DE2604176C3 - - Google Patents

Description

The invention btxifft a circuit arrangement for an automatic burner control unit for fanless gas burners equipped with a flame monitor, with a Safety timer that, if there is no flame, after its time constant has expired, the power supply for a a fuel valve actuating switching element interrupts, and its flame monitor at before the expiry of the Time constant of the timing element of the existing flame that opens the fuel valve and keeps it open

Such automatic burner control units for fanless gas burners (so-called atmospheric gas burners) are in the most varied of embodiments known, see z. B. AT-PS 3 26 256. It also applies to circuit arrangements for automatic gas firing systems in which the combustion air is supplied by a fan is (DE-OS 24 25 320).

In the case of furnaces with fanless gas burners, a compensation opening is usually provided that is generally connected to the flue gas transition line between the combustion chamber and the chimney. Under unfavorable circumstances it can namely happen with such furnaces that an exhaust gas return flow occurs through this equalization opening. causes this is mainly due to atmospheric influences, in particular gusts of wind acting on the chimney. If these only act for a short time, they generally do not interfere. However, if there is a longer exhaust gas return flow of, for example, more than about 10 seconds, considerable amounts of exhaust gas can enter the Flow into the space into which the compensation opening opens. This can lead to hazards which are to be avoided have to. For this purpose it is known to provide mechanical flaps in the area of the compensation opening, which close a microswitch in the event of an exhaust gas return flow, which emits an alarm signal and / or the Burner switches off. The disadvantage here is that the mechanical flaps are susceptible because they / in order to guarantee a safe function always open must be kept, but because of the strong thermal and corrosive stress in the area a combustion system is difficult to achieve. It is also known to have a temperature sensor in the Area of the compensation opening to be provided over a

The control unit acts on the automatic burner control unit with a time delay and switches it off the arrangement is made so that after a waiting time of about three minutes, the automatic burner control is blocked is canceled by the exhaust gas return flow monitoring, so that the automatic burner control again can start. However, a separate control unit is required here, which is attached separately must be and that must be reliably and correctly connected to the automatic burner control unit.

The object of the present invention is to provide a circuit arrangement of the type mentioned at the beginning improve that the hazards caused by an exhaust gas return flow are avoided without this an additional device is required.

This object is achieved on the basis of a circuit arrangement of the type mentioned in the introduction, that according to the invention in the circuit arrangement an exhaust gas return flow monitoring with a

Interruption, but not a short circuit, must be taken into account. This is how the exhaust gas return flow monitoring have a switching element in the output for fault reporting and for switching off the power supply, which is switched on during normal operation in which the exhaust gas return flow monitoring has not responded. This has the advantage that the switching element also emits a fault signal when, for example, the power supply is switched off the exhaust gas return flow monitoring fails. the capacitors required for smoothing, which inevitably have a higher failure rate than other components, not as high a reliability achieved

A Bime-15, for example, can be used as a temperature sensor Tallkontakt, if necessary in series with a resistor, is provided be the one at the temperature, at the one the arrangement should respond, opens or closes and thereby emits a corresponding signal. With a preferred In contrast, the embodiment of the invention is the temperature sensor The time-delayed temperature sensor of the exhaust gas return flow monitoring is integrated and after the response, the power supply is formed with a high temperature coefficient switches off for a time determined by a timer and is arranged in a branch of a bridge circuit.

By integrating the exhaust gas return flow, it monitors its diagonal voltage at the two inputs chung is applied to the circuit arrangement of the Gasfeuerungsau- an operational amplifier, and it is that On the one hand, there are production costs and on the other hand, switching devices, which are preferably a relay on the other hand, assembly costs are saved. In addition, it acts in the output of the operational amplifier the space requirement of the overall arrangement is reduced '~

