DE3411246C1 - Circuit for an automatic furnace - Google Patents

Abstract

An automatic furnace (1) consists of three time transmitters (2, 3 and 4), a flame-relay amplifier (5), four power supply apparatuses (6, 7, 8 and 9), a repetition circuit (10), a discharge resistor (11), a discharge zener diode (12), a voltage divider (13), a light-sensor voltage divider (14), two bias resistors (15, 16), an operating relay (AR; ar1; ar2), an auxiliary relay (HR; hr1; hr2), a flame relay (Fr; fr) and a blocking relay (Br; br). The first time transmitter (2) consists of a reference-voltage transmitter (17), a timing element (18) and an amplifier (19) which has positive feedback and is composed of an operational amplifier (19a) and a feedback element (19b; 19c) which, for its part, consists of the series circuit of a feedback zener diode (19b) and a feedback resistor (19c). The automatic furnace (1), to which an ignition transformer (ZT) and two fuel valve coils (BV1, BV2) are connected, contains a disturbance tripping path in which at least one opening contact (frb) of the flame relay (FR; fr), a first opening contact (hr1b) of the auxiliary relay (HR; hr1; hr2) and a first closing contact (ar1) of the operating relay (AR; ar1; ar2) are connected in series with a blocking relay coil (BR). A first AC voltage connection (6a; 6c) of the first power supply apparatus (6), whose DC voltage output (6d; 6c) supplies only the second time transmitter (3) and the auxiliary relay coil (HR), is ÄlacunaÜ in parallel with the first ... Original abstract incomplete. <IMAGE>

Description

description

The one shown in FIG. 1 shown burner control 1 consists of three Timers 2, 3 and 4, a flame relay amplifier 5, four power supply units 6, 7, 8 and 9, a repetition circuit 10, a discharge resistor 11, a discharge Zener diode 12, a voltage divider 13, a light sensor voltage divider 14, two series resistors 15 and 16, a working relay AR; aryl; ar2, an auxiliary relay HR; hrl; hr2, a Flame relay FR; fr, a blocking relay Br; br. There are two on burner control 1 Service valve coils BV1 and BV2 as well as an ignition transformer ZT connected.

The first timer 2 consists of a reference voltage generator 17, a timing element 18 and a positive feedback amplifier 19, which is the output circuit of the first timer 2 and consists of an operational amplifier 19a and a Feedback member 19b; 19c, which in turn consists of the series connection a feedback zener diode 19b and a feedback resistor 19c. The output of the reference voltage generator 17 is on the inverting input and the output of the timer 18 to the non-inverting input of the operational amplifier 19a out, while the feedback member 19b; 19c between the last entrance and the output of the operational amplifier 19a.

The second timer 3 consists of a control part 20 and a from this controlled auxiliary relay semiconductor switch 21, during the third timer 4 consists of a delay timer 22 and a working relay semiconductor switch controlled by this 23 composed. The input of the delay timer 22 is connected to the output of the feedback amplifier 19 and thus also to the output of the first timer 2 connected. The output of the timer 3 is single-pole on one pole of an auxiliary relay coil HR and the output of the timer 4 monopolar to one pole of a working relay coil AR led.

The circuit of the flame relay amplifier 5 is known per se. It consists of an input rectifier 24, a preliminary stage controlled by this 25, an output stage 26 consisting of a semiconductor switch, one against ground switched pre-stage output voltage divider 27; 28, the one of two connected in series Divider resistors 27 and 28 and the input of which is controlled by the preliminary stage 25 while its output is connected to the control input of the output stage 26. Of the negative supply pole of the preliminary stage 25 and one pole of the semiconductor switch forming the output stage 26 are connected to ground via a common emitter resistor 29. The output of the flame relay amplifier 5 is unipolarly led to one pole of the flame relay coil FR.

The circuits of the four power supply units 6 to 9 are known per se and therefore not shown in the drawing.

The first power supply 6 consists of two half-wave rectifiers that an alternating voltage supply pole 6a or 6b and a common reference supply pole 6c own. The reference supply pole 6c is at the same time the reference pole of the output DC voltage of the first power supply unit 6. The two poles 6a and 6c form a first AC voltage connection 6a; 6c and the two poles 6b and 6c a second AC voltage connection 6b; 6c of the power supply unit 6. The two half-wave rectifiers of the power supply unit 6 have one common smoothing capacitor and no stabilizing elements.

