DE2214629B2 - Performance-dependent tariff system - Google Patents

Description

5 6

Distance between the fixed quantity pulse and the previous one - the totalizer counts 8 pulses. The amount dependent on the fixed quantity pulse is switched on according to the definition of the relationship. 'between the sizes T and A , the respective

In the following, some exemplary embodiments of the desired tariff character will be taken into account, 5 The converter 3 can also be designed in such a way that purifies. It shows that for every fixed quantity impulse he has one of the

F i g. 1 is a block diagram showing the difference between a given reference variable

F i g. 2 a block diagram of an electronic output F i g that is electronic and the distance to the preceding fixed quantity solution, pulse linear or non-linear dependent. up to 5 basic circuit diagrams of electromechanical 10 size generated. In the case of the linear dependency solutions and the totalizer registers the overconsumption Ve F i g. 6 and 7 block diagrams of further electrical according to the formula mentioned earlier. A beneficial niche solution. Difference from the initially described in FIG. 1 means 1 a pulse generator. The known overconsumption meter, however, is a 15 not shown in the drawing that the known arrangement responds to the Mo electricity meter of conventional or electro- mentanwert the power, while the ernischer design is assigned; According to the implementation according to the invention, it gives the consumption of consumption of a certain fixed amount, for example energy blocks, assessed. The F i g. 2, 3 and 5 show a kilowatt hour, an impulse. An embodiment of a tariff device is denoted by 2, a totalizer, which has a mechanical, "o with a converter of this type. Electromechanical or electronic pulse meter. 2 is a pulse generator for generating counters or a mechanical counter with one of fixed quantity pulses in turn with 1 and a drive shaft. Between the pulse totalizer, here a pulse counter, with 2 denoting 1 and the totalizer 2 is a converter 3 net. The pulse generator 1 is connected via an AND gate 4, in which the ratio of output 25 to a control input 5 of a flip-flop 6 is connected. The size to input size is a function of the input, an output 7 of the flip-flop 6 and an oscillator 8 size. The output variable can be a pulse train with an AND gate 9 and the other output, or as the angle of rotation of the drive shaft of a summing counter designed as 10 and a time base generator 11 with an AND counter. Gate 12 connected. The outputs of the AND gates 9 By appropriate selection of the transmission radio 30 and 12 lead via an OR gate 13 to the counting of the converter 3 you have it in your hand, the input 14 of a counting chain 15. The AND gate 9 is the relationship between the electrical power is also connected to the totalizer 2, and the display of the tariff device to adapt the respective wishes of the energy supplier. is connected to a reset input 17 of the flip-flop 6 and the converter 3 is preferably output via an inverter 18 with a further input such that it is connected to each of the AND gate 4 generated by the pulse generator 1. From the pulse generator 1 fixed quantity pulse one of the reciprocal value of the distance leads a connection via a monostable tipping to the preceding fixed quantity pulse dependent stage 19 to a zero input 20 of the number output generated, with the dependency chain 15.

can be linear or non-linear. An example is shown in FIG. 40 To explain how the descried works given in the following table: this tariff facility is initially assumed

men, the position of the flip-flop 6 is such that the AND gate 9 is blocked and the AND gate 12 is conductive. The time base generator 11 generates time pulses 45 which reach the counting chain 15 via the gates 12 and 13 and are counted into it. The time T ₀ required to fill the counting chain 15 corresponds to the reference variable. If the distance Γ between two fixed quantity pulses is greater than the 50 reference variable T ₀ , that is, if the electrical power is below the specified limit value, the counting chain 15 is in each case between two fixed quantity

Here, P means the electrical power, Γ the quantity knobs completely filled. As soon as this is the case, the time interval between two fixed-quantity impulses appears at the output 16 of the last stage of the sen, A the signal from converter 3 to each fixed-quantity 55 counting chain 15, the number output via inverter 18 impulse to totalizer 2 AND gate 4 blocks. The next of the impulse impulses and B the number of impulses per 16 minutes. The fixed quantity pulse generated by the transmitter 1 can therefore be used. The table shows that the flip-flop 6 has no influence. On the other hand, the number of pulses, which is delayed to the zero amount in the totalizer 2 when a certain energy length is drawn, is counted by 60 control input 26 and sets the counting chain 15 back to the greater the greater the electrical line zero.

