CH615497A5 - Control and monitoring device for an oil or gas burner - Google Patents

Description

The invention relates to a control and monitoring device for an oil or gas burner, with a flame relay gg included in a flame guard circuit and a thermal time relay determining a pre-ignition period and a post-ignition period, the switches of which have at least one fuel delivery element, an ignition device and the heating winding supply the time relay with voltage, the flame monitor circuit being connected to the live line at least when the device is switched on gj and if the flame relay triggers a switch-off before the flame occurs.

In a known device of this type, the switch of the flame relay is connected on one side to the supply line having a thermostat switch and a safety switch and on the other side to the ignition device. A changeover switch of the timing relay connects a point between the switch of the timing relay and the ignition device in the rest position with the heating winding of the timing relay and in the working position with the magnetic winding of a motor relay, which can be connected to the supply line via a self-holding contact. The flame guard circuit is already effective during the pre-ignition period. However, it only has a normal sensitivity that is adapted to the flame. However, it is often desirable to check for false light with increased sensitivity during the pre-ignition period.

In another known flame monitor circuit, which is transformer-coupled to the mains AC voltage, the sensitivity can be changed by including a parallel resistor in the voltage divider having the photoresistor, which can be switched off by means of a switch actuated by the fuel relay. This arrangement is prone to failure. If the switch hangs mechanically or makes no contact due to contamination, there is no state of high sensitivity and the burner is switched on without checking for false light.

It has also already been proposed to change the voltage conditions on the voltage divider having the photoresistor to increase the sensitivity in that the AC mains voltage can be supplied not only to the normal connections, but also to an additional connection via a switch. The problem also arises here that a state of high sensitivity does not arise if the switch makes no contact.

The invention has for its object to provide a control and monitoring device of the type described in the introduction, in which the test for false light is ensured without the test of other functions being impaired.

According to the invention, this object is achieved by

that the flame monitor circuit is designed for a higher sensitivity and only assumes a lower sensitivity adapted to the flame when a voltage is applied to an additional connection, and that this additional connection is connected to the line leading to the fuel delivery device.

With this arrangement, the flame detector circuit has a high sensitivity in the normal state. A false light test must therefore be carried out after switching on. Switching to normal sensitivity is done via the same switch that also energizes the fuel delivery device. If this switch does not make any contact, the sensitivity of the flame detector circuit is not reduced; however, there is also no fuel subsidy. The device is therefore switched off after a predetermined safety time. Because of the voltage control in the branch of the additional connection in the flame monitor circuit, there is no need for any further switches and the associated malfunctions.

In a preferred embodiment, the switch of the time relay can be locked in its working position by a lock to be actuated when the flame is present by the armature of the flame relay, and its working contact is connected both to the fuel delivery element and to the additional connection. If the switch of the timing relay touches the make contact and then has activated the flame relay, the switch is locked mechanically, so that as long as the flame relay remains energized, both

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the fuel delivery element and the additional connection are securely supplied with voltage.

Furthermore, it is advantageous if the heating winding of the timing relay also actuates a safety switch and is connected to the live supply line via a normally closed contact of the switch of the flame relay, if the normally closed contact of the switch of the timing relay is connected to a normally open contact of the switch of the flame relay and if the lock of the Flame relay can also lock the switch of the timing relay in its rest position. If the flame monitor circuit responds to false light in the pre-ignition period, on the one hand the switch of the timer relay is locked in its rest position and on the other hand the switch of the flame relay is connected to it, so that the heating winding is continuously live until the safety switch is actuated.

A wide variety of circuits can be considered as a flame monitor circuit, the sensitivity of which can be reduced by applying a voltage to an additional connection. For example, a circuit according to German patent application P 24 48 098.6-13 is suitable for this purpose if it is designed for high sensitivity and the branch with the additional connection reducing the sensitivity is designed so that normal sensitivity occurs when a voltage is applied.

In a preferred embodiment, however, it is ensured that the flame monitor circuit has the parallel connection of a first Zener diode with the series connection of a first rectifier and a first capacitor and with the series connection of a second Zener diode, a second rectifier and a second capacitor, which parallel connection on the one hand at the zero Conductor and, on the other hand, upstream of impedances is located at a connection connected to the live supply line, with respect to this connection the first zener diode having a forward direction opposite to the second zener diode and the rectifiers, that the additional connection has a pre-impedance with a point between the second zener diode and the second rectifier and that the voltage divider having the photoresistor is parallel to the second capacitor. If an AC mains voltage is only applied to the first-mentioned connection, the voltage divider is supplied with a smaller DC voltage determined by the first Zener diode, which results in a high sensitivity. If, on the other hand, the AC voltage is also at the additional connection, the voltage divider is fed with a higher DC voltage, which is predetermined by the sum of both Zener voltages, which results in a state of low sensitivity.

Furthermore, a circuit having the flame relay winding and an associated amplifier can be connected in parallel to the first capacitor. This circuit is therefore always supplied with the low DC voltage, which is predetermined by the first Zener diode, regardless of whether the additional connection is live or not.