The second and third power supply units 7 and 8 each consist of one Half-wave rectifier, a smoothing capacitor and a Zener diode stabilization.

The fourth power supply unit 9 consists only of a half-wave rectifier with smoothing capacitor and has no stabilization circuit.

The AC voltage reference supply poles of the second to fourth power supply units 7, 8 and 9 are at the same time the reference poles of their output DC voltages and are all due to mass.

The repetition circuit 10 consists of a control device 30 and a reset semiconductor switch 31 controlled by this, the first pole of which the output of the repetition circuit 10 forms.

The output of the timer 2, which is connected to the input of the connected to ground Voltage divider 13 is, is via the voltage divider 13 with a first input 3a of the timer 3 connected. The voltage divider 13 consists of three in series switched load resistors 13a, 13b and 13c and thus has two exits. The lower voltage divider output is at the first input 3a of the timer 3. The one having a higher voltage The voltage divider output is via the flame relay coil FR with the output of the flame relay amplifier 5 connected.

The light sensor voltage divider 14 consists of a light sensor LF and two voltage divider resistors 14a and 14b, all three of which have a common Have pole that is connected to the input of the input rectifier 24, so that the flame relay amplifier 5 is controlled by the light sensor LF.

The reference voltage generator 17 is connected to ground and voltage divider consisting of two resistors connected in series. The timers 18 and 22 are both RC elements, the capacitor of which is connected to ground with one pole.

The working relay AR: ar 1; ar2 has a first make contact ar 1 and a second make contact ar 2. The auxiliary relay HR: hr 1; her 2 has a first changeover contact hr 1 and a second changeover contact hr2, wherein the first changeover contact hr 1 from a first make contact her 1. and a first break contact hr lb composed, while the second changeover contact hr2 consists of a second make contact her23 and a second break contact hr2. The blocking relay BR; br has an opening contact br and the flame relay FR; for a changeover contact fr, which in turn consists of a make contact and an opening contact frb exists. The blocking relay BR; br is a bistable Relay, e.g. B. a remanence relay. Its reset circuit, i.e. H. its pull-in circuit, is not shown in FIG. 1 for the sake of simplicity of the drawing.

An alternating supply voltage, the reference pole of which is connected to ground. feeds with its other pole an input pole via a normally closed contact R of a heater of the automatic burner control 1. It then appears within the automatic burner control 1 after the opening contact br of the blocking relay Br; br as single-pole AC supply voltage U ;. The alternating supply voltage U feeds, inter alia, an alternating voltage input pole of the second and fourth power supply units 7 and 9, from the flame relay amplifier 5 facing away from the pole of the first voltage divider resistor 14a and an interference trigger path fro; hrlb; 15; ar 1; 6a; 6c; BR. The disturbance trigger path fr6: hr lh; 15; ar 1; 6a; 6c: BR consists of the series connection of the opening contact in the order given frb of the flame relay FR; fr, of the first opening contact hr 1h of the auxiliary relay HR: you 1; hr2, the first series resistor 15, the first make contact arl des Working relay AR; arl: ar2 to which the first AC voltage connection 6a; 6c of the first Power supply 6 is connected in parallel, and the blocking relay coil BR.

The common pole of the break contact frb of the flame relay and of the first opening contact hr 1b of the auxiliary relay is directly connected to a first pole the primary winding of the ignition transformer ZT and via the first closing contact hr 1, the auxiliary relay and the subsequent second series resistor 16 with the AC voltage supply pole 6b of the second AC voltage connection 6b; 6c of the first power supply unit 6 is connected. The DC voltage output 6d; 6c of the first power supply unit 6 only feeds in two poles the second timer 3 with the associated auxiliary relay coil HR, d. H. he is dining directly to the control part 20 and via the Auxiliary relay coil HR the auxiliary relay semiconductor switch 21. The common pole of the first series resistor 15 and the first make contact ar 1 of the working relay is connected to an AC voltage input pole 3c of the timer 3 connected.