and a higher level of reliability is achieved. The vector group can be designed in different ways. It is possible,
to set up the vector group in such a way that it can only be operated with a 30
single active amplifier element gets by in preferred embodiments of the invention, however
the switching group has two transistors aof, the first of which switches off with its emitter at a tap of the bridge resistor 35 connected in series with the temperature sensor -Fixed voltage divider is connected; a Stönem collector, the base of the second transistor activation signal, is generated on its branch above a certain value (if either the thermistor forming the sensor, its emitter with the sensor-side bringer, the corresponding temperature, and its collector with the Input of 40 has reached or some short circuit is connected in this branch of the operational amplifier, which also occurs with), and when the value falls below the specified minimum, the sensor is connected to the bridge branch. least current. For example, in the event of an interruption in the sensor-bridge arm, in this embodiment any stronger loss branch, the switching group switches off the switching element, reduces the current in the sensor-bridge branch and thus causes the fault signal. It is in such a way. that the voltage drop between base and emitter 45 of a preferred further embodiment of the output is increased so much that the first transistor through-switching group for switching off the switching element is also hasty. As a result, the second transistor is also connected to the inputs of the operational amplifier. since its base is the collector current of the earth. This has the advantage that the vector group receives only one most transistor. If the second one is switched on, very little power has to be applied, since it uses the VerTransistor, i.e. when the collector-emitter is permeable, so the strengthening effect of the operational amplifier, the potential of the collector becomes the potential.

al so far approximated at the end of the bridge on the sensor side.

hert. as if the sensor has not reached or exceeded its target temperature for use with a resistor, which is limited to a shutdown temperature sensor. In a preferred embodiment of the switching element through the operational amplifier 55, a temperature sensor is used as the temperature sensor instead of the ^five- resistor with a high thermal coefficient.

In particular, the exhaust gas return flow monitoring can be temperature-dependent switching contact with a series contrary be built up so that there was no interruption as long as this contact is closed nor is a short-circuit of a short-circuit-proof one, the series resistance in the bridge is effective Switching element lead to a Fehlfunkliön. As a result, eo is dimensioned in such a way that it withstands the resistance of the withstand the functional reliability of the arrangement, in addition to the standing thermometer, is approximately the same in normal conditions. elevated. Such a fail-safe version of the exhaust gas opens the switching contact when the set value is reached Reverse current monitoring can, for example, be of the type temperature, so speaks the vector group in the before be constructed that no capacitors are used in the manner described and triggers over the division of the and possible semiconductors in the event of an interruption or 6-,

The operational amplifier assures due its design as an integrated circuit has a particularly high level of operational reliability.

In preferred embodiments of the invention, one is the current in that comprising the temperature sensor Bridge branch monitoring vector group provided, which when falling below a predetermined Minimum current in this bridge branch the switching

Short circuit the fault «s ^: trigger gnal. Then filament film resistors are to be used as resistors,
which are considered to be short-circuit proof, so that only the consequences of one

Switching element from the interference signal. Instead of the switch contact that opens when the temperature rises and the series resistance can also be an announcing Temperature closing switch contact with e'hem Pa-

parallel resistance can be used. Closes when reached the switching temperature of the switching contact short the parallel resistance, this has the same effect as the Resistance reduction of a thermistor temperature sensor: The operational amplifier receives a corresponding Diagonal voltage from the bridge and causes the switching element connected downstream to drop out and thus the triggering of an interfering signal.

A very special advantage of the invention is that the integration of the exhaust gas return flow monitoring into the circuit arrangement of the automatic gas burner control makes it possible to provide an arrangement for the automatic functional check of the exhaust gas return flow monitoring as well, which is coupled to the functional sequence of the automatic gas burner control. that it is effective before or at the latest with every start-up process. This considerably increases the reliability and operational safety of the combustion system with little effort.

The exhaust gas return flow monitoring system is designed so that, after it has responded, the burner for one Time of at least three minutes, which may also include switching back to a lower output, z. B. by turning on a throttle should be understood. This means that the startup process only takes some It takes seconds for the function test to trigger a response from the exhaust gas return flow monitoring system must be carried out at least three minutes before each start-up or the start-up process delayed by about three minutes. In a preferred embodiment of the invention contains Hence the arrangement for the automatic function check a switch-off time determined by the timer the exhaust gas return flow monitoring device reducing device. For example, this time is from three minutes reduced to about three seconds, namely a time that is shorter than that for the start-up process required time or shorter than that specified by the expiry of the time constant of the safety timer Time. This makes it possible in an advantageous manner to carry out the functional check during the start-up process, in particular while the time constant of the safety timer is running. This not only simplifies the structure of the entire arrangement, it is also at least undesirable Delaying the start-up process avoided.

