DE2435715A1 - Short circuit protection device for electrical apparatus - measures internal resistance of circuit using transistors in circuit with phototransistors - Google Patents

Abstract

Circuits of this type have particular application in the flame control of boilers. The internal resistance of the circuit is dependent upon external influences and the internal voltage drop is measured by a detector which in turn operates on the external controls and can eliminate voltage reductions caused by the external control circuits. For example in a flame control device for a boiler phototransistors are influenced by flame brightness and the emitter-collector voltage is measured by a monitor. Increasing brightness reduces the emitter-collector voltage to a point where the detector signals the fuel control (R11) to take corrective action.

Description

Short-circuit monitoring for a current-carrying electrical component The invention relates to a short-circuit monitoring device for an electrical device through which current flows Component whose internal resistance depends on an externally acting one Influencing variable changes and as an indicator for the respective state of the external influencing variable controls an electrical device.

Such components are used in a variety of ways for monitoring purposes; it can be semiconductors, resistors, coils, capacitors and the like act depending on the type of influencing variable (temperature, light, pressure, gas composition etc.) can be selected adapted to the respective purpose. This corresponds to a change in the internal resistance of the component and thus a change in the voltage drop a change across the internal resistance path for example of pressure, the temperature or the respective other influencing variable that has an external effect on the component acts. While now with a properly working component a reduction in the The voltage drop also reflects the actual state of the external influencing variable if the voltage drop (with a correspondingly low internal resistance) becomes very low, means almost complete in the event of a short circuit The disappearance of the voltage drop does not result in a corresponding change in the state of the external influencing factor. This creates a danger if, for example, in the event a safety circuit the electrical controlled by the electrical component Device from the short-circuited component in this way controlled electrical device from the short-circuited Component is controlled so that the electrical device gives the impression becomes that the state of the monitored influencing variable is correct.

This is the example of a flame monitor for one with liquid combustion system heated by gaseous fuel (for example a boiler system on board a ship). Such a flame monitor has at least one the phototransistor exposed to the light emission of the burner flame, its collector-emitter current increases with increasing illuminance and as an indicator of its presence the burner flame actuates a switching element controlling the fuel supply.

In a known arrangement of this type, the collector-emitter current controls amplified by transistors a relay, its secondary contacts in the circuit of the valves for the fuel supply to the burner.

If the phototransistor does not illuminate through the burner flame exposed, its internal resistance is so high and accordingly the collector-emitter current so low that the relay opens and the fuel supply to the burner interrupts. From a certain minimum illuminance onwards, however, this is sufficient correspondingly reduced internal resistance of the phototransistor flowing collector-emitter current off to close the relay after amplification.

However, there are considerable difficulties with this arrangement when a short-circuit defect occurs in the phototransistor: the internal resistance in the collector-emitter path of the phototransistor collapses and it flows a correspondingly high collector-emitter current, which in a sense is extraordinary strong lighting - i.e. a very bright burner flame - pretends to be, even if the burner actually does not work. It is obvious that such a short circuit in the phototransistor leads to a dangerous malfunction of the flame detector has tried to counter this problem by placing between the base of the Input transistor, which with the collector-emitter current from the phototransistor is supplied, and earth put a zener diode so when a certain value is exceeded Input voltage due to a correspondingly high current flow through the phototransistor the zener diode is activated and the base is connected to earth, causing the relay to drop out. However, it is extremely difficult, if at all feasible, to make the zener diode like this to be dimensioned that they are indeed with intense lighting by a strongly emitting Burner flame remains closed in the event of a short circuit of the phototransistor but opens, because the differences in the respective collector-emitter currents and thus the respective potential differences at the base of the downstream transistor are so small that due to the natural tolerances from Zener diodes do not ensure the short-circuit monitoring function of the phototransistor is guaranteed. The invention is therefore based on the object for monitoring circuits this type of short-circuit monitoring, which is reliable on the case a short circuit in the current-carrying component responds and prevents the electrical device controlled by the component falsely gives the impression of an actual one the condition of the externally acting influencing variable does not exist at all.