The closing contact for "of the flame relay and the second closing contact heart, the auxiliary relay are connected in parallel. The AC supply voltage U reaches as supply voltage U2 via this parallel connection, among other things, an AC voltage input pole of the third power supply unit 8 and the common pole of the second series resistor 16 and the first make contact hr 1a of the auxiliary relay. The supply voltage U2 feeds also a first pole via the second make contact ar2 of the working relay the first fuel valve coil BV1 and via the second opening contact hr2b of the auxiliary relay a first pole of the second fuel valve coil BV2 and one first input 10a of the repetition circuit 10 connected to this pole. In addition is still the pole of the second voltage divider resistor facing away from the flame relay amplifier 5 14b at the supply voltage U2.

The single-pole DC voltage output of the second power supply unit 7 feeds on the one hand the timer 2, d. H. the input of the reference voltage generator 17, the Input of the timing element 18 and the positive supply pole of the operational amplifier 19a, and on the other hand the positive supply pole of the preliminary stage 25 of the flame relay amplifier 5, a first feed input 10c of the repetition circuit 10 and via the working relay coil AR a first pole of the working relay semiconductor switch 23 of the timer 4. The unipolar DC voltage output of the fourth power supply 9 is on a second Feed input lOdund the output of the preliminary stage 25 to a second input 10b of the Repetition circuit 10 out, the output of which via the discharge resistor 11 with the output of the timing element 18 and the cathode of the discharge Zener diode 12 are connected is, while the anode in turn on the output of the timer 4 contained Delay timer 22 is performed.

The lower voltage output of the voltage divider 13 is connected to the first input 3a of the timer 3. The single-pole DC voltage output of the third power supply unit 8 on the one hand directly feeds the one having a higher voltage Output of the voltage divider 13 and on the other hand via the flame relay coil FR the output of Flammenrclais amplifier 5 and thus its output stage 26. The second Input 3b of timer 3 is in turn directly connected to the output of the flame relay amplifier 5 led.

The pole of the light sensor facing away from the flame relay amplifier 5 LF, the respective negative supply pole of the operational amplifier 19a and the control unit 30, the reference supply pole of the input rectifier 24 and the second in each case Pole of the primary winding of the ignition transformer ZT, the blocking relay coil BR, the first fuel valve coil BV1, the second fuel valve coil BV2, des Working relay semiconductor switch 23 and the reset semiconductor switch 31 are located all in bulk.

The auxiliary relay semiconductor switch 21, the working relay semiconductor switch 23, the semiconductor switch of the output stage 26 and the reset semiconductor switch 31 are e.g. B. Transistors. The drawing shows the use of NPN transistors accepted. Provided that the polarities of the diodes and the DC supply voltages be chosen the other way round, can of course also use PNP transistors can be used as semiconductor switches.

The control unit 30 of the FIG. 2 repetition circuit shown 10 contains an amplifier 32 at the output, the input of which on the one hand has a first resistor R 1 to the negative supply pole of the amplifier 32 and the negative connected to ground supply pole of the control unit 30, while cr on the other hand via a first diode D1 to a first pole of a first RC series circuit R4; Cl is led. The other, positive supply pole of amplifier 32 is connected to the first Feed input 10c and the first pole of the first RC series circuit R4; C1 through a second resistor R2 and a Zener diode ZD at a second feed input 10dder Repetition circuit 10. The second pole of the first RC series circuit R 4: C1 is via a second diode D 2 and a third resistor R3 to the first input 10a and a third diode D3 to the second input lob of the repetition circuit 10 connected. The cathode of the first diode D 1 is at the input of the amplifier 32, the anode of the second diode D2 and the cathode of the Zcnerdiode ZD are located on the side of the input 10a or the feed input 10d and the cathode of the third diode D3 is at the input lob. The two diodes D2 and D3 are thus from the inputs 10a and 10b of the repetition circuit 10 viewed in reverse Polarized direction.

The control part 2 (the second shown in FIG Timer 3 has a preamplifier 33 at its output. The input of the preamplifier 33 is on the one hand via a fifth resistor R 5 to the positive supply pole of the preamplifier 33 and the positive supply pole 3d of the timer 3 are connected, and on the other hand via a first diode / resistor series circuit D4; D5; R6 on the other negative supply pole of the preamplifier 33 and the timer 3 as well as to one pole of the auxiliary relay semiconductor switch 21. The entrance of the preamplifier 33 is additionally via a second RC series circuit R 8th; C2 and a subsequent second diode / resistor series circuit D6; R7 with connected to the AC voltage input terminal 3c of the timer 3, the one from the preamplifier 33 remote pole of the second RC series circuit R8; C2 via an input semiconductor switch T1, the control input of which forms the first input 3a of the timer 3, to ground lies. The first diode / resistor series circuit D4; D5; R6 consists of the specified Sequence from the input of the preamplifier 33 starting from a fourth diode D4, a fifth diode D5 and a sixth resistor R 6, the two diodes D4 and D5 are polarized in the same direction.