The specified switch-off or pause time during which the exhaust gas return flow monitor keeps the gas burner switched off can be implemented in different ways. For example, a cam timer can be provided for this purpose, which comprises a motor running at constant speed and a cam disk driven by the motor, which actuates correspondingly arranged switching contacts. However, the cost of such a timer is relatively great and a special arrangement would also have to be used in order to achieve the shortened switch-off time for the functional check. In a preferred embodiment of the invention, the timing element is therefore an RC-GWed, and the device for reducing the switch-off time comprises a resistor which can be connected in parallel to the resistance of the / C element. Time constants of about three minutes can still be reproduced easily with RC elements and by connecting a resistor in parallel it is possible with very little effort to reduce this time constant by any factor, for example by a factor of 60 from three minutes to three seconds or even shorter values.

The functional check of the exhaust gas recirculation monitoring can be carried out at bclies good times during the start-up process. For example, can they take place during the ignition time during which the ignition device is in operation. It is preferably provided that the function check takes place while the time constant of the safety timer is running. This

ίο The period of time is greater than the time during which the Ignitor is in operation and is always sufficient. in order to be able to carry out the function check conveniently. It should be noted that the time for the function check can be significantly shorter than the previous one specified three seconds because the shortest time for this is not much greater than the sum of fall time and response time of the electrical part of the exhaust gas return flow monitoring, which is essentially due to the switching times of a relay used as a switching element is determined. It is therefore possible to carry out the functional check during a period of time far less than one second.

Further details and configurations of the present invention emerge from the following Description and an embodiment shown in the drawing. In the drawing is the circuit diagram eirer circuit arrangement according to the invention for an automatic gas burner control with exhaust gas return flow monitoring shown.

A terminal 1 is connected to the center point or the neutral conductor and a terminal 2 is connected to a main switch 3 connected to the phase of a network connection, not shown, over which the entire arrangement is powered. A bridge 4 is laid from terminal 2 to a terminal S to which a contact 6 a thermostat or temperature controller, otherwise not shown, is connected, the other hand is connected to a terminal 7. A line 8 connects to the bridge 4, which has a protective circuit leads to a UV diode 9, which is connected between two terminals 10 and 11. Here is the clamp U is connected via a resistor 12 to a negative line 13 which is connected to the negative pole of a bridge rectifier 18 is connected. With the terminal Il is

<5 also a network of three resistors, a capacitor and connected to a diode to which two transistors 14 and 15 are connected, which are a flame monitor relay 16 control whose winding a protective diode 17 is connected in parallel. From the flame monitor relay 16 leads a feed line 19 to the Plu 'x> l of the bridge rectifier 18. its output voltage smoothed by a capacitor 20 and by a

. Zener diode 21 is stabilized. The bridge rectifier is via a ballast capacitor 22 and a protective resistor 23 connected in series to this, as well as a fuse 24 with a fault unlocking switch 25 connected.

Between the terminal 7 and a ground line 26 connected to the terminal 1, the primary winding is one Transformer 27 switched, the secondary winding of which feeds a bridge rectifier 28, whose The negative pole is connected to a negative bar 29 and a sieve chain 30 made of two resistors on its positive pole and two capacitors is connected to the output of which a Piusieitung 3i is connected between A Zener diode 32 is connected to the plus line 31 and minus bar 29 for voltage stabilization. Between the Piusieitung 31 and the minus rail 29 is

Furthermore, a bridge arm 33 made of two resistors is connected, the junction of which with an input 34 an operational amplifier 35 is connected, the feed connections of which are connected to the plus line 31 and the minus rail 29, respectively. To the positive line 31 is furthermore a potentiometer 36 is connected, at the other end of which a protective resistor 37 is connected is. which in turn establishes the connection to a further input 38 of the operational amplifier 35. Also is with the other end of the potentiometer 36, a terminal 41 is connected via a normally closed contact 39 of an ignition relay 40. Another terminal 42 is connected to the minus rail 29. A thermistor resistor 43, which serves as a temperature sensor, is connected between terminals 41 and 42.