According to the invention, this object is achieved by the voltage drop detached via the internal resistance path of the component, the sensor when it disappears of the voltage drop controls the device in a way that differs from the control with falling voltage drop due to a change in the state of the external influencing variable In this way, the invention makes the internal resistance of the Component itself as a reference value for determining a possible short circuit state of use and thus practically eliminates the risk that due to Manufacturing tolerances, setting inaccuracies, etc., short-circuit monitoring as well then responds when actually no short circuit has occurred, but for example due to a strong change in the state of the external influencing variable, the internal resistance of the component has only become very small.

In the case of short-circuit monitoring by a flame monitor, the arrangement according to the invention made such that the current-carrying electrical Component one of the light emission of the burner flame one with liquid or Gaseous fuel-heated combustion system, in particular a boiler system on board ships, exposed phototransistor is whose collector-emitter current increases with increasing illuminance and depending on the presence the burner flame actuates a switching element controlling the fuel supply, and that the sensor disappears when the voltage drop across the collector-emitter path actuated the switching element in the sense of an interruption of the fuel supply. Even an internal resistance of the phototransistor which is greatly reduced in the case of strong lighting still leads to a measurable voltage drop, while in the event of a short circuit the voltage drop on the collector-emitter path is practically zero.

In this case in particular, the sensor is preferably a differential amplifier, whose inputs are at the collector or at the emitter of the phototransistor, and its Output connected to a contactor located in the control circuit of the switching element is. As long as there is still a noticeable voltage drop across the phototransistor, this voltage difference leads to a signal at the output of the differential amplifier which allows the contactor to hold the switching element in the actuated state. Breaks but the voltage difference together, so that at both inputs of the differential amplifier essentially the same tensions lie (component tolerances neglected), see above the output signal disappears and the contactor allows the switching element to supply fuel interrupt.

If, for safety reasons, the flame monitor has two phototransistors is equipped for the same burner flame, then is in a further development of the invention intended, that each phototransistor is connected to a sensor is, and that the two sensors are connected to a common OR gate, the output of which when a sensor responds, the switching element is actuated.

Of course, such an arrangement can be divided into more than two Phototransistors (or other electrical components in a monitoring circuit) expand.

The drawing illustrates the invention using an exemplary embodiment in the form of a short-circuit monitoring device connected to a flame monitor circuit.

The flame monitor shown in the drawing as a schematic circuit for the sake of clarity is divided into several electrical connections and cables Interconnected assemblies have been subdivided, of course, too be combined into a single assembly or otherwise divided can. The electrical assemblies include a power supply circuit 20, A DC voltage of 24 volts is available at the output. This DC voltage serves to supply an essentially conventionally constructed flame monitor circuit 30, of which only the output transistor Tr 1 is shown in the drawing. It contains a relay relay Ri, which has a contact set K, through which the fuel valve a burner, not shown, is switched on or off. With the circuit 30 are connected to the flame sensors 31, 32.

While the outputs of the flame sensors 31, 32 were directly connected to the flame monitor circuit 30 are, according to the invention Output connections 7 and 8 or 7 'and 8' of the two sensors 31, 32 to one input connection 17, 18 or 17 ', 18' each following a circuit Short-circuit monitoring circuit 40 described in more detail out, also from the power supply 20 is supplied with DC voltage, the negative terminal of which 11 accordingly to terminal 1, and its positive terminal 12 to the output terminal 4 of the flame monitor circuit 30 is connected.

The monitoring circuit 40 contains sensors for each of the two 31, 32 a sensor that determines whether the assigned phototransistor Ft 1 or Ft 2 has a short circuit defect or not. Normally, such a short-circuit defect would simulate a very bright burner flame and lead to malfunction with a conventional one Flame monitor circuit lead Da the two sensors similar to that of them too monitoring sensors 31 and 32 have the same structure, will only be used below the sensor associated with the sensor 31 is described in detail, while the other Sensor marked by a prime has the same reference numbers.

