DE2448098C2 - Circuit supplied with alternating voltage for a flame monitor in a combustion system - Google Patents

Description

The invention relates to a circuit fed with alternating voltage for a flame detector Combustion system with the features of the preamble of claim 1.

In a known circuit of this type (LAI 2 amplifier from Landis & Gyr), the voltage ratios at the voltage divider can be changed as a result that an alternating voltage is applied to the first terminal and thereby such a charging of the Second charging capacitor is achieved that the sensitivity is reduced. Since this tension is on At the end of the pre-ignition period is applied to the first connection, one obtains during the pre-ignition period a higher sensitivity of the flame, guard and during the actual operating time a normal sensitivity.

In another known circuit (CH-PS 4 83,000) the sensitivity of the flame awake tcrs by switching the voltage divider on and off resisted changed. Here are those of one Relay operated switch within the voltage stci lers arranged so that only at these switches a small voltage difference anlicgi. Through this looks at the company. that if the switch is dirty em impeccable conversion of the sensitivity of the Flammcnuber.vachungseinrichlung rock is. here with the series connection, the Vti stronger and that

1 line relay from the secondary side of a Transfor nialors fed

In another known circuit (AT-PS

2 17 611) the Fotowidersland is part of a Rcihensth.il lung, which as well as the amplifier and that Flummcnrelais from the secondary rope of a mn Mains voltage-fed transformer via a diode, which is followed by a smoothing capacitor. be supplied with voltage

In another known circuit (DE-AS 19 ¹ JI 4 52) the voltage supply of a capacitor, a resistor and a Zci.er'Jiode is applied to the voltage. where in the Zener diode the operating voltage for the Flammclais, the series sounding with the f-olowidersl.ind and a thyristor serving as an amplifier is tapped. In this case, the sensitivity wedge is changed in that, by switching on an inductance, the voltage between the anode and cathode experiences a phase shift in relation to the voltage between the control electrode and the cathode.

The invention is based on the task, a Specify circuit of the type described above, which, in addition to its normal sensitivity, not only one higher, but also lower sensitivity can be obtained and in the case of contamination of the for Switching the required sensitivity switch is less critical.

According to the invention, this object is achieved by that the terminal of the second charging capacitor facing away from the point of fixed voltage has a third rectifier is connected to a second terminal which is connected to the AC voltage can be laid in that the third rectifier is opposite to the second rectifier is polarized that the first connection to increase the sensitivity during the pre-ignition period and the second connection to reduce the sensitivity during a post-ignition period to the alternating voltage are connected and that the connection between the first terminal and the voltage divider is made solely through the tap, not through the connection ends of the voltage divider.

The second charging capacitor v. Is charged in one direction when the first switch is closed and in the other direction when the second switch is closed, as a result of which the current through part of the voltage divider increases or decreases. As a result, higher or lower values of the exposure necessary to bring the amplifier or as ^r, flame relay to operate. The flame monitor circuit has its normal sensitivity when the switches are open, i.e. during normal operation. A fault with the switches, e.g. B. if the contact is dirty, or an interruption in the supply line does not affect normal operation. During the pre-ignition period, by applying the alternating voltage to the first connection, there is a higher sensitivity, with the help of which extraneous light can be detected better the flame is ineffective. so the ignition device is not switched off as a result of a weak or interrupted flame.

When the switch is open, the full AC voltage is applied to the switch (at a mains voltage of 220 V i.e. a peak value of 311 V). while on the voltage divider a low voltage of 39 V, for example. As a result of this high voltage difference any contamination on the switch is burned away. Therefore, there is no danger that as a result of such contamination, the switch no longer works.

It is particularly favorable if the connection of the / further charging capacitor facing away from the point of fixed voltage is connected to the control tap il.s voltage divider via a resistor. There is one end of the charging capacitor fixed in terms of voltage is. the other end charges from the first port in one direction and from that / linger connection btr in the other direction. This voltage then acts directly through the resistor on the control tap of the voltage divider, what a very simple circuit results.