The tap of the potentiometer 36 is connected to the emitter of a transistor 44 via a diode 43, its base to the tap of a voltage divider two resistors 45 and 46 are connected, which are placed between the positive line 31 and the negative rail 29 are. The collector of the transistor 44 is connected to the base of a further transistor 47, the emitter of which is connected to the negative rail 29 and the collector of which is connected the input 38 of the operational amplifier 35 is connected. A feedback resistor 49 connects an output 48 of the operational amplifier 35 with high resistance de: n input 38. From output 48, a resistor 50 and a diode 51 are connected in series a transistor 52 controlled, the base of which is connected to the cathode de. Diode 51 is connected and its emitter with the minus rail 29 is connected, from which a base resistor 53 is led to the base of the transistor 52. On The collector of the transistor 52 is connected to an exhaust relay 54, to which a protective diode is connected in parallel and which, on the other hand, is connected to the positive line 31. The transistors 52 and 57 are npn transistors. whereas transistor 44 is a pnp transistor. The transistors 14 and 15 are also npn transistors.

A line 55 also leads from terminal 7 to a normally closed contact 56 of the lockout switch 25. A resistor 57 is connected to the other terminal of the latter. From the other end of the resistor 57 leads to a connection via a diode 58 to the winding of a main relay 59. The winding of the main relay 59 and a protective capacitor is connected in parallel to the series circuit consisting of the winding of the main relay 59 and the diode 58. The connection of the coil of the main relay 59 facing away from the diode 58 is via a normally open contact 60 of the main relay 59 is connected to the ground line 26. The normally open contact 60 is another normally open contact 61 of a control relay 62 is connected in parallel.

While the power supply to the main relay 59 and the exhaust gas return flow monitoring system are connected directly to terminal 7 via the transformer 27. all other parts are supplied with power (with the exception of a malfunction indicator lamp 63) via the malfunction release switch 25. Is in the working position a normally closed contact 64 of the lockout switch 25 is closed. The normally closed contact 64 is via a line 65 connected to terminal 7, in which the parallel connection of a normally open contact 66 of the ignition relay 40 and a changeover contact 67 of the exhaust gas relay 54 are arranged. The normally open contact part of the Changeover contact 67 in the course of the line 65, whereas on the normally closed contact part of the changeover contact 67 an exhaust gas backflow indicator lamp 68 is connected. which on the other hand are connected to the ground line 26 is. The lockout switch 25 also has a normally open contact 69. the one between bridge 4 and the malfunction indicator lamp 63 is switched on. which on the other hand is connected to the ground line 26. Of the Break contact 64 leads a conductive connection to a bimetallic contact 70 of the lock release switch 25, which opens when the temperature rises and at the same time releases a mechanical lock, whereby the Störentriegelungsschali ^ r into the Stör or Goes off position, in which the normally closed contact 64 and the normally closed contact 56 are open and the normally open contact 69 are closed. With the bimetal contact 70 is a Heating coil 71 connected, at the other end of which a series resistor 72 is connected. To the previous

Is status 72 closes the series circuit of a break contact 73 of the flame monitoring relay 16 and one The normally closed contact 74 of the ignition relay 40 and a normally open contact 75 of the disturbance 62 3iv Her on the other hand is connected to the ground line 26. Parallel the series circuit of a normally closed contact 76 of the exhaust gas relay 54, a diode 77 and a capacitor 78 is connected to the normally closed contact 74 of the ignition relay 40. A resistor 79 is connected in parallel with the normally open contact 75 the connection between diode 77 and capacitor 78 a series resistor 80 is connected, at the other end of which a normally closed contact 81 of the ignition relay 40 is connected, the other with one end of the winding of the control relay 62 is connected. The other end of the winding of the control relay 62 is connected to the connection connected between contacts 74 and 75. The winding of the control relay 62 is a capacitor 82 connected in parallel. The control relay 62 is provided with a further normally open contact 83 on the one hand the fuse 24 is connected and to the other hand the series connection of a series resistor 84 and a protective capacitor 85 is connected. the to the Ground line 26 is performed. At the connection between series resistor 84 and protective capacitor 85 is a diode 86 connected to its anode, whose Cathode with the connection between normally closed contact 81 and winding of control relay 62 is connected.