The core of every sensor is a differential amplifier DV 1 or DV2, for example of type TBA 221B. A negative terminal b of the differential amplifier DV1 is connected to terminal 17 via a resistor RS, and a positive terminal c des Differential amplifier connected to terminal 18 via a resistor R4. A resistance R6 connects terminal c to a terminal d, which in turn has a resistor R8 is connected to a terminal f. Terminal f is in turn via a resistor R7 connected to port b. From the positive terminal 12 of the monitoring circuit 40 receive both differential amplifiers DV1 and DV2 via a resistor R10 at their respective terminal g supplied positive voltage. Furthermore, the two connections d of the two differential amplifiers DV1 and DV2 together to the negative terminal 11 of the monitoring circuit 40 is connected. For internal voltage preparation within the monitoring circuit 40 two Zener diodes Z2 and Z3 are in series between Terminal 11 and the internal end of the resistor R10 connected, and Starting from their common connection point, another Zener diode Z4 is connected, the cathode of which connects a resistor R 11 to the positive terminal 12.

The monitoring circuit 40 occurs with the aid of an OR gate 36 immediately in function when one of the two differential amplifiers DV1 or DV2 or both detect a short circuit in their associated phototransistor Ft1 or Ft2. For circuit reasons, however, at the input of the OR gate 36 is a Reversal of polarity is required, and this is done by means of an upstream Inverter 34 performed. For this reason, the output of the first differential amplifier DV1 through a resistor R9 to a terminal a, and the output of the other differential amplifier DV2 via a similar resistor R9 'to a terminal c of the inverter 34 tied together.

The polarity reversed signals are then transmitted via one each Terminal b and d of the inverter are output to a terminal b and a of the OR gate 36, respectively. The two assemblies 34 and 36 are connected via their connections g, g and

n, n n for power supply to the junction between the two Zener diodes Z2 and Z3 or at the connection point between the cathode of the Zener diode Z4 and the resistor R 11 connected.

In the case of a differential amplifier DV1 resp.

DV2 detected phototransistor short circuit from OR gate 36 The output signal generated passes from its terminal c to the base of a transistor Tr2, which is coupled in an emitter follower circuit with a further transistor Tr3 is. These two transistors amplify the signal and pass it through a resistor R 12 of the excitation coil of a relay R12 belonging to the monitoring circuit 40, the second coil terminal of which is connected to the positive terminal 12. In the event of a detected short-circuit phototransistor picks up the relay R12, and its normally open contact K2 closes a connection 14 to a connection 15 of the Monitoring circuit 40 briefly. These two connections 14 and 15 are with the connections 4 or

5 of the flame monitor circuit 30 is connected. A short circuit in one of the phototransistors Ft1 or Ft2 thus closes the base of the end transistor Trl the flame monitor circuit 30 briefly and thus achieves the same effect as it occurs when an extinguished flame condition is detected. The fuel supply the burning is shut down.

Claims (4)

Expectations Short circuit monitoring for an electrical component through which current flows, its internal resistance depends on an externally acting influencing variable changes and as an indicator for the respective state of the external influencing variable controls electrical device, characterized by a voltage drop across the internal resistance path of the component, which when it disappears of the voltage drop controls the device in a way that differs from the modulation with falling voltage drop due to a change in the state of the external influencing variable differs. 2. Short circuit monitoring according to claim 1, characterized in that that the electrical component through which current flows is the light emission of a burner flame a furnace system heated with liquid or gaseous fuel, in particular a boiler system on board ships, exposed phototransistor (Ft1; Ft2) whose collector-emitter current increases with increasing illuminance and Depending on the presence of the burner flame, a fuel supply that controls the fuel supply Switching element (Rl1) actuated, and that the sensor (DV1; DV2) disappears when the Voltage drop across the collector-emitter path the switching element in the sense of a Fuel supply interrupt actuated. 3. Short circuit monitoring according to claim 2, characterized in that that the sensor is a differential amplifier (DV1; DV2) whose inputs (b, c) are on Collector or emitter of the phototransistor (Ft1; Ft2) lie, and its output (f) with one in the control circuit (30) of the switching element (Rl1) Contactor (Rl2) is connected. 4. Short circuit monitoring according to claim 2 or 3 with two phototransistors for the same burner flame, characterized in that each phototransistor (Ft1, Ft2) is connected to a sensor (DV1, DV2), and that the two sensors to a common OR gate (36), the output of which when a Sensor actuates the contactor (R12). L e r s e i t e