The invention is explained below with reference to an embodiment shown in the drawing. The drawing shows the circuit diagram of an inventive control and monitoring device for an oil burner.

The device controls a blower motor M, a solenoid valve MV for the fuel oil and an ignition transformer TT. Furthermore, a flame monitor circuit with a flame relay is provided, which has a magnetic winding F and controls a switch Fi. Furthermore, there is a thermal time relay, the heating winding P of which has a first switch Pi actuated at the end of the pre-ignition period and a safety switch P2 actuated at the end of the safety time. The switch Pi will, as is done by the lock FL

is indicated, locked when the flame relay is energized in the position in which it is currently.

The device is operated at network terminals 1 and 2 with an AC voltage of, for example, 220 V. A live supply line 3 is connected to the power terminal 1, in which there is a boiler thermostat KT that switches on the device and the safety switch P2. A neutral conductor 4 is connected to terminal 2. In the event of a fault, the safety switch P2 switches from its normally closed contact a to its normally open contact b, as a result of which the device is switched off and instead an indicator lamp L is connected to voltage via a resistor Ri.

The flame monitor FW has a connection 5 connected to the live supply line 3 and a connection 6 connected to the neutral conductor. Between these connections there is a series connection consisting of a series resistor R2 and a capacitor Ci and a parallel connection which has a first Zener diode Zi in the first branch , in the second branch the series connection of a first rectifier Di and a capacitor C2 and in the third branch the series connection of a second Zener diode Z2, a second rectifier D2 and a further capacitor C3. The Zener diode Zi has a forward direction which is opposite to the Zener diode Z2 and the rectifiers Di and D2. In parallel with the capacitor Cs, that is between the point 7 and the neutral conductor 4, there is a voltage divider having a photoresistor LD. A resistor R3 is located between the connection point 7 and the tap 8. Between the tap 8 and the neutral conductor 4 is the parallel connection of the photoresistor LD and a resistor R4. Parallel to the capacitor C2, ie between a connection point 9 and the neutral conductor 4, there is a second voltage divider which consists of the resistors R5 and Re. Its tap 10 is connected to the emitter of an input transistor Tri of an amplifier. Its base lies on tap 8 of the first-mentioned voltage divider and is connected to tap 10 via a diode D3. Its collector is connected to the base of an output transistor Tr2. Its emitter is connected to the neutral conductor 4 via an emitter resistor R7.

Its collector is connected via the parallel connection of the magnetic winding F of the flame relay, a capacitor C4 and a rectifier D4 to the connection points 9, and via a feedback resistor Rs to the base of the input transistor Tri.

An additional connection 11 is connected to a point 12 between the second Zener diode Z2 and the second diode D2 via two series resistors R9 and Rio connected in parallel. It is firmly connected to the line 13 leading to the fuel solenoid valve MV.

If there is an AC voltage between the terminals 5 and 6, the capacitor C2 charges to a DC voltage value predetermined by the Zener voltage of the Zener diode Zi, e.g. B. to 39 V. The other capacitor C3 is also charged to this voltage. The series circuit R3, R4, LD is therefore fed with a relatively low DC voltage. The voltage at the tap 8 therefore drops below the voltage of the tap 10 even under relatively weak lighting, so that the transistors Tn and Tß become conductive and the flame relay responds. The flame guard is therefore very sensitive. The amplifier has a toggle or switching behavior because the output is connected to the input via the feedback resistor R8. This means that the flame relay only drops again when the resistance value of the photoresistor LD has risen to a higher value than was required for the response due to less lighting. Now a change5 to the additional connection 11

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sel voltage applied, the capacitor Cs charges to a DC voltage which corresponds to the sum of the Zener voltages of both Zener diodes Zi and Z2. This higher DC voltage requires a stronger exposure of the photoresistor LD before the voltage at tap 8 drops below the voltage at tap 10, which is still determined by the constant voltage across capacitor R2. This gives the state of normal sensitivity adjusted to the flame.

The diode Dg serves to limit the counter voltage across the base-emitter path of the input transistor Tri. The capacitor C4 is connected in parallel to the relay winding F in order to delay a drop in the flame relay. The diode D4 prevents polarity reversal of the capacitor C4 when the output transistor Tr * interrupts the current. The emitter resistor R7 limits the charging current of the capacitor C4 when the transistor Tr2 becomes conductive. On the other hand, it ensures that the flame relay F does not pick up when the photo resistor LD is short-circuited. If the voltage at point 8 becomes zero in the event of such a short circuit, it also breaks down at point 10 because there is a connection via the base-emitter path of the input transistor Tri. Consequently, at the base of the output transistor there is at most a small voltage which, taking into account the voltage drop across the resistor R7, is not able to drive this on to such an extent that a current which is sufficient to attract the flame relay F flows. The parallel resistor R4 is provided in order to achieve a well-defined maximum resistance value between the base of the transistor Tn and the neutral conductor 4. The resistors R9 and Rio are connected in parallel in order to achieve higher security. If one of the resistors is interrupted, the function is fully retained. The two resistors are expediently mounted at a distance from one another.