The common pole of the two diodes D 4 and D 5 is via a third RC series connection R9; C3 is fed to the second input 3b of the timer 3. the The anode of the fourth diode D4 is on the side of the input of the preamplifier 33 and that of the sixth diode D6 on the side of the AC voltage input terminal 3c of the Timer 3. The negative supply pole of the timer 3 is denoted by 3e. Of the Input semiconductor switch T1 is z. B. a transistor.

Functional description The following is based on the assumption that the burner control 1 an oil burner control unit is for a two-stage burner with or without post-ignition or for one single-stage burner with post-ignition. In addition, it is assumed that the blocking relay BR; br himself in the deferred, d. H. is in the tightened state, and in this state in FIG. 1 is shown.

As soon as an alternating voltage appears at the input of the burner control unit 1, z. B. by slitting the regulator closing contact R, lie over the opening contact br of the blocking relay the following devices resp.

Circuits at their supply voltage, namely: - the interference trigger path fRb; hr lb; 15; ar 1; 6a; 6c; BR, - the primary winding of the ignition transformer ZT via the break contact frb of the flame relay, - the first power supply unit 6 via his first AC voltage terminal 6a; 6c, - the second power supply unit 7, - the fourth Power supply 9 and - the light sensor voltage divider 14 via his with the first Voltage divider resistor 14a connected input.

At the same time, the output DC voltages feed the affected Power supply units 6, 7 and 9, the three timers 2, 3 and 4, the preliminary stage 25 of the flame relay amplifier 5 and the control unit 30 of the repetition circuit 10. The relay coils HR and AR now have their supply voltages. Only the supply voltage of the output stage 26 of the flame relay amplifier 5 and that of the flame relay coil FR are still missing. By the appearance of the output DC voltage of the second power supply unit 7 at the input of the first timer 2 is generated by the timer 18 of the timer 2 Pre-purge time tv started.

After the pre-purge time tv generated by timer 2 has expired, appears at the output of the first timer 2, a voltage due to the positive Feedback of the feedback amplifier 19 is maintained as long as the The capacitor of the timer 18 remains charged. This provided that the supply voltage of the timer 2 remains present.

The output of the common timer 2 controls on the one hand directly the timer 4 and on the other hand via the voltage divider 13 and its one lower Voltage output the timer 3.

After the pre-purging time tv has elapsed, one of the delay time elements is thus on the one hand 22 of the timer 4 generated pull-in delay time ta started after it has expired the working relay picks up, and on the other hand a safety time generated by the timer 3 t started. The first service valve coil BVl is now activated.

The presence of light or a flame is determined with the help of the Light sensor LF and the downstream flame relay amplifier 5 is monitored. While the pre-purge time tv there is still no flame, but extraneous light may be present be. If there is light, then the output stage 26 of the flame relay amplifier is 5 conducts to ground and closes the output having a higher voltage of the voltage divider 13 via the flame relay coil FR and the emitter resistor 29 short. If the extraneous light is still present at the end of the pre-purge time tv, then thereby the control of the timer 3 and thus the start of the safety time ts locked. Since the third power supply 8 is not yet in operation and that of the voltage divider 13 is too low, the flame relay does not pick up yet. Since the started timer 4 continues in Is in operation, the working relay then switches on sequence the pick-up delay time ta with the help of its first make contact ar 1 die Blocking relay coil BR on and thus triggers the fault release. As a consequence, that the opening contact br of the blocking relay feeds the burner control 1 turns off.

The disturbance trigger path frb; hr lb; 15; ar 1; 6a; 6c; BR blocks thus, in the presence of extraneous light at the end of the pre-purge time tv, delayed by the time ta after the end of the pre-purge time tv, the automatic burner control 1.

During the pick-up delay time t, on the other hand, only the start of the Timer 3 locked.