stung is. If, for example, with a constant At T < T ₀ , if a fixed quantity impulse for an output of 7.5 kW occurs within 8 minutes, the counting chain 15 is not yet filled and an energy quantity of 1 kWh is thus drawn, then the gate 4 does not yet register locked so that the totalizer fixed two pulses. If, on the other hand, the 65 volume pulse flips the flip-flop 6 into the other position, the same amount of energy with an output of 30 kW. The time pulses of the time base generator 11 are consumed within 2 minutes and during the remaining 6 minutes no more energy can be drawn to the counting chain 15, so, however, the oscillator 8 is connected to the counting

P. T A. B. (kW) (Min.) 30th 2 8th 64 15th 4th 4th 16 7.5 8th 2 4th 3.75 16 1 1

chain 15 and also to the totalizer 2 by turning off exactly one revolution in the reverse direction. The frequency of the oscillator 8 is opposite leads, so the filled angle of rotation memory is complete that of the time base generator 11 is discharged as high as possible.

chosen. The counting chain 15 therefore becomes full very quickly. At T <CT ₀ , a fixed quantity pulse occurs before

counted. As soon as it is filled and the rotation angle memory 28 is completely filled at the output 16 5. There a signal occurs, the flip-flop 6 flips back into but the gear 30 by the rotating step of the returned to its original position. The monostable stepping motor 26 in turn has a predetermined Flipper 19 sets the counting chain 15 with a delay to the rotation angle in the reverse direction Zero and the process starts all over again. the arm 32 with the finger 31 as soon as the memory

After each fixed quantity pulse, the counter 10 28 is discharged. The totalizer 2 is thus coupled to the chain 15 with pulses from the oscillator 8 quickly and fully to the stepping motor 26 as soon as the rotation is counted, if it is not already the angular memory 28 unloaded at this point in time. This leads to the filled is. The required number of pulses drive shaft of the stepping motor 26 one angle of rotation also reaches the totalizer 2. The one from the, which corresponds to the difference T ₀ -T. I parts 4, 6, 8, 9 and 18 existing circuit gives 15 The measuring accuracy of the tariff system

j thus with each fixed quantity pulse a blank of Fig. 3 depends on the constancy of the rotation

j set the counting chain 15 from the corresponding number in steps of the stepper drive 26. Using

I pulse to the totalizer 2. This number of a stepper motor as a stepper drive results

I speaks of the difference T ₀ - T. a simple implementation, but there is a risk of

A non-linear dependency of the on each »o that the individual rotary steps are not exactly the same : Fixed quantity pulse has arrived in totalizer 2. A stepper drive in which this

^] counted number of pulses has been eliminated from the difference T ₀ - T part is shown in FIG. 4 shown.

I can be achieved if the pulse repetition frequency. In FIG. 4 have the same reference numerals as in

I of the time base generator 11 is not constant, but rather the same parts as shown in FIG. 3. The differential

! z. B. after each zero position of the counting chain 15 steadily 25 gear 22 and the downstream components

; falling is chosen. The counting chain 15 is shown in FIG. 4 not drawn to which the

by synchronous motor 24 driving gear 23 at first quickly, then more and more slowly, there is more than a fill. With an appropriate selection of the frequency characteristic shaft 37 and a slip clutch 38, preferably teristics of the time base generator 11, an output shaft 39 of the sizes T and A, for example the one in the front stepping drive 26, can be coupled between a hysteresis clutch. The anchor 40 one; The relationship shown in the table above is achieved by the electromagnet 41 controlled by the pulse generator 1

■ become. blocks an arm 42 fixed on the shaft 39.

In Fig. 3, this is a sun gear 21 of a dif- When a fixed-quantity pulse arrives, the differential gear 22 via a gear 23 to an electromagnet 41 briefly energized and the output synchronous motor 24 coupled. The other solar 35 wide 39 for a certain angular rotation, before- ! wheel 25 is released with a stepper drive 26, here a preferably one full revolution.