It is particularly advantageous that with a resistor in series with the second rectifier polarized opposite / around the first rectifier lies. With the help of the series resistor, the charging voltage of the second charging capacitor can be adjusted depending on differently for the selected connection.

In a preferred embodiment, gc ^fl 5 ensures that the second connection to reduce the sensitivity wedge is connected to the supply line via the series connection of the normally open contact of a first switch of a time relay, the normally closed contact of a second switch of the time relay that switches later and a normally closed contact of a second switch of the flame relay and an ignition device is connected to the supply line via the normally closed contact of the first switch of the flame relay. In this way, the effectiveness of the flame monitor is completely suppressed during a post-ignition period. Even if a flame is formed, it does not respond. As a result, the switch of the flame relay controlling the ignition device remains closed. If the normal sensitivity of the flame monitor is restored at the end of the post-ignition period, the flame relay immediately switches off the ignition device.

Furthermore, to increase the sensitivity, the first connection can be connected to the normally closed contact of a first switch of the timing relay which responds at the end of the pre-ignition period and is connected to the supply line, to the normally open contact of which a fuel feed element is connected and which, when the flame relay responds in its operating position ¹ ^ ig is mechanically lockable. In the case of this known switch, which is necessary for delayed switching on of the fuel delivery, the rest position is used in order to give the flame monitor increased sensitivity during the preignition period. The consequence of this is that a test for false light is carried out with increased sensitivity. False light is therefore detected with greater certainty. As soon as the switch is in its working position, the flame monitor receives its normal sensitivity with which it can determine the formation of the flame. As soon as the flame has arisen. the switch is locked in its working position and monitored by the flame relay.

The invention is explained in more detail below with reference to an exemplary embodiment shown in the drawing explained. Fs is the circuit for an inventive Flame monitor with the associated switches from t lammenrclais and timing relay illustrated.

[in / and- and monitoring device controls a fan motor M. a first solenoid valve MV 1 for a small «. Amount of oil. a / wide solenoid valve MV 2 for an Ihuiptölmengc and an ignition transformer ΊΎ. There is also a flame monitoring circuit FW with a flame relay. which has a magnet winding F , which controls two switches F \ and F2 , is provided. There is also a thermal time relay, the heating coil P of which has a first switch Pi , which is operated at the end of the pre / and period, a switch / '2 operated at the end of the post / and period, and a third safety switch P 3, which is operated at the end of the security period having. The switch PX is controlled by a mechanical lock Fl. when the flame is excited, the irilais is locked in the position it is currently in.

The device is operated a 1 the mains terminals I and 2 with an AC / AC voltage, for example 220 V. A live supply line 3 is connected to the Nci / terminal 1, in which a boiler thermoseai KT, which switches on the device, and the Sichcrheilbswhaller Pi are located. Cm neutral conductor 4 is connected to terminal 2. In the event of a failure, the safety switch switches from its normally closed contact. / To its normally open contact b, whereby the device is switched off and instead an indicator lamp L is connected to voltage via a resistor R 1.

The flame monitor FW has a first charging capacitor C \ , which has a first rectifier

Di and a capacitor C2 is placed between lines 3 and 4. A Zener diode Z is connected in parallel to the charging capacitor 1 and the first rectifier D 1, so that a DC voltage of 39 V, for example, is available at the charging capacitor C 1. This voltage feeds a voltage divider with the Ohrrischen resistors R2, R3 and R 4 as well as the photoresistor LD , as a result of which there is a voltage at the tap 5 that is dependent on the exposure state. Furthermore, a voltage divider consisting of the ohmic resistors R 5 and R 6 is connected in parallel with the first charging capacitor Cl and forms a tap 6. A rectifier D 2 is placed between the taps 5 and 6. Two transistors TrI and Tr 2 serve as amplifiers. The base of the first transistor TrI is connected to the tap 5, its emitter to the tap 6 and its collector to the base of the second transistor Tr2 . Its emitter is connected to Nulle'ier A. while its collector is connected to a tap 7 between the resistors R2 and R 3 via the magnet winding F of the flame relay, which is bridged by a rectifier D 3.