In the absence of extraneous light at the end of the pre-purge time t; - the safety time t5 is delayed by the time ta with the aid of the timer 3 started and the auxiliary relay picks up directly, i.e. before the working relay. As a result, the first changeover contact hr 1 interrupts the fault triggering path and sets at the same time the AC supply voltage via the second series resistor 16 to the second AC voltage terminal 6b; 6c of the first network device 6, so that the timer 3 and the auxiliary relay coil HR continue to be fed from the first power supply unit 6 despite the de-energized state of the first AC voltage connection 6a; 6c. By switching the auxiliary relay also becomes the second voltage divider resistor 14b connected in parallel to the first voltage divider resistor 14a and thereby the Sensitivity of the light sensor voltage divider 14, which is no longer the presence monitored by extraneous light, but rather the appearance of a flame, reduced. aside from that the third power supply unit 8 is now also in operation, so that the flame relay coil FR now has a powerful power supply.

With the start of the safety time, the working relay picks up and puts voltage on the first fuel valve coil BVl via br, uhr2 ,, ar2, see above that now, since the ignition transformer has been under voltage since the start of the prepurge time tv the generation of a flame is started.

Arises from any cause of failure during the safety period there is no flame, the auxiliary relay drops out at the end of the safety time and triggers the fault release with the help of its first opening contact, since yes meanwhile the first NO contact ar 1 of the working relay has been closed. while the flame relay has still not responded due to the lack of a flame on the other hand, correctly a flame during the safety time ts, then on the one hand draws the flame relay and on the other hand the output of the flame relay amplifier starts 5 via the second input 3b in the timer 3, the generation of an interval or

Post-ignition time ph which ends later than the safety time ta. The auxiliary relay now drops only after the time ti has elapsed and this time does not trigger any interference off, since the opening contact frb of the flame relay is now the fault trigger path has separated. The auxiliary relay also connects via br, f. Hr2b the second fuel valve coil BV2 and the first input 10a of the repetition circuit 10 on voltage, so that the burner control 1 is now fully in operation.

At the same time, the first make contact hr 1a disconnects the ignition transformer ZT from the supply voltage. After completion of this commissioning phase, these are Auxiliary relay in the de-energized and the working relay and the flame relay in the energized State. In the event of a flame failure caused by any malfunction during the subsequent operating phase is in many cases smaller or smaller burners middle Power an automatic restart of the automatic burner control 1 desired, without blocking the burner unnecessarily. This is done with the help of the repetition circuit 10.

The operation of the repetition circuit -10 is now under simultaneous Consideration of the F i g. 1 on the basis of FIG. 2 described. Because the repeater circuit 10 from the start of the pre-purge time t, with their supply voltages at the two supply inputs 10c and l0d is provided and the series circuit, consisting of the Zener diode ZD, the second resistor R 2, the first diode D 1 and the first resistor R 1, is connected as a voltage divider, the first output of which controls the amplifier 32, the output of the amplifier 32 is switched through to ground and the reset semiconductor switch 31 not conductive to ground. The first input 10a of the repetition circuit 10 is on the second fuel valve coil BV2 (see Fig. 1) to ground and the second diode D2 is blocked. As long as during pre-purge time 1 and the following Safety time t, no extraneous light or

If there is no flame, the preliminary stage 25 of the flame relay amplifier has 5 no output voltage and the second input 10b is therefore connected to ground (see Fig. 1). As a result, the third diode D3 is conductive in FIG. The first capacitor C1 is however over ZD, R 2, R4 and D3 because of an existing voltage limit only lightly charged. If the flame arises during the safety time ts, SO arises a voltage at the output of the preliminary stage 25, the third via the second input 10b Diode D3 blocks. At the end of the interval or post-ignition time ti appears above hr2b the supply voltage U2 at the first input 10a of the repetition circuit 10 (see F. i g. 1), so that the positive half-waves of the supply voltage U2 over the then conductive second diode D 2 charge the first capacitor C I via R 3, D 2, R 4, D 1 and R 1. This does not yet lead to a change at the output of the repetition circuit 10. If there is now a flame failure for any reason, then on the one hand it falls the flame relay and makes the second with the help of its closing contact fra Fluid valve coil BV2 de-energized, so that the first input 10a of the repetition circuit 10 is back to ground. The second diode D 2 is blocked again. on the other hand the output of the preliminary stage 25 is also de-energized because of the flame failure. so that the second input 10b of the repetition circuit 10 is again connected to ground (see Fig. 1).