'Stepper motor, connected. This is connected to the impulse In Fig. 5 a tariff device is shown.

: encoder 1 connected. To the output shaft 27 of the represents, the mode of action of the one after

; Differential gear 22 is a rotation angle memory of Figure 3 differs; however, the measurement result remains

28 coupled, the one from a rotating on an axis 29 40 the same.

ι bar mounted, driven by the output shaft 27 in FIG. 5 is a synchronous motor 43 via a

j enclosed gear 30 is made, the one in the pivot shaft 44 corresponding to the armature position

i a finger 31 fastened on the axis 29 into an electromagnet 45 to a spur gear 46 or to

! has protruding arm 32. The axle 29 is coupled via a spur gear 47. The spur gear 46 is over

I a slip clutch48 made up of a driver33 and a pawl 34 45, e.g. a friction clutch

' Existing freewheel gear with the summation, connected to a driver shaft 49. on

! counter 2 connected. A ratchet wheel 35 and a ratchet - this is attached to a gear wheel 50 which has an arm 51

1 spring 36 prevent the sum from running backwards, which when the

i mier counter. Driving axis 49 from a zero position against one

j The tariff system described works like 50 stop 52 hits. A torsion spring 53 seeks the middle

I follows: Between two fixed quantity pulses the slave axis 49 is in the zero position in each case.

I step motor 26 and thus also the sun gear 25 lead.

of the differential gear 22 still. The synchronous gear 50 meshes with a sun gear 54

Motor 24 drives the sun gear 21 with a constant differential gear 55, the second solar angular velocity at. As a result, the rotary wheel 56 is connected to a measuring shaft S7. On your ! Angular memory 28, the storage capacity of which is somewhat output shaft 58 of differential gear 55

i includes less than a full turn, steadily attached to the pinion 59, in which a on the pivot shaft c

I loaded. When the memory is full, the 44 mounted locking lever 60 engages when di <

j arm 32 the finger 31 with, and further rotations pivot axis pivoted upwards, d. H. with de:

1 are lost in freewheeling 33,34. ^6o driver axis 49 is coupled.

j The time required to fill the reservoir 28. Another connected to the locking lever 60

Here, too, i corresponds to the reference _{variable T 0} , which engages in a pinion 62 through locking lever 61 when di

j corresponding setting of the gear 23 arbitrarily pivot shaft 44 is pivoted down Da

j can be chosen. When T Ξ> T ₀ occurs a fixed pinion 62 is on the output shaft 63 of a differential

1 volume pulse each only on, after the storage ~ ⁶ S tialgetriebes attached 64th The one sun gear 6

is rather filled Here, the stepping motor 26 leads this differential gear meshes with the Stirnra even step of a given length. The device 47, which is rigidly connected to the measuring shaft 57 i tion is tuned in such a way that thereby the gear wheel The second sun gear 66 of the differential gear ti

ίο

is in mesh with a spur gear 67. This is via an idle memory 68 with the totalizer 2 associated with game. The idle travel memory consists of one on the drive shaft of the totalizer 2 attached driver wheel 69 with an elongated hole 70 in which a arranged on the spur gear 67 Pin 71 engages. A return spring 72 is clamped on the spur gear 67 and on the driver gear 69. On the drive shaft of the totalizer 2, a ratchet 73 is also attached, which together with a spring 74 engaging in this a detent forms.

The measuring shaft 57 is via a pair of wheels 75 to a Cam disk 76 is coupled, the switching cam 77 of which actuates a changeover switch 78. As a pulse generator 1 is Another switch is provided here. One of the two switching contacts of the switch 1 is each with connected to one of the switching contacts of the switch 78. The switching arm of the switch 78 is on the excitation winding of the electromagnet 45 is connected.