This circuit has the following operating mode:

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 time relay are connected to voltage via the normally closed contact a of the switch Fi of the flame relay. In addition, the voltage is at connection 5 of the flame monitor. This results in a pre-ignition period in which the combustion chamber is vented and, at the same time, a check for false light takes place with increased sensitivity. At the end of the pre-ignition period, the switch Pi of the timing relay goes from its normally closed contact a to its normally open contact b. This opens the MV solenoid valve. At the same time, the mains voltage is applied to the additional connection 11 and the flame monitor FW is switched to normal sensitivity. After a while the flame guard responds; the switch Fi goes to its normally open contact b and the lock FL locks the switch Pi of the timer in its working position. At the same time, the heating winding P of the timer and the ignition transformer TT are switched off, so that the post-ignition period is also ended. Normal operation is now reached. As a rule, it is interrupted by opening the KT boiler thermostat. When the voltage drops, the solenoid valve MV closes, the motor M comes to a standstill and the flame relay drops out, as a result of which its switch Fi returns to the illustrated rest position and the locking of the switch Pi is released, which also returns to the rest position as a result of pretensioning.

If there is no flame during the switch-on program, the heating winding P of the timing relay remains energized via the switch Fi until the safety switch P2 responds and a fault is reported. As a rule, the safety switch P2 can only be reset manually.

If the flame goes out during operation, the flame relay drops out and the lock FL is withdrawn. As a result, the switch Pi returns to the rest position and the solenoid valve MV is switched off. In this case, another attempt to ignite can be made immediately to determine whether the flame is permanently extinguished.

If the photoresistor LD is hit by false light during the pre-ignition period, the switch Fi of the flame relay goes to the make contact b. At the same time, the switch Pi is locked in its rest position by the lock FL. As a result, the heating winding P is heated further, and after the safety time, the lockout takes place by means of the safety switch P2. If the mains voltage ceased, the same conditions would result as when the KT boiler thermostat was switched off. When the voltage reappears, a new ignition takes place.

A short circuit in the photo resistor LD prevents the flame relay from responding. The radiator P is therefore continuously heated until the safety switch P2 switches.

If the lines to the photo resistor LD are interrupted, the flame relay also drops out and the device switches off.

When the combustion system starts up, it is ensured that the Zener diode Z2 and the rectifier D2 are in order. If these components are interrupted, the amplifier can be designed so that the relay remains de-energized or that it responds. In both cases the safety switch P2 switches off.

In addition to a solenoid valve, an oil pump or a relay, which in turn influences the oil production, can also be used as fuel supply elements. The fuel supply element can also only supply a quantity of ignition oil, while after the flame relay has responded, a further fuel supply element is opened to convey the main quantity.

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Claims (5)

615 497 2nd PATENT CLAIMS 1.Control and monitoring device for an oil or gas burner, with a flame relay included in a flame monitor circuit and a thermal time relay which determines a pre-ignition period and a post-ignition period, 5 whose switches have at least one fuel supply element, an ignition device and the heating winding of the time relay with voltage supply, the flame monitor circuit being connected to the live supply line at least when the device is switched on and a response of the flame relay 10 before the flame occurs causes a switch-off, characterized in that the flame monitor circuit is designed for a higher sensitivity and only by applying a voltage an additional connection (11) assumes a lower sensitivity adapted to the flame and that 15 this additional connection is connected to the line (13) leading to the fuel supply element (MV). 2. Device according to claim 1, characterized in that the switch (Pi) the timing relay in its working position by a presence of the flame from the armature of the 20 flame relay lock (FL) can be locked and its working contact (b) both with the fuel supply member (MV), as well as connected to the additional connection (11). 3. Device according to claim 2, characterized in that the heating effect (P) of the timing relay also actuates a safety switch (P2) and via a normally closed contact (a) of the switch (Fi) of the flame relay is connected to the live supply line (3), that the normally closed contact (a) of the switch (Pi) of the timing relay is connected to a normally open contact (b) of the 30 switch (Fi) of the flame relay and that the lock ( FL) of the flame relay can also lock the switch (Pi) of the timing relay in its rest position (a). 4. Device according to claim 1, characterized in that the flame monitor circuit, the parallel connection of a first 35 Zener diode (Zi) with the series connection of a first rectifier (Di) and a first capacitor (C2) and with the series connection of a second Zener diode (Z2) of a second rectifier (D2) and a second capacitor (C3), which is connected in parallel on the one hand to the zero 40 conductor (4) and on the other hand with upstream impedances (R2, Ci) at a connection (5 ), whereby, based on this connection, the first Zener diode has a forward direction 45 opposite the second Zener diode and the rectifiers, that the additional connection (11) has a point (12) between the second Zener diode and the second via a pre-impedance (Rd, Rio) Rectifier connected and that the voltage divider (Rs, R4, LD) having the photoresistor (LD) is parallel to the second capacitor (C3). 50 5. Device according to claim 4, characterized in that a flame relay winding (F) and an associated amplifier (Tri, Tr2) having circuit in parallel to the first capacitor (C2). 55