DE1939165A1 - Overconsumption indicator - Google Patents

Description

Over-consumption display device The invention relates to an over-consumption display device for electrical power, with a threshold value element to determine the non-consumption and with a step element that defines the permissible consumption limit according to the specified Criteria automatically increased if the same is exceeded.

Suppliers of electrical energy are interested, if possible to deliver a lot of energy with the lowest possible maximum power. The application applicable tariffs set sioh in general from one of the related, Energy-dependent member measured with counters and a power-dependent element Collective bargaining member together. For the definition of the consumption-independent tariff element Up to now, maximum counters have mostly been used, which is associated with a great deal of effort is.

It is also known through the use of current limiters for this to ensure that the maximum output to which a consumer is entitled is not exceeded will. Such a power limitation and the disconnection of the consumer from However, energy distribution network when the power limit is exceeded are in many Cases undesirable.

To avoid these disadvantages, the use of a device suggested which measures the drawn current instead of the power. At this known device, a timer is set in motion; as soon as the current one exceeds the specified threshold. After a predetermined time has elapsed a higher current level is automatically switched on by means of a step switch. If the current drawn is below this new threshold value, the current remains The step switch is in the switch position that has been reached.

However, if the mains current is above the mentioned level or increases at a later point in time beyond the stage, the timer is again set in motion and so on reached switching stage a sign that the step value of the mains current assigned to the previous switching step has been exceeded during a certain period of time.

The determination of the basic tariff based on the purchased electricity However, the current is only available at constant voltage and constant power factor in relation to the purchased service.

It is known that the electrical energy consumed with an electronic To determine energy meter, which has no mechanically moving parts. Included is done with the help of a power meter, which is usually made up of a multiplier Formation of the product from current and voltage and from an analog-digital converter exists, a pulse train with the power proportional pulse repetition frequency is generated. The number of pulses occurring within a measurement period is a measure of the electrical energy consumed. The invention is based on the object Over-consumption indicator using such electronic power to create a knife.

The invention is characterized in that the input of the threshold value element is connected to a power meter, which is a pulse train with the reciprocal value the power output period that is proportional to the threshold value element so is designed that it responds when the period has a predetermined threshold value falls below, and that the pulse train or a reference pulse train when responding of the threshold value element is fed to a pulse counter which, when a a predetermined number of pulses triggers the switching of the stage element.

Some exemplary embodiments of the invention are illustrated below the drawings explained in more detail.

They show: FIGS. 1, 3 and 5 ″ block diagrams and FIGS. 2, 4 and 6 Diagrams.

In Fig. 1, a power meter 1 is shown, which consists of a Multiplier 2 to form the product of current I and voltage U, from one Analog-digital converter 3 for the formation of a pulse train with the reciprocal value of the power U.I proportional period T and consists of a frequency divider 4. The output of the power meter 1 is connected to an input terminal 5 of a threshold value element 6 and connected to an input 7 of an AND gate 8, the other input of which 9 is connected to the output terminal 10 of the Schwellwetelementes 6.

The input terminal 5 of the threshold value element 6 is connected to a monostable Connected multivibrator 11, which controls a switching transistor 12. The collector-emitter streoke the same, a capacitor 13 and an input of a threshold switch 14 are in parallel switched, the output of which is connected to output terminal 10. The condenser 13 is charged with a constant current I1 by means of a current source 15.

The output 16 of the AND gate 8 is connected to a pulse counter 17, which advances a stage element when a predetermined number of pulses n is reached, that by a tariff counting chain 18 and a decoding matrix 19 assigned to it formed with a tariff level display not shown in the drawing is. The decoding matrix 19 controls the storage capacity via output lines 20 n of the pulse counter 17 and via an output line 21 the current I1 of the current source 15 depending on the respective tariff level. The pulse counter 17 and the tariff counting chain 18 can by pressing a button 22, which is only for the staff of the energy supplier accessible, can be set to zero.