The tariff system according to FIG. 5 works as follows: between two fixed quantity pulses, the electromagnet 45 is not energized, and the pivot shaft 44 is in the position shown. The measuring shaft 57 is coupled to the synchronous motor 43 via the differential gear 55, the driver shaft 49, the friction clutch 48 and the swiveling shaft 44 and is driven by this at a constant angular speed. The output shaft 63 of the differential gear 64 coupled to the measuring shaft 57 is not blocked, so that the totalizer 2 stands still. If T;> T ₀ , after a predetermined _{time corresponding to the reference variable T 0} , the arm 51 is at the stop 52, so that the driver shaft 49 and the measuring shaft 57 come to a standstill, while the synchronous motor 43 can continue to rotate unhindered as a result of the friction clutch 48. The cam disk 76 coupled to the measuring shaft 57 is set in such a way that the switching cam 77 is just unable to actuate the changeover switch 78 when the arm 51 hits the stop 52.

After a fixed amount has been consumed, a fixed amount pulse occurs, ie the pulse generator 1, which is designed as a changeover switch, switches over. This is about the order? : holder 78 and the excitation winding of the electromagnet 45 closed a circuit, and the armature of the electromagnet pivots the pivot shaft 44 downwards. The measuring shaft 57 is now coupled directly to the synchronous motor 43 via the pivot shaft 44, and the locking lever 61 locks the output shaft 63 of the differential gear 64, so that the totalizer 2 via the idle travel memory 68, the differential gear 64, the measuring shaft 57 and the pivot shaft 44 as well is coupled to the synchronous motor 43. The connection from the synchronous motor 43 to the driver shaft 49 is now interrupted, as a result of which the torsion spring 53 can turn the driver shaft 49 back into the zero position. The measuring shaft 57 is driven by the synchronous motor 43 until the switching cam 77 tilts the switch 78, the electromagnet 45 drops and the shaft 44 is pivoted upwards again. BjK t ^ % Wd here the measuring shaft 57 only make a small angle because - like * i | etfkhat, - ^ the switch 78 was already before the iäs lFesäiiengenm% iäsK kotz before the switch. This slight rotation of the measuring shaft 57 is recorded by the idle travel memory 68 and is therefore not transferred to the totalizer 2.

In contrast, if T <CT _a , a fixed quantity pulse occurs before the arm 51 touches the stop 52. When the pivot shaft 44 is pivoted downwards, the synchronous motor 43 rotates the measuring shaft 57 by an angle of rotation until the switch 78 tips over,

ίο which corresponds to the difference T _a - T. This angle of rotation is transferred to the totalizer 2.

Of course, the transmission ratios of the device described must be selected such that the measuring shaft 57 is driven at a relatively high angular speed when the pivot shaft 44 is pivoted downwards, so that the time span between the occurrence of a fixed-quantity pulse and the response of the changeover switch 78 neglects the time span T ₀ .

is casually small.

In the tariff devices according to FIGS. 3 and 5, the output variable given as the angle of rotation of the converter connected between the pulse generator 1 and the totalizer 2 corresponds to the difference T ₀ - T. Difference T ₀ -T can be achieved if the output speed of the synchronous motor 24 or 43 is not constant, but rather

z. B. chosen continuously falling within each given by two fixed-quantity pulses measurement period will. This can be done, for example, by a gear unit with non-linear transmission characteristics connected downstream of the synchronous motor every fixed quantity pulse is returned to its original position. Gearboxes of this type are known and therefore do not need to be explained in more detail here. There is another advantageous possibility in feeding the synchronous motor with a voltage, the frequency of which during each between two Fixed quantity pulses lying time interval falls steadily.

Finally, it should be noted the possibility that in the tariff institutions according to the F i g. 3 and 5, the synchronous motor 24 or 43 can be shut down with the aid of a switch when the rotation angle memory 28 (FIG. 3) is filled at T ^ T ₀ or the arm 51 (FIG. 5) is looking at the stop 52. This can significantly increase the service life of the device.

In FIG. 6 shows a block diagram of a tariff device, its between the pulse generator 1 and the totalizer 2 switched converter on each fixed quantity pulse one of the size

55

proportional number of pulses generated. A constant current source 79 is connected to the input of an Inte grators80, the output of which is connected via in of Pulse generator 1 controlled switch 81 connected to a scarf tungsgüed 82 for reciprocal value formation is. A switch 83 is provided for discharging the integrator 80, which is also operated by the pulse generator 1 g ( is controlled. The output of the circuit element 8 leads via a differential amplifier 84, a quadrie

member 85 and an analog-to-digital converter 86 to the summing counter 2, which is a pulse counter here. In addition to the output voltage of circuit element 82, differential amplifier 84 is supplied with a reference voltage U _R which is proportional to the reciprocal value of reference variable T _0. A connection leads from the output of the differential amplifier 84 via a zero threshold switch 87 to a pulse counter 88.

