DE2258174C3 - Circuit arrangement for monitoring the heating of current-carrying protégés - Google Patents

Description

The present invention relates to a circuit arrangement for monitoring the heating of current-carrying protégés, in particular motors and transformers according to patent 45 605, which converts the currents to be monitored into a voltage, which a voltage frequency converter is converted into pulses that have a frequency proportional to the square of the currents and a Storage member are supplied, after reaching tines certain memory contents a via a Switching stage controlled switch in the circuit of the protégé can be triggered

The solution according to the patent 22 45 605 is that in the multi-stage up-down counter executed memory element the pulses are supplied to the forward number input that its Downward counting input the pulses from a generator running at a given constant frequency are supplied that the predetermined frequency of the generator is dimensioned in such a way. that they are in the area permissible currents greater than the frequency of the voltage frequency converter is that of the up-down counter emits a stop signal to the generator when it reaches its zero position, and that the Output pulses fed to one of the outputs of the multi-stage up / down counter of the switching stage are.

The payments made in the forward direction correspond Impulses of the loss generated in the protégé

to heat, while the incoming in the reverse direction The impulses of the heat emission, i.e. the dissipated heat loss, are adapted. With increasing performance and thus increasing pulse frequency in the forward direction, the temperature in the protégé rises until one Limit temperature, which corresponds to a certain counter reading, a shutdown takes place

As an up / down counter in the main patent, an integrated module in IIL technique can be used. Such meters, however, have a relatively high sensitivity to interference, d. H. Interfering impulses of any kind - but especially high-frequency ones - can interfere with the counting process falsify in such a way that too great or too little heating of the current-carrying protégé is simulated will. The required reliable monitoring of the heating is made very difficult

The semiconductor industry now has forward-backward counters in CMOS technology (also integrated circuits) developed by the company are less sensitive to interference These meters require a different control because they have a single Have counter input with a special directional input.

From AEG-Mitteilungen 58 (1968). Pp. 372 - 375> t

a monitoring circuit has become known in which the current is converted into a proportional voltage in a rectifier circuit with a downstream shunt. This voltage w ^; rd squared in a squaring circuit and then converted into pulses Dip pulses charge a downstream capacitor of an ÄC element in such a way that the voltage on the capacitor is a measure of the temperature of the current-carrying line The capacitor is followed by a threshold value stage with an adjustable threshold value the set threshold value on the capacitor, ie, if the temperature of the line to be monitored, through which current flows, reaches its maximum permissible value, the threshold value stage emits an off signal, whereby the line current is switched off. The pulse frequency is given as a quadratic function of the current value.

The disadvantage is that the thermal time constants of the protégés to be monitored, which are in the order of magnitude of 10 ³ seconds, can only be electrically simulated with great effort. In addition, the simulation of such large thermal time constants by electrical means requires very high insulation resistances, which can only be achieved through special measures, such as potting with synthetic resins.

The object of the additional invention is to provide an alternative to the initially mentioned solution according to patent 22 45 605 To create circuitry that the after

f> * Main patent is equivalent, but above In addition, with essentially the same effort, an additional security against influences due to Provides glitches

According to the invention, this object is achieved in that, as a multi-stage up-down counter executed memory element these pulses and the pulses of a generator its common Apply counting input that at the directional input of the up-down counter one of the Pulses of the voltage frequency converter and / or the generator derived voltage or a Auxiliary DC voltage is that the predetermined frequency of the generator is dimensioned such that it is in The range of permissible currents is greater than the frequency of the voltage frequency converter that the up-down counter emits a stop signal to the generator when it reaches its zero position, and that the Output pulses fed to one of the outputs of the multi-stage up / down counter of the switching stage are.

The invention is illustrated below with reference to two in FIGS. 1.2 of the drawing illustrated embodiments explained in more detail.

F i g. 1 shows the block diagram of an exemplary embodiment in which the voltage at the directional input of the up / down counter of uen impulses of the Voltage frequency converter and the generator is derived

F i g. 2 shows an embodiment in which the voltage at the direction input of the up / down counter is derived from a fixed voltage and from the pulses of the generator

In Fig. 1, 1, Γ detected 1 "lines, de ^r s streams of the main current transformers 2 and intermediate current · converters 3 are fed. An resistors 4, these currents into voltages reshaped which are rectified in a rectifying circuit 5. A Spannungsfrequenzumformer 6 converts These pulses control, via a first decoupling resistor 36, the direction input 9 of an interference-insensitive up-down counter 27 consisting of two counting stages 24, 25 and also act on the counting input 7 of the first OR circuit 34 Up / down counter 27. The pulses from a generator IO also control the direction input 9 via a negation stage 35 and a second decoupling resistor 37 and also act on the counting input 7 of the counting stage 24 via the first OR circuit 34. Each counting stage 24, 25 of the up / down counter 27 has four outputs 11-14 and 15-18, respectively a second OR circuit 26, the output of which controls the generator 10. Einei.i output 28 of the counting stage 25 is followed by a switching stage 19 which acts on a relay 20 and a third OR circuit 21 the reset impulses for the counting stages 24, 25 at their reset inputs 8, 23. The second input signal for the third OR circuit 21 is derived from the operating voltage UB by means of a trigger circuit 22

At the beginning of the measurement, the outputs 11-18 are reset to zero, whereby the output of the OR circuit 26 supplies an output signal blocking the generator 10. When the motor M is switched on, a voltage appears at the output of the rectifier circuit 3, which is converted into pulses in the voltage frequency converter 6 whose frequency increases quadratically with the currents to be monitored.