Through the sudden connection to ground with the help of the third diode D3 of the positively charged pole of the first capacitor C1 becomes the input of the amplifier 32 is applied to a negative voltage so that the output of amplifier 32 does not is more conductive to ground and the reset semiconductor switch 31 to Ground becomes conductive. This discharges the capacitors in the two timing elements 18 and 22 of the timer 2 and 4 are included, via the discharge resistor 11 and the reset semiconductor switch 31 or via the discharge Zener diode 12, the discharge resistor 11 and the reset semiconductor switch 31.

As a result, the working relay is also the last to be picked up Relay reset. This also increases the output of the positive feedback Amplifier 19 again de-energized. In the meantime the first capacitor charges C1 of the repetition circuit 10 again via ZD, R 2, R 4 and D 3 to, so that the voltage at the input of the amplifier 32 rises again and after a certain time the output of the amplifier 32 becomes conductive to ground again. The reset semiconductor switch 31 is then again non-conductive. The burner control 1 is now back in the State that it had at the beginning of the pre-purge time tv and there the controller closing contact R is still closed, the automatic burner control 1 will again be automatic as desired started. Since it is possible that the fire box linings because of the preceding The burner control will stop the combustion chamber still glowing after it is hot in operation 1 determines the presence of extraneous light in this case. The afterglow disappears however, before the working relay is pulled in again, the relay used is delayed Type of extraneous light monitoring at most causes timer 3 to start no unnecessary interference, which is a great advantage of the external light monitoring used is.

If the flame fails before the end of the interval or post-ignition time b so the first capacitor Cl I cannot be reloaded and it takes place accordingly also no resetting of the timers 18 and 22 and no resetting of the working relay. In this case, the drop in the auxiliary relay at the end of the interval or Post-ignition time without lockout.

The one shown in FIG. The second timer 3 shown in FIG. 3 operates as follows: During the pre-purge time tv, the positive half-waves of an alternating voltage AC voltage applied to the input pole 3c the second capacitor C2 via D6, R7, R8, D4, D 5 and R 6. At the end of the pre-purge time tv appears from the output of the voltage divider 13 coming from (see FIG. 1) at the first input 3a of the timer 3 a voltage, so that the input semiconductor switch T1 is conductive to ground and the second Capacitor C2 reloads via R 5, R8 and T1. But first is through switching of the input semiconductor switch T 1, the positively charged pole of the second capacitor C2 suddenly connected to ground, so that a negative voltage at the input of the preamplifier 33 appears.

The output of the preamplifier 33, which is connected to ground, becomes non-conductive and the auxiliary relay semiconductor sounder 21 conductive, so that the auxiliary relay picks up. The charge reversal of the second capacitor C2 reduces the voltage at the input of the preamplifier 33 again, so that if a flame does not appear after the expiry the safety time ts of the auxiliary relay semiconductor switch 21 again non-conductive and the auxiliary relay drops out again. At the beginning of the safety time ts will also according to FIG. t with the help of the second closing contact hr2 of the picking up auxiliary relay the third power supply unit 8 put into operation, the output of which via the flame relay coil FR feeds the second input 3b of the timer 3, so that within the same the third capacitor C3 is charged through R9, D5 and R6. Decoupled in this phase the blocked fourth diode D4 the two RC series circuits R 8; C2 and R9; C3. If a flame appears during the safety time t, the output of the Flame relay amplifier 5, the second input 3b of the timer 3 via the emitter resistor 29 connected to ground and thus the interval or post-ignition time tj started. Because of this sudden grounding of the positively charged pole of the third capacitor C3 The input of the preamplifier 33 is still via the fourth diode D4, which is now conducting biased more negatively, so that the auxiliary relay also after the safety time ts remains attracted. Meanwhile, the third capacitor C3 across R 5, D 4 and R 9 reloaded so that the voltage at the input of the preamplifier 33 rises again. After the interval or post-ignition time t; has the input voltage of the preamplifier 33 reaches such a high value that the output of the preamplifier connected to ground 33 again conductive and thus the auxiliary relay semiconductor switch 21 again non-conductive will. The auxiliary relay drops out at this moment.