Switches 81 and 83 are open between two fixed quantity pulses. A time-proportional voltage is formed at the integrator 80. After a fixed amount has been consumed, the switch 81 closes briefly, and the voltage proportional to the variable T reaches the circuit element 82 which forms the reciprocal of this voltage. At the output of the differential amplifier 84 there is a size

i_ _JL \

TT ₀ )

proportional signal, which is converted by the squaring element 85 oi.oHriprf, mil by the an? loe-digital converter86 into a proportional number of pulses which are cumulated with uuiiiiiiicizatuer i. The switch 83, which responds with a delay to a fixed quantity pulse, now closes briefly and discharges the integrator 80, whereupon the process described begins anew. 3 »

The zero threshold switch 87 outputs a pulse to the pulse counter 88 when

1 _L
T ^> T ₀

35

is. The pulse counter 88 thus shows the number of fixed quantities that have a greater average power than the specified reference power were consumed.

When the energy supplier reads the tariff device described, the mean square deviation s of the electrical power from the reference power in the event of an overload can be obtained from the two meter readings using the formula

are calculated, where «, the count of the totalizer 2 and n ₂ that of the pulse counter 88 means.

In FIG. 7 is a capacitor 103 to which a resistor 104 is connected in parallel through a Switch 105 controlled by pulse generator 1 and a resistor 106 to a voltage source 107 and via a switch 108, also controlled by the pulse generator 1, to the input of an analog-to-digital converter 109 switched. The totalizer 2 is connected to its output.

The pulse generator 1 first briefly closes the switch 108 with each fixed quantity pulse and then briefly the switch 105. When the switch 105 is closed, the capacitor 103 is out of the Voltage source 107 quickly charged to a constant voltage. Here the resistance limits 106 the charging current; however, the charging time constant is opposite to the smallest possible distance two fixed quantity pulses chosen to be negligibly small. The switches 105 and 108 are each between two fixed-quantity pulses open, so that the capacitor 103 via the resistor 104 slowly discharges again. As already mentioned, when the following fixed quantity pulse occurs, the first one closes Switch 108 and applies the capacitor 103 to the input of the analog-digital converter 109. This generates at its output a number proportional to the voltage or the charge of the capacitor Pulses that are accumulated by pulse counter 2. Then the capacitor 103 is from the Voltage source 107 is recharged and the process begins again.

The tariff system according to FIG. 7 is characterized by an extremely simple structure. To discharge the capacitor 103, instead of the resistor 104, an impedance with a non-linear dependence between current and voltage or a constant current source can also be used. The relationship between the time interval T between two fixed quantity pulses and the number of pulses delivered to the totalizer 2 changes accordingly.

For this purpose 4 sheets of drawings

Claims (21)