The working contact 83 is also used by the Circuit arrangement controlled devices supplied with power. These devices, namely an ignition transformer 87, an ignition gas valve 88, a main gas valve 89 and a safety valve 90 are all connected to the ground line 26 on one side. Ignition transformer 87 and Ignition gas valve 88 are connected in parallel and via a normally open contact 91 of the ignition relay 40 and an Ar make contact 92 of the main relay 59 with the work con- tala 83 connected on the side to which the series resistor 84 is also connected. To normally open contact 92 a normally open contact 93 of the flame monitor relay 16 is also connected to which, on the other hand, the main gas valve 89 is connected. In contrast, the safety valve 90 is directly connected to the normally open contact 92 connected.

The circuit arrangement also includes a control group, which during a predetermined safety time the ignition transformer 87 and the ignition gas valve 88 are supplied with power. Will during this time of If no flame is reported to the flame monitor, the system switches off. The timer that defines after is also connected to this switching group how long the exhaust gas return flow monitoring system allows a new start-up process after it has responded. This time switch group comprises a timing element made up of a time capacitor 94, a fixed resistor 95 and a

nem setting resistor 96. The time capacitor 94 is on the one hand via a protective resistor 97 to the negative line 13 and on the other hand via a break contact 98 of the control relay 62 is connected to the feed line 19. The connection between time capacitor 94 and Normally closed contact 98 is also connected to the work control connection of a changeover contact 100 via a line 99 of the control relay 62 is connected, the normally closed contact terminal of which is connected to the feed line 19, whereas the series circuit of the resistors 95 and% is connected to the common Kentakt part. On the end of the series circuit comprising the resistors 95 and 96 facing away from the changeover contact 100 is the The base of a transistor 101 is connected to the collector of which the winding of the ignition relay 40 is connected, which, on the other hand, is connected to the feed line 19; the winding of the ignition relay 40 is a protective diode 102 connected in parallel. The emitter of transistor 101 is via the series connection of two diodes 103 as well a resistor 104 in series with this is connected to the negative line 13. Resistor 104 is also a Zener diode 105 connected in parallel. There is also a resistor 105 between the feed line 19 and the emitter of transistor 101 switched. With the base of the transistor 101, the collector is also via a normally closed contact 106 of the control relay 62 Transistor 107 is connected, which like transistor 101 is an npn type between the collector of the A capacitor 108 is connected to the transistor 107 and the negative line 13. A protective capacitor 109 is connected between the base of the transistor 107 and the negative line 13 switched. The series connection of a fixed resistor 110 and a setting resistor U1 is connected to the connection between the fixed resistor 95 and the changeover contact 100, one of which is the other End of a diode 112 leads to the base of transistor 107, to which she is connected with her Käihöuc. Between a time capacitor 113 is connected to the anode of the diode 12 and the negative line 13. In parallel with the series circuit made up of resistors 110 and 111 is a Series connection of a resistor 114 and a break contact 115 of the main relay 59 is provided. the The resistance of the resistor 114 is very much smaller than that of the series connection of the resistors UO and 111: when the contact 115 is closed, the resistor 114 together with the time capacitor 113 therefore forms a timing element, whereas when the contact 115 is open, the resistors HO and Hl together with the time capacitor 113 form a timing element. In the first case, the time is preferably selected to be about three seconds, in the second case about three minutes

The functional sequence during a start-up process is described below. In the drawing is the The position of the contacts when the relay has dropped out and the fault unlocking switch 25 in the rest position is shown.

When the main switch 3 is closed, only the UV diode 9 voltage. When the contact 6 is closed by a temperature controller, the exhaust gas return flow monitoring device receives voltage via the transformer 27 and the exhaust gas relay 54 picks up because the resistance value of the cold temperature sensor (resistance 43) is relatively large, so that input 38 is positive opposite the input 34 of the operational amplifier 35. The transistors 44 and 47 are blocked, white on Sufficiently large current flows through the potentiometer 36. The exhaust relay 54 switches the changeover contact 67 um, whereby via the line 65, the lockout switch 2S and the power supply with the Bridge rectifier 18 the time switch arrangement with the ignition relay 40 and the flame monitor amplifier receive power with the flame monitor relay 16.

