DE2227252A1 - CIRCUIT ARRANGEMENT FOR DETERMINING THE CONDITION OF A CONSUMER - Google Patents

Description

Circuit arrangement for determining the state of a consumer The invention relates to a circuit arrangement for determining the state of a Consumer.

With control or regulating circuits, such as those in connection have been used with the influence of temperature, pressure and humidity, becomes in practice a Circuit for the energy supply and a Sensing circuit used.

These control circuits generally require separate ones Energy supply lines and sensor lines, because of the space available and Environmental conditions are sometimes difficult or practical not to be separate To lay sensor lines to the consumer area in order to control the consumer to monitor.

In the present invention, there is no need to provide a separate sensor to be to the consumer to be controlled, for example with regard to the temperature, Monitor humidity and / or pressure etc. The consumer, e.g. a with electrically heated vessel filled with a liquid to be treated lies as Active, glare or impedance resistance in a bridge branch of a suitably designed one The bridge and the bridge are supplied with pulses at intervals.

When the consumer changes the balance setting of the bridge has, the exit will be. a comparison circuit supplied. The comparison circuit compares the bridge output with a predetermined, required output level and energizes, if necessary, a switching arrangement to supply current through a separate one Supply circuit for a certain period of time. After the power feed has been switched off again for the consumer, the bridge and the consumer become by means of impulses in order to determine or

ascertain.

The invention is described below on the basis of a preferred exemplary embodiment explained in more detail, with the accompanying drawing with a schematic Sehaltbild is referred to.

In the drawing, the grouped together by dashed lines Main assemblies of the circuit according to the invention a bridge lo, a converter circuit with a comparator circuit 11, a circuit arrangement 12 and a power supply unit 13 on. Although the invention is not necessarily limited thereto, will in the following using the control resp.

Control of the temperature of a heat consumer described.

In Fig. 1, an AC voltage via lines 14 and 15 is the Power supply 13 and the bridge 1o supplied. The bridge has a resistance in one arm 16, a variable potentiometer 17, a resistor 18 and a rectifier diode 19 on. In the opposite arm, the bridge has a consumer with a either negative or positive temperature coefficient of resistance, a resistor 21 and a rectifier diode 22, the cathode of which is connected to the cathode of the diode 19 is. The Brileke is supplied with electricity from a common line 15, which is connected to the resistor 16 and the consumer 20 is connected. On the opposite Side is current from the line 14 through a resistor 23 to the connection point fed between diodes 19 and 22 The exit of the bridge will The comparison circuit 11 is supplied via connections 24 and 25. The bridge output signal at connections 24 and 25, which occurs when the bridge is no longer in equilibrium is, indicates whether the temperature of the consumer 20 is higher or lower than the setting of the calibrated potentiometer 17.

According to a feature of the invention, the bridge is spaced with following pulses fed in order to determine their balance state and thereby to feel the state of the consumer. In the present embodiment the bridge is operated with pulses and a sensing process only takes place when the AC line 15 is positive with respect to the line 14; but it can another pulse mode can also be used. For the determination of the bridge equilibrium assume, for example, that voltage is applied to lines 14 and 15 is that the consumer 2o has a positive temperature coefficient of resistance owns, and da2 the consumer or the temperature at the consumer below the temperature set on potentiometer 17.

If under these circumstances the line 14 is positive with respect to the line 15, then no current flows through the bridge, since it flows through the diodes 19 and 22 is blocked. There is therefore no sensing process.

When line 15 becomes positive with respect to line 14, flows a current pulse through both arms of the bridge and through the respective diodes 19 and 22. Since the consumer 20 has a lower temperature than that on the potentiometer 17 set temperature, its resistance is lower than that of the potentiometer. There is therefore a larger voltage drop across the potentiometer 17 than on the consumer 20.

The bridge output terminal 24 is then more negative than the output terminal 25th

The negative voltage signal on terminal 24 then becomes the negative input 26 of an amplifier 27 in the comparison circuit 11 is supplied. The bridge output terminal 25 is coupled to the positive input 28 of the amplifier.

The amplifier 27 is designed so that its output at a negative Input is positive. The positive output is then via a resistor 29 to the Collector 30 of a transistor 31 and coupled via a diode 32 to a with the common line 15 connected capacitor 33 to charge. The bigger the positive Output des'Verstärkers is, the greater is that built up on the capacitor 33 Tension. The transistor 31 performs a synchronous clamping function when the line 14 becomes positive; this will be described in detail later.

As described above, the capacitor 33 is charged when the line 15 is positive; the bridge load is then below the setpoint of the potentiometer 17, which causes the signal from the Bridge to consumer 27 negative will; the amplifier output is then positive.

The output of the comparison circuit 11 then becomes the switching arrangement 12 supplied. In particular, the voltage on the capacitor 33 is applied to a flip-flop switch applied, the transistors 34 and 35 has. In this arrangement the capacitor is 33 is connected to the base 36 of the transistor 34, which in turn has a feedback resistor 37 is connected to the collector 38 of the transistor 35.