The power meter 1 can be connected to a pulse counter 23 for determination connected to the consumed electrical energy.

The operation of the described overconsumption display device is explained below with reference to FIG. 2, in which voltages U1 to U5 in Function of time t are shown.

At every negative edge of the voltage pulses generated by the power meter 1 U1, the monostable multivibrator 11 is triggered and the capacitor 13 is triggered briefly unload. The capacitor 13 is then charged again by the current 11; the voltage U3 at the input of the threshold switch 14 increases linearly and reaches counted from the beginning of the capacitor discharge, the threshold value U of the threshold switch 14 after the comparison time t0.

If after a capacitor discharge the next one from the power meter 1 emitted pulse only occurs when threshold switch 14 has responded, so this pulse cannot pass through the AND gate 8. On the other hand, it is the period duration T of the voltage U1 is less than the comparison time T0, the AND gate 8 is permeable, because the capacitor 13 is discharged again before the threshold switch 14 respond can.

The pulse counter 17 thus counts those from the power meter 1 pulses output whose distance T to the previous pulse is less than the comparison time T0, i.e. he forms the time integral of the performance P, if a specified power threshold P5 is exceeded. For those to achieve the number of pulses n required time ts, the relationship tS # n / n applies. For P = PS, tS = t @@@ = N'TS.

When the number of pulses n is reached, the pulse counter 17 emits an incremental pulse to the tariff counting chain 18. The decoding matrix 19 now increases on the one hand over the Output line 21 increases the current I1 by one step, as a result of which the comparison time T0 is reduced will. On the other hand, the decoding matrix 19 effects a via the output lines 20 Increase in the number of pulses n by the same amount, so that tmax = n # t0 remains constant.

The quantities n and T0 can be kept constant if the frequency divider 4 has several outputs with different reduction ratios, which are carried out by Switches controlled by the decoding matrix 19 are optionally tapped and connected to the inputs 5 and 7 can be switched.

In Fig. 3, a threshold element 24 is shown, which in the Fig. 1 takes the place of the threshold value element 6 and after a purely digital one Principle works. The same parts as in FIG. 1 are given the same reference numerals Mistake.

A pulse generator 25 is via a frequency divider 26 to a Reset input 27 of a bistable multivibrator 28 connected, whose Output 29 is connected to output terminal 10 of Schwellwetelementes 24. Whose Input terminal 5 is connected to a reset input 30 of the frequency divider 26 and Connected via a delay element 31 to a control input 32 of the flip-flop 28. The decoding matrix 19 (FIG. 1) controls the reduction ratio via the output line 21 m of the frequency divider 26.

The pulse generator 25 is a reference pulse train with constant Period duration TR to the frequency divider 26.

This is corresponding with each pulse generated by the power meter 1 4, in which the voltages U1, U5, U6 and U7 are shown as a function of time are reset to zero. The trigger stage 28 is somewhat delayed in the logical State L tilted. After the comparison time T0 = m # TR occurs at the output of the frequency divider 26 an L signal, which the flip-flop 28 zurtekstellen so that the AND gate 8 is blocked will. The pulses emitted by the power meter 1 can therefore only be sent to the input of the pulse counter 17 arrive when the condition T <T0 is met. When switching forward of the tariff counting chain 18, m and thus also T0 are reduced by one level.

5 is a block diagram of an overconsumption display device shown in which the cumulative excess duration tS, during which the activated performance threshold is exceeded without the tariff increase is independent of the amount of excess. Same parts as in previous figures are again provided with the same reference numbers.

The output of the power meter 1 is via a frequency divider 33 is connected to a control input 34 of a bistable multivibrator 35, the output of which is connected to an input 36 of an AND gate 57. A pulse generator 38 is to an input 39 of the AND gate 37 and via a delay element 40 to one Reset input 41 of the frequency divider 33 and to a reset input 42 the flip-flop 35 connected. The elements 33, 35J 38 and 40 are components a threshold value element 43.