The time capacitor 94 is charged via the closed normally closed contact 98 of the control relay 62. Over the contact 100 and the resistors 95 and%, the transistor 101 is turned on, whereby the ignition relay 40 picks up. This closes the contacts 66 and 91 and the contacts 39, 74 and 81 open. By closing the contact 66, even if the exhaust relay 54 drops out, the power supply to the Line 65 connected circuit parts maintained. By opening the contact 39 is the Malfunction "interruption in the sensor circuit" simul.eri. As a result, the current in the potentiometer 36 is almost.: U Zero and the base-emitter voltage at the tran-istor 44 is so great that this controls and also the Transistor 47 turns on. The transistor 47 shifts while the potential of the input 38 in the direction of the Minus rail 29, so that a negative potential compared to input 34 is present at input .38, whereby the operational amplifier 35 blocks the transistor 52 and thereupon the exhaust relay 54 drops out. With thereby closed contact 76 and at the same time open) contact 74, the capacitor 78 is corresponding to the Time constant charged, which is given by its capacity and the resistance value of resistor 79: this time constant is about one second de. After about two more seconds, the time capacitor 113 is charged to such an extent via the resistor 114 that it controls the transistor 107 via the diode 112. This will put the potential at the base of the Transistor 101 lowered so far that the transistor 101 blocks and thereby the ignition relay 40 drops out. This closes the contacts 39, 74 and 81 and contacts Si and 66 open. By closing the contact 39, the transistors 44 and 47 locked again and by the operational amplifier 35 the transistor 52 aufgesteueri, whereby the exhaust relay 54 picks up again. The check of the exhaust gas return flow monitoring is now complete. By tightening of the exhaust relay 54, the previously switched on fault indicator lamp 68 is switched off and the power supply of line 65 continued to be maintained. By closing the contact 81, the charged capacitor 78 is discharged through resistor 80 and winding 62, causing the control relay 62 picks up It closes contacts 61, 75 and 83 where-

so by the control relay 62 holds itself. On the other hand, it causes the main relay 59 to be attracted also holds via the contact 60 itself and that also closes the contact 92 and the contact 115 opens The control relay 62 also has the contacts 98 and 106 opened and the contact 100 switched By switching these three contacts, the time capacitor 94 via the resistors 95 and% to Discharge the base of the transistor 101, which is thereby turned on, whereupon the ignition relay 40 turns on again.

eo pulls The time capacitor 94 is able to during to hold the ignition relay 40 in the attracted position for a safety time of five seconds. When the ignition relay 40 is pulled in, the contact 91 is closed and received it, since contacts 83 and §2 were closed, the ignition transformer 87 and the pilot gas valve 88 voltage, whereby pilot gas flows to the burner and is ignited by the ignition transformer. Forms during the safety time, while

The capacitor 94 opens the transistor 101 holds, no flame, then the ignition relay 40 drops again and opens the contact 66. The power supply of the circuit connected to the line 65 is maintained, however, since by closing the contact 39, the exhaust relay 54 picks up again and the contact 67 switches over. In this switching state, the contacts 73, 74 and 75 are all closed and it is, limited by the resistor 72, the heating coil 71 heated, whereupon the bimetal switch 70 triggers and the normally closed contacts 64 and 56 open, whereby the power supply to the one on the fault unlocking switch 25 connected circuit part interrupted wi-d. At the same time, contact 69 is closed and thus the malfunction indicator lamp 63 is switched on. Only through manual unlocking and return With the fault release switch in the position shown, the system can be started up again.

However, if a flame is formed during the safety time specified by the time capacitor 94 off, then the transistors 14 and 15 are turned on and the flame monitor relay 16 picks up. Through this it closes the contact 93, whereupon the main gas valve 89 opens. (The main gas valve 89 and the The safety valve 90 connected upstream of the pilot gas valve 88 already had the main relay pulled up for the first time 59 open.)