Since the charging of the third capacitor C3 at the time t before Start of the safety time ts begins, the amount of charge on the capacitor C3 is from Depends on the time of the flame signal. That means, if the flame is reported early, he has Capacitor C3 only has a low effectiveness and the interval or post-ignition time ti ends only slightly after the end of the safety time ts. In the event of a later flame report the capacitor C3 has a correspondingly higher charge, so that the drop of the auxiliary relay more delayed and the interval or post-ignition time ti ended accordingly later will.

As can be seen from the description so far, the timer generates 3 both the safety time ts and the interval or post-ignition time t.

By connecting the first make contact ar 1 des Working relay with the first AC voltage connection 6a; 6c of the power supply unit 6 it is achieved that during the pre-purge time tv the power supply of the timer 3 flows via the fault trigger path without the power supply current flowing through the blocking relay falls off because it has the wrong polarity. If there is a fault-related If the disturbance trigger path is interrupted before or during the pre-purge time tv, this is also the case the power supply of the timer 3 is interrupted and so the start of the safety time ts prevented.

Commissioning is thus interrupted in spite of the defective interference trigger path and fuel cannot be approved. The only part of the noise release path which is not traversed by the power supply of the timer 3 is the first Closing contact ar 1 of the working relay with its connections. If there is a line interruption there or if the normally open contact ar 1 is not closed incorrectly, operational reliability remains still fully guaranteed. The presence of the positive feedback amplifier 19 has the effect in this case that if there is an additional malfunction, such as B. no flame formation during the time ts, this is not dangerous State leads, since the auxiliary relay activates the fuel valve coils at the latest after the time ts has elapsed BV1 and BV2 de-energized and because of the positive feedback permanently pending output voltage of timer 2 a new automatic start of the timer 3 prevented. The automatic burner control 1 is thus in spite of the non-response of the blocking relay blocked at least as long as the automatic burner control 1 below There is tension.

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Claims (9)