The pulses arrive via the first OR circuit 34 on the one hand on the counting input 7 of the counting stage 24, on the other hand, a voltage is derived from them as a directional decision on the directional input 9 is given. This voltage is positive, as a result of which the counting stage 24 receives the pulses of the Voltage frequency converter 6, which are present at the counter input 7, counts upwards

ίο first pulse as L signal at output 11 of the counting stage 24, as a result of which a sin L signal is also present at the output of the OR circuit 26, which starts the generator 10 Its pulses also reach the common counter input via the OR circuit 34

On the other hand, by means of the negation stage 35 and the second decoupling resistor 37, a voltage is derived which is applied to the direction input 9. This voltage is negative, as a result of which the pulses from the generator 10 are counted down. The first pulse of the generator 10 thus causes the previously recorded first 1 pulse of the voltage frequency converter 6 to be paid back to zero. As long as the 1-frequency of the jTipuise of the voltage frequency converter 6 is less than the frequency of the pulses of the generator 10, there is a constant change between the zero and /. Signal at the output U, while the other outputs constantly have a zero signal. The adjustable frequency of the generator 10 corresponds to the value of the currents through the lines 1, Γ, 1 ″, from which the monitoring of the motor for heating is desired

If the frequency of the voltage frequency converter 6 exceeds the frequency of the generator 10, then After a certain time, pulses pass through the counting stages 24, 25 to output 28. With the increase of the currents in lines 1, Γ, 1 "takes the frequency of the pulses from the voltage frequency converter 6 to rapidly, while the generator 10 counts down with the once set constant frequency. With the increase in the currents in lines 1, Γ, 1 ", the first pulse also arrives accordingly faster to output 28. This first pulse at output 28 controls switching stage 19, which controls the relay 20 can respond, whereby the lines 1, Γ, 1 "are switched off. It is also possible to use the binary Signals from outputs 12 - 18 of counting stages 24, 25 to switch off the currents in lines 1, Γ, 1 " to use. For this purpose z. B. the switching stage 19 with the downstream relay 20 to the output 16 of the Counting stage 25 connected. A /. Signal on this Output lets relay 20 respond. In this way, the release time is shortened without the Circuit construction changes would have to be made. After a release by the Switching stage 19, the counting stages 24, 25 must be reset to their original position, i.e. Hall Outputs' 1 - 18 must have a zero signal again a Daz'i the output signal of switching stage 19 is over the third OR circuit 21 is fed to the reset inputs 8,23. The counting stages 24,25 are also included switching on the voltage source that controls the operating

b *> voltage UB for the circuit arrangement supplies deferred. For this purpose, a pulse is derived from an operating voltage UB by means of the trigger circuit 22, which via the other input of the third OR switch

device 21 to the reset inputs 8, 23 of the counting stages 24.25 arrives.

tn F i g. 2 shows an embodiment that differs from that shown in FIG. 1 only through the generation of the voltage for the direction input 9 differs. Therefore, only this difference is explained in more detail below, while otherwise on the F i g. 1 is referenced.

The pulses of the voltage frequency converter 6 in turn reach the counting input 7 of the counting stage 24 via the first OR circuit 34. The directional input 9 is now connected to the positive operating voltage UB via a series resistor 38. As a result, the first pulse of the voltage frequency converter 6 is counted up, so that ^{an L signal appears again at the output Ii i 1} , which starts the generator 10. Its impulses in turn reach the counting input 7 via the first OR circuit 34. In addition, a negative voltage is generated by them "iittsls" the Ncsticnsslüfc 35, which - added to the positive operating voltage UB constantly applied to the directional input 9 - at this directional input 9 As a result, the counting stage 24 receives a directional decision, with which the first pulse of the generator 10 is counted down.

So that the pulses of the generator 10 and the voltage frequency converter 6 occur at the same time is largely prevented at direction input 9, the ratio of pulse spacing to pulse duration is the Generator 10 and the voltage converter 6 selected very large.

In a departure from the exemplary embodiments mentioned, it is also possible to use directional input 9 to put an additional resistor constantly at zero potential, so that a control of this input from Generator 10 can be omitted. The voltage frequency converter 6 pulls this input when a pulse is emitted according to plus potential, with which the directional decision

Integrated circuits in MOS technology are primarily used as interference-insensitive counters.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Circuit arrangement for monitoring the heating of current-carrying protégés, especially motors and transformers that convert the monitored currents into a voltage which a voltage frequency converter converts into pulses that are one to the square of the Currents have proportional frequency and are fed to a storage element, after A switch in the controlled via a switching stage reaches a certain memory content Circuit of the protégé can be triggered according to patent 2245605, characterized in that in the case of the storage element designed as a multi-stage up / down counter (24, 25, 27)? Pulses and the pulses of a generator (10) act on its common counter input (7), that at the direction input (9) of the up-down counter (24,25,27) one of the pulses of the S ^ approximation frequency converter (6) and / or the Generator (! 0) derived voltage or an auxiliary DC voltage is that the specified Frequency of the generator (10) is such that it is greater than the range of permissible currents Frequency of the voltage frequency converter (6) is that the up-down counter (27) when When it reaches its zero position, it emits a stop signal to the generator (10), and that the output pulses at one of the outputs (11 to 18, 28) of the multi-stage up / down counter (24, 25, 27) are fed to the switching stage (19) 2. Circuit arrangement according to claim 1, characterized in that the voltage frequency converter (6) and the generator (10) via an OR circuit (34) with the counting input (7) of the Up-down counter (27) are connected. 3. Circuit arrangement according to claim 1, characterized in that the generator (10) has a Negation stage (35) is connected to the direction input (9) of the up / down counter (27) 4. Circuit arrangement according to claim 1, characterized in that the auxiliary DC voltage is the operating voltage (UB) hl.