Two connections A and B , which can be connected to the supply line 3, are provided for arbitrarily changing the sensitivity of the flame monitor FW. A / further charging capacitor C3 is connected in series with the first charging capacitor CI, together with a limiting resistor R 7. The end 8 of the second charging capacitor C3 facing away from the first charging capacitor CI is connected to the first connection A via a second rectifier DA and a resistor R 8 and to the second connection B via a third rectifier D 5. The third rectifier D 5 has the same forward direction * as the first rectifier D I; the second rectifier D4 has the opposite forward direction. The capacitor end 8 is connected to the tap 5 via a resistor R9.

In the case of the flame monitor FW , the transistors Tr 1 and Tr2 form a trigger amplifier because its output is coupled to the input 5 via the resistor /? 3. Normally, the current through the voltage divider K2, KJ, «4, LD is only given by the Wide ι -suiikK value of the photoresistor LD . If, however, a current flows through the transistor Tr2 , there is a larger voltage drop across the resistor R 2, as a result of which the voltage at the tap 5 drops. As a result, the flame relay is safely switched on when a threshold value is exceeded. If, for example, a resistance value of the photoresistor LD of about 150 kilo ohms is sufficient to energize the flame relay, the resistance value must rise to about 200 kilo ohms as a result of less lighting before it drops again.

If the mains voltage is applied to the first terminal A , the second charging capacitor C3 is charged in the negative half cycle. This leads to an increase in the current in the resistors R 2 and R3, as a result of which the voltage at the tap 5 drops. This results in increased sensitivity, since less lighting is now sufficient to cause the amplifier to tip over.

If, on the other hand, the mains voltage is connected to the second connection B , the second charging capacitor C3 charges in the positive half-cycle, which leads to an increase in the current in the resistors R 4 and LD that even the short-circuit the photoresistor LD the voltage has a sufficiently high value at the tap 5 to as "Photoswitches to let Unconfirmed.
This circuit results in the following mode of operation.

When the boiler thermostat KT closes, the blower motor M is started. At the same time, the ignition transformer TT and the heating winding P of the timing relay are connected to voltage via the normally closed contact «of switch F \ of the flame relay. In addition, the first connection A is supplied with mains voltage via the normally closed contact a of the first switch Pi of the timing relay. This results in a pre-ignition period. in which the combustion area is vented and, at the same time, with an increased sensitivity wedge, a false test is carried out! takes place. At the end of the pre-ignition period, the first switch P \ of the Zeilrelais goes to its normally open contact b. This opens the solenoid valve MV1. At the same mains voltage via the series circuit of the working contact b of the first switch P 1 of the normally closed contact a of second switch P2 and the normally closed contact a of the switch F2 to the second terminal set ß, so that the flame detector is FVVunempfindlich and does not respond, even if due to the presence of the ignition and the oil forms a flame. Only at the end of the post-ignition period. when the second switch P2 opens, the flame monitor FW is sensitive to the failure of the mains voltage at the second connection B , and the two switches F1 and F2 go to their working contact b: the lock FL locks the first switch P1 in its working position. As a result, the heating winding P and the ignition transformer TT are separated from the supply line 3 and the switching on of the second solenoid valve MV2 is prepared. As a result of the cooling of the time relay, the second Schaller / '2 returns to its rest position after a predetermined time, whereby the second solenoid valve MV2 is switched on. Now the normal drive has been reached. It is usually interrupted by opening the KT boiler thermostat. When the voltage is lost, the solenoid valves MV 1 close

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Flame relay drops out. whereby the switches F1 and F2 return to the illustrated rest position and the lock of the first switch Pl is released, the also returns to the rest position due to bias.