An output 44 of the AND gate 37 is led to the pulse counter 17, which when the number of pulses n is reached via that formed by the elements 18 and 19 Step element an increase in the reduction ratio m of the frequency reducer 33 causes.

In Fig. 6, voltages U1 and U8 to U10 are described Non-consumption display device shown, which operates as follows; Of the Pulse generator s generates a reference pulse train B8 with a constant period TR. . The power meter 1 gives its output pulses to the frequency divider 35 from; after m pulses, a signal is produced at the output of the frequency divider 33, that sets the flip-flop 35, if a reference pulse has not occurred previously is which via the delay element 40 the frequency divider 41 is reset Has. The flip-flop 35 is set when the condition T0 # TR> m # T is met The next reference pulse then advances the pulse counter 17 by one digit and resets the frequency divider 33 and the bistable multivibrator 35 with a delay. As soon as the pulse counter 17 after the cumulative duration tS = n # TR n reference pulses has counted, the tariff counting chain 18 switches on and the reduction ratio m is increased by one level.

Claims (10)

PATENT CLAIMS 9 overconsumption indicator for electrical power, with one Threshold element for determining the overconsumption and with a step element, which automatically increases the permissible consumption limit value according to defined criteria, if the same is exceeded, characterized in that the input of the threshold value element (6; 24; 43) is connected to a power meter (1), which a pulse train (U1) emits with the reciprocal value of the power proportional to the period duration (T), since the threshold value element (6; 24; 43) is designed in such a way that it responds, if the period (T) falls below a predetermined threshold value (T0), and that the pulse train (U1) or a reference pulse train (U8) when responding of the threshold value element (6; 24; 43) a pulse counter (17) suggests iot, the when a predetermined pulse is reached, the step element is switched on (18, 19) triggers. 2. Overconsumption display device according to claim 1, thereby marked, that the threshold value element (6) has a capacitor (13) which is one of the Power meter (1) controlled discharge switch (12) and the input of a threshold switch (14) is connected in parallel and connected to a power source (15). 3. Overconsumption device according to claim 1, characterized in that that the threshold value element (24) has a pulse generator (25) which has a Frequency divider (26) to a reset input (27) of a bistable Xippstufe (28) is connected, and that the output of the power meter (1) with a Reset input (30) of the frequency converter (26) and via a delay element (31) is connected to a control input (32) of the bistable flip-flop (28). 4. Overconsumption display device according to claim 2 or 3, characterized in that that the output (10) of the threshold value element (6; 24) to a first input (9) of an AND gate (8) is connected, the second input (7) with the Output of the Beistungameseer (1) and its output (16) with the pulse counter (17) connected is. 5. Overconsumption display device according to claim 1, characterized in that that the threshold value element (43) has a pulse generator (38), the over a delay element (40) to a reset input (42) of a bistable multivibrator (35) and connected to a reset input (41) of a frequency reducer (35) is, and that the output of the power meter (1) via the frequency divider (33) is connected to a control input (34) of the bistable tilting stage (35). 6. Overconsumption display device according to claim 5, characterized in that that the bistable multivibrator (35) is connected to a first input (36) of an AND gate (37) is connected, the second input (39) to the pulse generator (38) and whose output (44) is connected to the pulse counter (17) * 7. Overconsumption indicator according to claim 1, characterized in that the step element by a counting chain (18) and a decoding matrix (19) assigned to it is formed. 8. Overconsumption display device according to claim 1 or one of the claims 2, 3, 5 and 7, characterized in that one in the output of the power meter (1) switched frequency reducer (4; 33) one controllable by the step element (18, t9) Reduction ratio is shown. 9. Overconsumption display device according to claim 2, characterized in that that the current (I1) of the current source (15) and the fit (n) of the pulse counter (17) are gradually changeable by the step element (18, 19). 10. Overconsumption display device according to claim 3, characterized in that that the reduction ratio of the frequency reducer (26) and the capacity (n) of the pulse counter (17) can be changed in steps by the step element (18, 19) are. Blank page