DE2825478C2 - Flame monitor connected to AC voltage - Google Patents

Description

The invention relates to a flame monitor connected to AC voltage for automatic firing systems according to the preamble of the claim 1.

Burner controls and their flame monitors must be intrinsically safe, that is, they should be built that way that every defect of a component is detected in the course of a switching sequence and leads to a shutdown or shutdown. leads to a start prevention. This task is fulfilled by an amplifier circuit of a flame monitor the DE-OS 25 07 811, which at the same time also has means to prior to each commissioning by a Switch-on pulse of the flame relay to demonstrate its ability to attract and fall off.

In such a design there are components in which a defect is recognized as described, however, at the time of occurrence during operation, the logoff time of the Flame relay can lead. The time span is under the registration and termination time of the flame relay to understand that from the occurrence of an event to the pick-up or drop-out of the flame relay elapses.

The logon and logoff time of a flame detector must not be allowed for reasons of stable flame formation too short, and the logout time must not be longer than one second for security reasons, whereby for different burners the optimal values of these lines required for trouble-free operation are not always the same and cannot be set in the known flame monitors.

The invention is based on the object of specifying an intrinsically safe flame monitor circuit which the logon and logoff times can be preselected and where the logoff time is in the event of an interruption or Short circuit of components not increased

The invention is characterized in claim 1

An example of the invention is illustrated below with reference to the single drawing figure, which shows a circuit diagram represents a flame monitor, explained in more detail.

With 1 and 2 are a first and a second terminal for connecting the circuit to an AC voltage An amplifier 3 is connected to a first series circuit consisting of the excitation winding a flame relay 4 and a collector resistor 5, connected to terminals 1 and 2, and that is located the collector resistor 5 at the second terminal 2.

The collector-emitter path of an output transistor 6 is connected in parallel with the excitation winding. Between the emitter and the base of the transistor 6 is opposite to the forward direction of this path polarized first diode 7 arranged, while a further, equally polarized Zener diode 8 between the base and the collector of transistor 6 is connected. In parallel with the Zener diode 8, it is opposite to it polarized collector-emitter path of an input transistor 9, the base of which has an input! 0 of the Amplifier 3 forms.

The input 10 is via a resistor 11 and a Component with a voltage-dependent threshold value, in the example described, a Zener diode 12, of which Voltage at a first connection point 13 between a first capacitor 14 and a Flame sensor 15 can be influenced. The capacitor 14 and the flame sensor 15 form one to the Terminals 1 and 2 connected in series, in which the flame sensor 15 is connected to the second terminal 2 lies. An ionization sensor which utilizes the rectifying effect of the flame is used as the flame sensor 15.

Any other flame sensors with a rectifier connected in series can also be used.

Another voltage divider connected to terminals I and 2 to increase the voltage on the first Connection point 13 consists of a further Zener diode 16 and a second capacitor 17, the capacitor 17 being connected to the second terminal 2. A junction 18 between the The capacitor 17 and the Zener diode 16 are connected to the connection point 13 via a diode 19. The Zener diode 16, the diode 19 and the flame sensor 15 form a series circuit with the same polarity Current direction.

The following description refers to an explanation of the mode of action of the DE-OS 25 07 811 known amplifier 3 waived. Be it only noted that the flame relay 4 is energized when the current flow at the input 10 of the Amplifier has fallen below a limit value. This is when AC voltage is applied to the terminals 1 and 2 is the case for the time being, so that the flame relay 4 picks up immediately when it is switched on. During the positives

Voltage half-waves at terminal 1, the capacitor 17 is charged via the Zener diode 16, provided that the flame sensor 15 is non-conductive, i.e. does not indicate a flame in the negative Voltage half-waves, the capacitor 17 transfers its charge via the diode 19 to the capacitor 14. Between the connection point 13 and the terminal 1, that is, above the capacitor 14, a build-up Voltage for which the Zener diode 12 blocks for the time being. When the Zener voltage is reached, it flows in Current to input 10, and the ram relay 4 drops and thus proves the functionality of the amplifier 3.

Instead of the Zener diode 12, any other component with a voltage-dependent one could also be used Threshold value can be used, for example a diac, with which an additional hysteresis between input and switch-off point can be achieved and thus increased security against rattling of the flame relay 4 results

The voltage across the capacitor 14 continues to rise to theirs after the flame relay 4 has dropped out Maximum value. This is determined by the Zener voltage of the Zener diode 16.

As soon as a flame arises, the positive voltage half-waves flow through the flame sensor 15 in addition, a current which reduces the voltage across the capacitor 14 and which removes more charge than in the negative voltage half-wave from the capacitor 17 is supplied. When falling below the zen voltage at the Zener diode 12 this blocks again and the flame relay 4 picks up. The voltage across the capacitor 14 drops further down to its minimum value given by the sum of the forward voltages of the Zener diode 16 and the diode 19.

From what has been said it can be seen that the threshold voltage of the voltage-dependent component, in the described Example of the Zener diode 12, arbitrarily between the minimum and maximum values of the voltage can be placed across the capacitor 14 in order to reduce the logon and logoff time of the flame relay 4 to select. These times are the differential voltages between the threshold voltage and the maximum or Minimum voltage of the capacitor 14 proportional and thus directly from the Zener voltage values the Zener diodes 12 and 16 dependent. The desired times can therefore be through the dates of these Zener diodes can be preselected independently of each other.

The arrangement described ensures that if the flame goes out during operation, the log-off time of the flame relay is always independent of the size of the previously existing Fühierstromes. Only the login time decreases with increasing sensor current.

Any defect in one of the components described causes either a fault shutdown of the downstream Automatic machines in the course of a switching sequence or, depending on the error, an extension or shortening the registration time. It is also possible to shorten the logout time; however, its extension is in avoided in any case.

1 sheet of drawings

Claims (3)

Patent claims: 1. Flame safeguards for automatic firing systems connected to AC voltage, with one on the AC voltage connected to the first series circuit of a first capacitor and a flame sensor that only allows the current to pass in one direction, with a diode that connects to your a pole to the connection point of the first series circuit between the first capacitor and connected to the flame sensor and arranged in a branch parallel to the first capacitor and which has the same direction of current flow as the flame scanner, and with a Flame relay with an upstream amplifier, the input of which is connected to the connection point of the first series connection characterized in that a second series circuit connected to the alternating voltage from a first Zener diode (16) and a second capacitor (17) is provided that the other pole of the diode (19) to the junction (18) between the first Zener diode (16) and the second capacitor (17) is connected that the first Zener diode (16), the Diode (19) and the flame filler (15) a third series circuit connected to the alternating voltage form and have the same current flow direction in this, and that between the input (10) of the Amplifier (3) and the connection point (13) of the first series circuit a component (12) with a voltage-dependent threshold is arranged. 2. Flame monitor according to claim 1, dadurchgekennzeichnel, that the component (12) with the voltage-dependent threshold value is a Zener diode. 3. Flame monitor according to claim 1, characterized in that the component (12) with the voltage-dependent threshold is a diac.