Claims: 1. Circuit for an automatic furnace (1) with a second and third controlled by a common first timer (2) Timer (3, 4) with a flame relay amplifier controlled by a light sensor (LF) (5) and with an interference release path containing a blocking relay coil (BR), wherein the output of the second timer (3) on an auxiliary relay coil (HR). the exit of the third timer (4) to a working relay coil (AR) and the output of the Flame relay amplifier (5) is led to a flame relay coil (FR), thereby characterized in that at least one opening contact (er6) of the flame relay (FR; fr), a first opening contact (hr 1 b) of the auxiliary relay (HR; hr 1; hr2) and a first closing contact (ar 1) of the working relay (AR; ar 1; ar2) with the blocking relay coil (BR) are connected in series that a first AC voltage connection (6a; 6c) a first power supply unit (6), the DC voltage output (6d; 6c) of which only the second The timer (3) and the auxiliary relay coil (HR) are fed in parallel to the first make contact (ar 1) of the working relay (AR; ar 1; ar2) is switched and that the output circuit of the first timer (2) consists of a positive feedback amplifier (19). 2. Circuit according to claim 1, characterized in that the positive The feedback amplifier (19) contains a feedback element (19b; 19c) which consists of a feedback zener diode (19b) and a feedback resistor (19c). 3. A circuit according to claim 1 or 2, characterized in that when Presence of extraneous light at the end of a pre-ventilation time generated by the first timer (2) (tv) the second timer (3) is blocked and then after a the pull-in delay time (ta) generated by the third timer (4) triggers a disturbance is triggered. 4. A circuit according to claim 3, characterized in that the first Timer (2), the third timer (4) via the working relay coil (AR) and one Pre-stage (25) of the flame relay amplifier (5) from a second power supply unit (7) and an output stage (26) of the flame relay amplifier (5) via the flame relay coil (FR) are fed by a third power supply unit (8) that the output of the first timer (2) via a voltage divider consisting of three load resistors (13a, 13b, 13c) (13) is connected to the second timer (3), which is a lower voltage having voltage divider output at a first input (3a) of the second timer (3) while the higher voltage divider output via the flame relay coil (FR) to the output of the flame relay amplifier (5) is connected, and that the output stage (26) of the flame relay amplifier (5) when present Light conducts to ground. 5. Circuit according to one of claims 1 to 4, characterized in that that a repetition circuit (10) is available for a flame failure during operation is for discharging capacitors in the first and third timer (2, 4) and for resetting the working relay (AR; ar 1: ar2). 6. Circuit according to claim 5, characterized draws that a first Input (10a) of the repetition circuit (10) with one pole of a fuel valve coil (BV2) and its second input (10b) with the output of a pre-stage (25) of the flame relay amplifier (5) is connected, while its output via a Discharge resistor (11) to the output of one contained in the first timer (2) Timing element (18) and is led to the cathode of a discharge Zener diode (12), its anode with the output of a delay timer element contained in the third timer (4) (22) is connected. 7. Circuit according to claim 5 or 6, characterized in that the repetition circuit (10) has a reset semiconductor switch at its output (31) which is controlled by the output of an amplifier (32) that the input of the amplifier (32) on the one hand via a resistor (R 1) with a supply pole of the amplifier (32) and connected to one pole of the reset semiconductor switch (31) and on the other hand via a first diode (D 1) to a first pole of a first RC series circuit (R 4; C 1) is performed that the other supply pole of the amplifier (32) at a first supply input (10c) and the first pole of the first RC series circuit (R 4; C 1) via a resistor (R 2) and a Zener diode (ZD) to a second Feed input (lOd) of the repetition circuit (10) and that the second pole of the first RC series circuit (R 4; C1) via a second diode (D 2) and a resistor (R3) to the first input (10a) and via a third diode (D3) to the second Input (10b) of the repetition circuit (10) is connected. 8. A circuit according to claim 7, characterized in that the two Feed inputs (10c, 10d) of the repetition circuit (10) from different power supply units (7, 9) are fed and that the power supply unit feeding the second feed input (10d) (9) Has no stabilization circuit. 9. Circuit according to one of claims 1 to 8, characterized in that that the second timer (3) has an auxiliary relay semiconductor switch at its output (21), which is controlled by a preamplifier (33), that the input of the preamplifier (33) on the one hand via a resistor (R 5) each with a feed pole of the preamplifier (33) and the second timer (3) is connected and on the other hand via a first diode / resistor series circuit (D 4; D 5; R 6) to the other Feed pole of the preamplifier (33) and the second timer (3) as well as one Pole of the auxiliary relay semiconductor switch (21) is that the input of the preamplifier (33) additionally via a second RC series circuit (R 8; C2) and a subsequent one second diode / resistor series circuit (D 6; R 7) with an AC voltage input pole (3c) of the second timer (3) is connected, the one from the preamplifier (33) remote pole of the second RC series circuit (R 8; C2) via an input semiconductor switch (T1), whose sleeve input is a first input (3.w) of the second timer (3) forms, is connected to ground, and that the first diode / resistor series circuit (D 4; D 5; R 6) in the specified order from the input of the preamplifier (33) starting from a fourth diode (D 4), a fifth diode (D5) and a resistor (R 6), the two diodes (D4, D5) being polarized in the same direction and the common pole of the two diodes (D4, D5) via a third RC series circuit (R 9; C3) is led to the output of the flame relay amplifier (5). Field of application and purpose The invention relates to a circuit for an automatic furnace according to the preamble of claim 1. State of the art From the publication 7433 »Automatic gas burner control LFM 1 ... «from August 1979 from Landis & Gyr, Zug, Switzerland is a circuit of the type mentioned with an existing working relay. Auxiliary relay, flame relay and Blocking relay known. Problem and Solution The invention is based on the object the partial electronification of automatic oil or gas firing systems as economically as possible and taking into account the valid norms as well as limited existing ones Space conditions to guarantee the operational safety of the automatic firing systems, if an existing interference trigger path itself is disturbed. It is allowed in this case no dangerous conditions arise in the automatic burner control. The stated object is achieved according to the invention by means of the characteristics of claim 1 specified features solved. Advantageous further developments of the invention are set out in the subclaims 2 to 9 indicated. An embodiment of the invention is shown in the drawing and is described in more detail below. It shows F i g. 1 is a block diagram of a Automatic firing systems, F i g. 2 shows a circuit diagram of a repetition circuit and FIG. 3 is a circuit diagram of a timer for generating a safety and interval time. The same reference numbers denote the same in all figures of the drawing Parts.