If an exhaust gas backflow occurs, the resistance 43 heated above the specified temperature, its resistance decreases so much that that the potential at the input 38 is more negative than that at the input 34 of the operational amplifier 35. As a result the exhaust gas relay 54 drops out and switches the contact 67 into the position shown, in which the exhaust gas return flow indicator lamp 68 lights up. This interrupts the power supply for the control relay 62, whereupon this and also the flame monitor relay 16 drops out. Only the main relay 59 remains picked up. The main gas valve 89 and the safety valve 90 close, which extinguishes the flame. Has the Resistance 43 of the temperature sensor has cooled down again to below the response temperature, so the relay pulls 54 on again and the downstream circuit arrangement is again supplied with power via line 65 provided. The time capacitor 94 is charged and the ignition relay 40 picks up. Ignition transformer 87 and Ignition gas valve 88 receive no current, however, because the control relay 62 has dropped out and therefore the contact 83 is open. When the ignition relay is pulled in, the exhaust relay 54 is switched off, but it is through the contact 66 maintain the power supply. Since the contact 115 is open, is now only after through the resistors 110 and 111 and the time capacitor 113 predetermined period of time the transistor 107 is opened, which causes the ignition relay 40 causes. This is the case after about three minutes. The further start-up process takes place as described above, only compared to before, the time constant until the ignition relay 40 drops out, not three seconds ω (Resistance 114). but about three minutes (resistances 110 and 111). It then follows that Re-tightening of the exhaust relay 54, the switching on of the control relay 6Z, the ignition process during the safety time (Capacitor 94) and finally normal operation.

An inventively constructed circuit can also find the EGR flow monitoring including de ^r automatic self-monitoring in connection with differently constructed gas burner control use. For example, a thermocouple can also be used as a temperature sensor if the circuit is changed slightly, so that tben cases can be monitored for short circuits and interruptions.

For this purpose 2 sheets of drawings

Claims (11)

Patent claims: 1. Circuit arrangement for a gas burner control provided with a flame monitor for No-blast gas burner, with a safety timer that, if there is no flame, after its Time constant interrupts the power supply for a switching element actuating a fuel valve, and its flame monitor when it expires the time constant of the timing element of the existing ram keeps the fuel valve open, characterized in that an exhaust gas return flow monitor is integrated in the circuit arrangement (33 to 54) is integrated with a temperature sensor (43), which responds with a time delay and after The power supply (65) responds for a time determined by a timer (110,111,113). 2. Circuit arrangement according to claim 1, characterized in that the exhaust gas return flow monitor (33 to 54) has a switching element in the output (54) for reporting faults and for switching off the power supply, which during normal operation, at which the exhaust gas return flow monitoring has not responded, is switched on. 3. Circuit arrangement according to claim 2, characterized in that the temperature sensor (43) of the exhaust gas return flow monitoring system is designed as a resistor with a low temperature coefficient and in a branch (36, 43) a bridge circuit (33, 36, 43) is arranged, the diagonal voltage of which is applied to the two inputs (34, 38) of an operational amplifier (35), and cus switching element (54) im Output (48) of the operational amplifier (35) is arranged 4. Circuit arrangement according to claim 3, characterized in that a current in the the temperature sensor (43) comprehensive bridge arm (36, 43) monitoring switching group (44 to 47) is provided. when falling below a specified minimum current in this bridge branch the switching element (54) switches off. 5. Circuit arrangement according to claim 4, characterized in that the output of the switching group for switching off the switching element with one of the inputs (38) of the operational amplifier (35) connected is. 6. Circuit arrangement according to claim 5, characterized in that the switching group two so Transistors (44 and 47), the first of which has its emitter on a tap of the bridge resistor (36) connected in series with the temperature sensor (43) and its base on one of the bridge ke parallel fixed voltage divider (45, 46) is connected, that the base of the second transistor (47) is connected, the emitter of which with the sensor-side bridge end and whose collector is connected to the input (38) of the operation amplifier (35), which also is connected to the tap of the filler bridge / toilet. 7. Circuit arrangement according to one of claims 3 to 6, characterized in that as a temperature sensor instead of the resistance with high Temperature coefficient, a temperature-dependent switch contact with a series resistor is provided. 8. Circuit arrangement according to one of the preceding claims, characterized in that an arrangement is provided for the automatic functional check of the exhaust gas return flow monitoring which is effective before or at the latest with each start-up process 9. Circuit arrangement according to claim 8, characterized in that the arrangement for automatic function check a switch-off time determined by the timer (110,111,113) Contains diminishing device 10. Circuit arrangement according to claim 9, characterized in that the timing element (110, 111, 113) is an RC element and the device for reducing the switch-off time comprises a resistor (114) which can be connected in parallel to the resistor (110, 511) of the ÄC element 11. Circuit arrangement according to one of claims 8 to 10, characterized in that the functional test takes place during the expiry of the time constant of the safety timer (94,95,96).