If no flame occurs during the switch-on program, the heating winding P of the cell relay remains connected to voltage via the switch Fl until the Sicliprheilv schaller P3 responds and a fault is reported. As a rule, the safety switch P3 can only be reset manually. If the flame disappears during operation, the two solenoid valves MV 1 and MV2 are switched off because the first switch P1 returns to its rest position due to the withdrawal of the lock FL

In this case, a new ignition attempt can follow immediately, through which it is determined whether the flame for permanent elimination.

If the Fotowidersland LD is hit by false light, the switch Fl of the flame relay goes to the normally open contact b. This happens with great certainty in the pre-ignition period because the sensitivity of the Flsmmenwächers FW has been increased. At the same time, the first switch Pl is locked in its rest position by the lock FL.

st-n, the heating coil P is heated further, and after the safety rope, the Störverschadting takes place by means of the safety switch Γ3. In the event of fur spinning, the same conditions result as when the boiler thermostat KT is switched off. When the voltage reappears, a new ignition takes place. A short-circuit of the Folowider.standcs LD leads to the fact that normal operation is continued until the Kcssellhcrmostaleii KT is switched off: the next time it is switched on, however, the photoresistor is deceptive.

LD Lieht stood in front of him, so that the alarm shutdown occurs after the sickle period. If lines to the photoresistor LD are interrupted, the flame relay drops out immediately.

In addition to the solenoid valves, there are also oil pumps or relays as fuel conveyors for their part influence the oil production.

The switches / ³ I, Pt P3. F \ and Fl are preferably designed as snap switches.

For this purpose J BIaIl drawings

Claims (5)

Patent claims: 1. AC-powered circuit for a flame monitor of a furnace, in 5 of which a photoresistor is part of a voltage divider, which has a tap for controlling a flame relay controlling amplifier, in which a first switch is provided for changing the sensitivity of the flame monitor to feed the flame detector, a first rectifier and a first capacitor that can be charged to a predetermined low direct voltage are connected in series to the alternating voltage. B. a Zener diode, through which a point of fixed voltage is given, at which the voltage divider is parallel to the first charging capacitor, in which a second charging capacitor is arranged in a branch that is connected between the: point of fixed voltage and the tap of the voltage divider is, and in which the second charging capacitor can be charged via its terminal remote from the point of fixed voltage from a first terminal which can be connected to the AC voltage by means of the first switch via a second rectifier, characterized in that the terminal of the second remote from the point of fixed voltage Charging capacitor (O) is connected via a third rectifier (D5) to a / wide terminal (B), which can be connected to the AC voltage via a second switch (P2) so that the third rectifier (D 5) is opposite to the zwriten rectifier (D 4) is polarized that the first connection '' A) to increase the sensitivity during the pre-ignition period and the z wide connection (B) for reducing the sensitivity during a post-ignition period are connected to the AC voltage and that the connection between the first connection (A) and the voltage divider (R 2. Ri, R 4. LD) • No via the tap (5), not via the connection ends of the voltage divider. 2. Sound system according to claim 1, characterized in that the terminal of the second charging capacitor (C 3) facing away from the point of fixed voltage is connected to the control tap (5) of the voltage divider via a resistor (R 9). 3. A circuit according to claim 1 or 2, characterized in that with the opposite to the first rectifier (D 1) polarized / dwell rectifier (D4) a W resistor (RS) is in series. 4. Sheath according to one of claims 1 to 3. characterized in that the second terminal (B) / ur reduction of the sensitivity via the series connection of the working cone (b) of an erit switch (Pl) of a time relay, the normally closed contact (a) of a later switching / wide switch (P2) of the time relay and a normally closed contact fascines second switch (F2 ) of the flame relay is connected to the supply line (3) and an ignition device (TT) is connected to the supply line via the normally closed contact (a) of the first switch (Fl) of the flame relay. 5. Circuit according to one of claims 1 to 4, characterized in that the first connection (A) to increase the sensitivity with the rest ^ contact (a) of an arri Ertde of the pre-ignition period to · »connected ₍ to the lead (3)) first switch (P ¹ I) of the timing relay is connected, to whose working contact (b) a fuel delivery device CMVI) is connected and which can be mechanically locked in its working position when the flame relay is triggered.