When the voltage across the capacitor 33 is a sufficient, predetermined reaches positive value, the transistor 34 is conductive and the transistor 35 is non-conductive. When the transistor 34 is conductive, its collector 39 is connected to the voltage is on, on low voltage. The transistor 35 then switches off because his asis 40 is on low voltage because it has a feedback resistor 41 is connected to the supply voltage E + and the collector 39 of the transistor 34 is. Under this condition, the voltage at the collector 38 of the transistor then rises 35 almost to the supply voltage E.

When transistor 34 is conductive (and transistor 35 is off is), a capacitor 42 is connected to the supply voltage via resistors 43 and 44 E + loaded. The common connection point of the two resistors 43 and 44 is with the collector 38 of transistor 35 connected. The outcome of the Capacitor 42 is coupled to emitter 45 of a unijunction transistor 46. When the capacitor 42 reaches the crest voltage of the unijunction transistor 46, it switches on, whereby the capacitor is discharged to a pulse transformer 47.

The voltage on the secondary winding 48 of the pulse transformer is coupled to the control electrode 39 of a triac 50 (bidirectional thyristor diode), which applies the full alternating voltage to the consumer 20. The output of the triac switches the part of the bridge in which the consumer is located, then or closes it in parallel him briefly.

With the help of a triac 5o, the full line voltage to the consumer 20 switches, when the line 14 becomes positive with respect to the line 15, the BrUc1Len output also positive. The output of amplifier 27 then becomes negative and the condenser 33 is not charged. One previously saved on the odensator Charge is then slowly introduced through transistor 34, one resistor 37, and another Resistor 51 connected to transistor base 36 to the common line 15 discharged. This makes the unijunetion transistor 46 in an oscillating state and the triac 50 'is kept switched on' until the capacitor 33 is below the critical voltage level of the Tilip-Flop, which is in equilibrium, discharges. Thereupon the transistor 34 switches on from nd the transistor 35, whereby the unijunction transistor 46 and the triac 50 are switched off.

When the energy supply to the consumer 20 is switched off, is the bridge 1o is fed again with pulses and feels the state of the heat consumer, when line 15 is positive.

If the temperature of the consumer is still below that on the potentiometer 17, the charging process of the capacitor is repeated 33 complete.

The task of the transistor 31 is explained below. According to the In the drawing, its base 52 is coupled to line 14 via a diode 52 '. When line 14 is positive, base 52 is also positive and the transistor 31 conductive; as a result, the output of the amplifier 37 is then instead at the circuit point 53 on the line 15. This then increases the noise due to an additional Prevents charging on the capacitor 33 and thereby the signal-to-noise ratio of the system improved. The second task of transistor 31 is to provide the amplification output clamp on line 15 when line 14 is positive and triac 50 is conductive and the full alternating voltage at the consumer 20 and at the Bnicke output 25 lies. Since the bridge output 25 with the positive input 28 of the amplifier 27 is connected, when the consumer voltage becomes positive, the amplifier output is also positive. In this case, transistor 31 applies the amplifier output at point 53 to the line 15 and thereby prevents the capacitor 33 from being charged. The input of the amplifier is then, as long as the full supply voltage is applied to the consumer, protected by zener diodes 54 and 55.

The consumption should now be set on the 1.7 on the potentiometer Setpoint temperature lie and the triac 50 be switched off. If then the line 14 is positive, the bridge does not sense because the diodes 19 and 22 block. If the Line 15 is positive and the consumer is hotter than the one on the potentiometer is the set temperature, the bridge output is positive. The amplifier output then becomes negative and the diode 32 prevents the capacitor 33 from being charged. As a result remains the transistor 34 and the unijunction transistor 46 and consequently also the Consumer 20 switched off.

When the consumer cools down, the bridge 10 is during the negative Half-period of the alternating voltage on the line is periodically pulse-controlled in order to To feel consumer state.

When it cools down below the setpoint set on the potentiometer the bridge output is negative again and thus the amplifier output is positive. The switching arrangement is then controlled or triggered because the capacitor 33 is charged and over the triac 50 current flows to the consumer 20. This repeats itself periodically, so that the consumer temperature is always slightly above or below the required temperature lies.

The control fineness is determined by means of the gain of the amplifier and the time constant of capacitor 33, resistors 37 and 51 and des equivalent input resistance of the transistor 34 in its switched-on state adjusted or adjusted.

According to a further feature of the invention, a device is provided, by which it is prevented that too high currents flow into the bridge io when voltage is applied to the consumer 20. This is achieved by means of diodes 19 and 22, which are polarized in opposite directions at a common connection point and in opposite directions Arms of the bridge are switched. The power loss in the resistors 16, 18 and 21 and in the potentiometer 17 is thus kept at values which are normal Low power resistances can be included. The diodes 19 and 22 are used but also to rectify the currents in the corresponding bridge arms, if the bridge for sensing a pulsating DC error signal on the amplifier is used.