Patent claims: 1. Performance-dependent tariff system with a pulse generator controlled by an electricity meter to generate consumption a solid volume indicating solid volume pulses and with one coupled to the pulse generator Totalizer, characterized in that between the pulse generator (1) and the Suramier counter (2) a converter (3) is connected to each fixed quantity pulse outputs such an output variable to the totalizer (2) that the totalizer (2) by one of the time interval between the fixed quantity pulse the amount depending on the previous fixed quantity pulse is switched on. 2. tariffing device according to claim 1, characterized in that the converter (3) such is designed that the totalizer (2) on each fixed quantity pulse by one of the reciprocal the time interval between the fixed quantity pulse and the preceding fixed quantity pulse linear or non-linear dependent amount is advanced. «5 3. Tariffing device according to Anspruqh 1, characterized in that the converter (3) such is designed that the totalizer (2) on each fixed quantity impi'Is by one of the Difference between a specified reference variable and the time interval between the fixed quantity pulse a linear or non-linear dependent amount is switched on to the preceding fixed quantity pulse. 4. tariffing device according to claim 1, characterized in that the converter (3) such is designed that the totalizer (2) on each fixed quantity pulse by the amount T ₀ 40 is switched on, where T is the time interval between the fixed-quantity pulse and the preceding fixed-quantity pulse and T _{0 is} a predetermined reference value. 5. tariffing device according to one of claims I to 4, characterized in that the output of the converter (3) is a pulse train. 6. tariffing device according to one of claims 1 to 4, characterized in that the Output variable of the converter (3) given as the angle of rotation of a drive shaft of the totalizer (2) is. 7. Tarifiereinriphtung according to Claims 3 and 5, characterized in that the converter (3) has a counting chain (IS) into which time pulses generated by a time base generator (11) during each time interval between two fixed quantity pulses are paid, and that a circuit (4, 6, 8, 9, 18) is provided, which generates a number of pulses corresponding to the spaces in the counting chain (15) for each fixed quantity pulse (FIG. 2). 8. tariffing device according to claim 7, characterized in that the pulse repetition frequency of the time base generator (11) is constant. 9. tariffing device according to claim 7, characterized in that the pulse repetition frequency of the time base generator (11) during each lying between two fixed quantity pulses Time interval increases steadily. 10. tariffing device according to claims 3 and 6, characterized in that the converter (3) has a rotation angle memory (28), which during each between two fixed quantity pulses lying time interval is continuously charged by a synchronous motor (24), and that a stepper drive (26) controlled by the pulse generator (1) is provided which, with each fixed quantity pulse executes an angle of rotation of a predetermined length and thereby discharges the angle of rotation memory (28), and that also the totalizer (2) is coupled to the stepper drive (26) via the angle of rotation memory (28) in such a way that it is only driven by the stepper drive (26) when the angle of rotation memory (28) is unloaded (FIG. 3). 11. tariffing device according to claim 10, characterized in that an output shaft (39) of the stepper drive (26) is coupled to a motor (24) via a slip clutch (38) and that an electromagnet (41) is provided which, in the non-energized state, the output shaft (39) blocked (Fig. 4). 12. tariffing device according to claims 3 and 6, characterized in that the converter (3) has a Meßwellc (57) which is controlled by a from the pulse generator (1) gearbox (44 to 56) is coupled to a synchronous motor (43) in such a way that the measuring shaft (57) during each between two fixed-quantity impulses continuously, but at most up to one specified angle of rotation and with each fixed quantity pulse with increased angular velocity is continued to rotate until the predetermined angle of rotation is reached, and that the totalizer (2) continues to rotate the measuring shaft (57) is coupled to it (FIG. 5). 13. Tariffing device according to claim 12, characterized characterized in that the gearbox (44 to 56) comprises an electromagnet (45), which in the non-excited state the measuring shaft (57) via a slip clutch (48) and a driver shaft (49), the angle of rotation of which is limited by a stop (51, 52), to the synchronous motor (43) couples (Fig. 5). 14. tariffing device according to claim 13, characterized in that one of the measuring shaft (57) controlled changeover switch (78) is provided, which controls the excitation circuit of the electromagnet (45) interrupts when the specified angle of rotation is reached (FIG. 5). 15. tariffing device according to claim 10 or 12, characterized in that the speed of the synchronous motor (24, 43) is constant. 16. tariff device according to claim 10 or 12, characterized in that the frequency the supply voltage of the synchronous motor (24, 43) during each between two fixed quantity pulses lying time interval increases steadily. 