 one full turn. The counter torque has its highest Value when the pendulum is rotated through a right angle from its equilibrium position has, and if the applied torque is large enough to the part B '° over To turn away this critical angle, the turn is definitely brought about. When part B '° has rotated two right angles, the counter torque rotates around and has the same direction as the driving torque. Both torques together can be used to trigger any suitable device D '°. While the rotation is being completed, the part B '° can be used for the actuation of this Device to store enough living energy. After the part B1 ° the device Has exceeded D1 °, it continues its movement up to the starting position then start a new cycle.

Fig. I i shows an embodiment similar to that in FIGS. 6 and 7 described, but the part B 'is under the action of a spring cl. With this arrangement, the rotation of B11 can be used to set a counter Dl 'to operate, so that every time the driving Drehrno = ment the counter torque predominates, a count takes place by the counter. The spring can through the Screw c2 can be adjusted. If necessary, the turn of Bll can be added serve to turn the screw c = and thereby increase the tension of the spring cl.

Fig. 1a shows an embodiment in which the coordinator A12, B12 influences the voltage circuit of a writing wattmeter D'-. The registration strip can be driven by a clockwork, the escapement, as shown, by the thumbs d3 and d4 is controlled. The registration can also be accessed directly driven by the thumb via a latch mechanism. In this embodiment the coordinator and the wattmeter are connected to a single-phase network.

In some cases where the coordinator is used to adjust the phase Influencing the voltage fed to a measuring device or relay can have a retroactive effect a torque between the two windings of the coordinator Cause parts, and this torque element can serve to bring about mutual movement. The mutual movement can be through any customary process inhibition or brake can be regulated, or it can be used to in order to bring the rotating part into synchronism with one serving as a drive Synchronous motor.

Another embodiment is shown in FIG. Here is a writing wattmeter cal is supplied with power through the connecting lines N, while a current corresponding to the voltage is sent to the coordinator through the connecting lines 11 is fed, which in turn with your writing device through the line b = is connected. The recording strip of the writing wattmeter is through a clockwork driven whose shaft d = is extended and a locking disk d3 wearing. The coordinator consists of a fixed part a1 and a rotatable part b1. The rotation of part b1 is brought about by the torque, which is exerted by the rotating field generated by the winding of part a1. The part a1 carries a ratchet wheel b3, the development of which is shown in FIG. 15A.

The position of the slot cd4 is arranged so that the rotation of the Coordinator is prevented by the locking disk, which engages in this slot, and thus any phase change of the ones flowing in the leads: 11 and b = Currents does not arise. The writing device will therefore record watts. if the shaft d '= has performed one revolution, the coordinator is released and makes a complete revolution under the action of its own torque. As a result, the writing wattmeter becomes at one point during the revolution record the value of kVA when the maximum point is within a Circulation of the part a1 is recorded. The speed of the rotating wave b = can have any suitable value, for example this wave can be a Execute rotation in five minutes, so the kVA records on the Registration strips are made periodically and ensure that the even recording of the kW superimpose. Of course, the coordinator can do any particular Location recorded "- for example to record the blind kilowatts or read off. It can also be used in cases where the power factor is known changes only within a small area, the coordinator in one position in which the Wattaneter records kVA, provided that this particular power factor is actually present in the network. Also can one or more slots can be provided in different positions in the disk b- ″. If, for example, the slot d5 indicated by dotted lines is provided, it can alternate kW and blind kilowatts are recorded.

In addition, the control can be between the coordinator and the recording strips take place at will. Fig. 15B shows a partial view of a record that has been obtained when two slots are provided in the part V.

Claims (7)

PATENT CLAIMS: i. Measuring device for alternating current systems, in which two of the voltage or current influenced, provided with windings and each other Mutually inducing measuring systems as a function of the product volt times amperes execute a display, recording, integration or triggering of switching processes, characterized in that the one measuring system is a periodically rotating or oscillating movement is issued, such that within each period of this Movement is passed through at least one position, the phase shift is zero, d. H. corresponds to the arithmetic product of current and voltage and in which to the indicating, recording, integrating or triggering a switching process Organ a maximum torque is exerted. 2. Measuring device according to claim i, characterized in that the two are provided with windings and each other inducing measuring systems are arranged coaxially and a drive device the one of them drives periodically rotating or oscillating. 3. Measuring device according to claims 1 and 2, characterized in that the winding of one measuring system through the voltage, the winding of the other measuring system from the current of the @AC system is fed and the measuring system not set in motion under the action of a mechanical or magnetic counterforce and as a driving force for that indicating, recording, integrating or switching processes triggering element acts. . 4. Measuring device according to claim i and 2, characterized in that the current or the voltage-fed windings of the two measuring systems to the current coil or voltage coil a wattmetric device for displaying, Recording, integrating or triggering switching processes is connected. 5. Measuring device according to claim i to 4, characterized in that the excess a certain value of the torque corresponding to the product of current and voltage a relay actuated. 6. Measuring device according to claim i to d., Characterized in that that a recording strip driven by a clock mechanism shows the values of the product from current and voltage as a function of time. 7. Measuring device according to claim i to 4, characterized in that the step-by-step movement of the Registration strip as a function of the periodic movement of the driven Measurement system takes place and the recording device as a function of the time Recorded apparent and real power: B. Measuring device according to claim 7, thereby characterized in that the index strip advances within each movement period of the driven measuring system alternately with two or more different sizes Switching steps takes place and the registration device also records the reactive power. G. Measuring device according to Claims 6 to 8, characterized in that the recording device the measuring system set in a periodic movement ifl a certain one Holds position in which the instantaneous value of a certain measured variable, z. B. the active power, is recorded. ok Measuring device according to claim i to 4, characterized in that the existing between the windings of the two measuring systems Motor action of one of the two measuring systems, possibly with application of a process inhibition, set in motion, so that a special drive device is not required is.