Although only one embodiment is shown, it goes without saying in the area of the subject matter of the invention, instead of the triac, another switching device to use; comparison circuits other than the amplifier used can also be used, as well as other switching arrangements than the flip-flop unijunction transistor are used will. Other vibration generating devices can also be used, For example, an astable multivibrator or blocking transistors made up of transistors. Another converter or converter device can also be used to convert the To transmit bridge output to the switching arrangement. The bridge can also use pulses operated or controlled by a separate source or a direct current source originate from the power supply connected to the Consumer is disconnected; the consumer supply can also be a DC device or a transformer be, although the consumer as a heating device with variable, Olum'schen Resistance is shown, it can be replaced by other consumers whose Impedance changes with current flow along with their operating state, inclusive of pressure and humidity. Furthermore, the same circuit arrangement can also used to control more than one operating mode, for example to control the heating and cooling processes.

The invention thus creates a circuit in which a star to be starved, electrically conductive consumer is in a bridge branch with the consumer, which acts as its own converter.

When the power to the consumer is switched off, energy pulses are generated the bridge fed to the operating state of the consumer with the equilibrium setting to compare the Bru ¢ ks. An unmatched state, the bridge then becomes used to initiate a control process.

Claims (15)

Claims (i.) Circuit arrangement for determining the state of a consumer, e k e k e n n n n z e i c h n e t by a bridge (10), by one in one arm of the Fractions (10) lying consumes (20), by a switching arrangement (i2) over their Output a current source (50) can be coupled to the consumer (20) in order to thereby to bridge the bridge (10), and by a device for dispensing at intervals occurring pulses to the consumer when the power source (50) is switched off is to determine the bridge equilibrium and thereby the state of the consumer and to energize the Schaltannrdnung (12). When the consumer (20) has a predetermined State reached. 2. Circuit arrangement according to claim 1, characterized in that g e k e n n -z e i c h n e t that the consumer is chosen in such a way that it has its electrical impedance changes with current flow when a change in its operating state occurs. 3. Circuit arrangement according to claim 1, characterized in that g e k e n n -z e i c h n e t that the consumer has a measurable coefficient of resistance. 4. Circuit arrangement according to claim 1, characterized in that g e k e n n -z e i c h n e t that a converter device (ii) between the bridge output and the Input of the circuit arrangement (12) is arranged to turn the bridge output into a Reshape signal when the bridge has a predetermined state reached in order to then excite the switching arrangement (12) and power to the consumer to put on. 5. Circuit arrangement according to claim 4, characterized in that g e k e n n -z e i c h n e t that the converter device (11) has an amplifier (27). 6. Circuit arrangement according to claim 1, characterized in that g e k e n n -z e i c h n e t that the bridge (10) has two rectifier elements (19, 20) which Are connected polarized and are in adjacent arms of the bridge (10). 7. Circuit arrangement according to claim 5, characterized in that g e k e n n -z e i c h n e t that the bridge output is coupled to the amplifier (27), and that Devices for short-circuiting the amplifier output when the consumer receives power and provided between the pulses applied to the bridge. 8. Circuit arrangement according to claim 5, characterized in that g e k e n n -z e i c h n e t that the amplifier output is coupled to a charging circuit (31, 32, 33) is, and that means for limiting the charging circuit to a predetermined Polarity of the amplifier output are provided. 9. Circuit arrangement according to claim 8, characterized in that g e k e n n -z e i c h n e t that a flip-flop switch (34, 35) to the Output of the Amplifier circuit is coupled. 10. Circuit arrangement according to claim 9, characterized in that g e k e n n -z e i c h n e t that an oscillator device is coupled to the flip-flop (34, 35) is and is excited when the flip-flop is in one of its operating states. 11. Circuit arrangement according to claim 10, characterized in that g e k e n n -z e, i c h n e t that the oscillator device has a unijunction transistor (46). 12. Circuit arrangement according to claim li, characterized g e k e n n -ze i c h n e t that the output of the unijunction transistor (46) with a transformer (47) is connected, and that the output of the transformer (47) to the input of the Switch assembly (5O) is coupled. 13. Circuit arrangement according to claim 12, characterized in that g e k e n n -z e i c h n e t that the switching arrangement is a triac (50). 14. Circuit arrangement according to claim 1, characterized in that g e k e n n -z e i c h n e t that an AC power supply (13) is provided and that the bridge is pulsed during a period of the alternating current. 15. Circuit arrangement according to claim 7, characterized in that g e k e n n -z e i c h n e t that the device for short-circuiting the amplifier output a Has transistor (31) whose output to the amplifier output and its base is coupled to an AC power source. Blank page