17. tariffing device according to claim 10 or 12, characterized in that the synchronous motor (24, 43) a gear with non-linear transmission characteristics downstream tet is such that the speed of the output The usual mechanical overconsumption counter shaft of the transmission while each between two has a differential gear that is between the Fixed quantity impulses lieger the rotor of an electricity meter and a synchronous steadily increasing motor is connected The differential gear drives, 18. Tariffing device according to claims 4 5 if the speed of the counter rotor is greater than one and 5, characterized in that the converter by the synchronous motor given reference variable (3) is an integrator (80) for forming a time, a summing counter. This registers the proportional voltage that from the Im- overconsumption Ue according to the relationship pulse generator (1) controlled switches (81, 83) for sampling this voltage and for discharging the io Ue = ^k ( ^P ~ ^P «) Integrator (80) are provided and that the ρ ' Integrator (80) via a circuit member (82) for Reciprocal value formation, a subtraction circuit where P is the electrical power, P _{0 is} the specified (84) and a squaring element (85) at an analog power limit value and k is a constant Digital converter (86) is connected (Fig. 6). 15 indicates. Also in this known device is the 19. Tariffing device according to claim 18, since loading the counter rotor disadvantageously. characterized in that the output of the It is known electricity meter with an Im subtraction circuit (84, 92) to be equipped with a sound pulse generator, each after the vertebral element (87, 95) to a pulse counter (88) need a predetermined fixed amount of a pulse is connected, which emits in each case with a positive output 20 Based on the fact that such input signal the subtraction circuit (84, 92) pulse generator without any further "load" or even legs Emits impulse (Fig. 6). can be coupled to the counter rotor without load 20. Tariffing device according to claim 18, were already overconsumption indicator or 19, characterized in that _{proposed to the r} gte (CH-PS 4 79 875), in which an output of the subtraction circuit (84, 92) a 25 the electricity meter assigned pulse generator maximum value memory (94) is connected is used. Here are those from the pulse (Fig. 6). encoder generated fixed quantity pulses each then in 21. Tariffing device according to Claims 2, a counting device is counted in when the distance and 5 or 3 and 5, characterized in that between the pulses a predetermined reference value of the transducer (3) falls below a capacitor (103) up to 30 value. Thus, the counter registers that via a first switch (105) controlled by the pulse generator (1) direction that portion of the energy consumed is drawn from a voltage with a higher than the specified limit source (107) and via a second from the power supply became. Pulse generator (1) controlled switch (108) to a further, an overconsumption meter is known Analog-to-digital converter (109) is connected. 35 (FR-PS 14 75 885), in which the fixed quantity pulses generated by an electricity meter within a predetermined measuring period in a preset can be counted in using a pulse counter. If the Number of impulses exceeds the preselected value, the impulse counter releases another counter that counts the The invention relates to a power-dependent tariff device that still arises within the measurement period registered with a fixed quantity pulse from an electrician. Here the ity counter-controlled pulse generator to generate power exceeding a specified value of the consumption of a fixed amount not immediately recorded by measuring technology, but the Um-fixed amount pulses and with one with the obstacle to the integration of the performance via a defipulsgeber coupled totalizer. ned, selectable time range from 1 ms to 10 s Suppliers of electrical energy are made on a permanent basis. This implies a relatively high As uniform energy consumption as possible, inter- imouls rate of the fixed quantity impulses ahead, which allensates. They therefore generally apply tariffs which, if with an electronic electricity meter, based on the energy consumed, but not with a conventional Ferrari meter gen element and from one depending on the performance can be realized. Gigen link assemble For the definition of the invention is based on the object of a Consumption-independent Tarifglieaes were already performance-dependent tariffing device under Ver many Measuring devices proposed by using an electricity meter assigned In practice, only the maximum counter and 55th fixed quantity impulses to create their counters so-called over-consumption counter, a directly evaluable measure for the could put. Determination of the tariff dependent on the performance Maximum counters have a driver which represents a member and which, in principle, can be used for both rather, the processing of fixed quantity pulses with high during constant measuring periods on the rotor an electricity meter is coupled and a 60 pulse rate as well as those with very low Maximum pointer moves forward. At the end of each pulse rate · is equally suitable. Measurement period, the driver is put back, while a tariff device of the aforementioned rend the maximum pointer stops and thus the ArJ at which this task is solved is the highest according to the invention average power of the preceding measurement according to characterized in that between the Indicates periods. A disadvantage of this maximum pulse generator and the totalizer is a converter counter is the unavoidable considerable load of the switches, which is one on each fixed quantity pulse Counter rotor. Also for reasons of collective bargaining policy, he sends such an output variable to the totalizer, the maximum counter often does not like to satisfy. that the totalizer by one of the time