RU2005127960A - METHOD AND ELECTRICAL CIRCUIT FOR GAS FLOW IGNITION - Google Patents

Claims (19)

1. A method of igniting a gas stream, characterized in that by means of an electronic control device, after activating it, for igniting the gas stream, a DC voltage conversion device is activated that converts the DC voltage from the voltage source (10) to a higher voltage, a storage capacitor (C1) and the ignition capacitor (C2) used to prepare the ignition voltage are charged with a higher voltage, the electromagnet (6) of the safe ignition system activates by means of a holding current supplied by a voltage source (10), moreover, by means of a relay (17), the electrical circuit between the electromagnet (6) of the safe ignition system and the thermocouple (4) is interrupted, the storage capacitor (C1) is discharged by a switching element, and a current pulse is produced , which serves to briefly excite the electromagnet (5) to open the valve (2) of the safe ignition system and at the same time actuate the armature (3) of the electromagnet (6) of the safety system passive ignition, and the anchor (3) due to the activated holding current, the electromagnet (6) of the safe ignition system, after being actuated, is held in this position by means of the ignition electrode (9) connected to the ignition capacitor (C2) through the ignition transformer, in a known manner an ignition spark for igniting the escaping gas, repeated ignition processes are carried out, while the ignition capacitor (C2) is again charged, after a charge has occurred, a new ignition spark is produced, after After a specified time, the ignition is terminated, the holding current from the voltage source (10) to the electromagnet (6) of the safe ignition system is interrupted, and by means of the relay (17) the electric circuit between the electromagnet (6) of the safe ignition system and the thermocouple is closed again (4) . 2. The method according to claim 1, characterized in that by means of an electronic control device after activating it to ignite the gas stream, it is checked whether the gas flame is on, and if the information is positive, the ignition process is interrupted. 3. The method according to claim 1, characterized in that the presence of thermal voltage is measured, and in the absence of thermal voltage, repeated ignition processes are carried out, the ignition capacitor (C2) is again charged, after the charge is completed, a repeated ignition spark is produced. on the contrary, with the existing thermal voltage, the ignition is terminated, the holding current is interrupted from the voltage source (10) to the electromagnet (6) of the safe ignition system, and the electrical circuit between the safe ignition system electromagnet (6) and the thermocouple (4) is again closed by relay (17) as soon as the thermoelectric current calculated from the available thermal voltage becomes sufficient to hold the armature (3) on the electromagnet (6) of the safe ignition system. 4. The method according to one of claims 1 to 3, characterized in that the storage capacitor (C1) and the ignition capacitor (C2) are charged in each case by means of a DC voltage converter designed for them. 5. The method according to one of claims 1 to 3, characterized in that a higher AC voltage is produced from the DC voltage coming from the voltage source (10), and instead of the DC voltage converter, an oscillator (11), a storage capacitor are used (C1) is connected to a multistage device connected after the first stage (12) of the first stage (12) and after charging to a predetermined higher DC voltage, the ignition capacitor (C2) is electrically connected to the second stage (13) for many adnogo device is charged to a prescribed higher DC voltage. 6. The method according to claim 5, characterized in that after reaching the specified higher DC voltages, the oscillator (11) is turned off, and at the beginning of repeated ignition processes, it is turned on again. 7. The method according to one of claims 1 to 3, characterized in that the holding current supplied from the voltage source (10) for holding the armature (3) simultaneously flows through the electromagnet (6) of the safe ignition system and relay (17), and that by the time the circuit is closed between the electromagnet (6) of the safe ignition system and the thermocouple (4), an additional current is briefly generated by the relay (17). 8. The method according to one of claims 1 to 3, characterized in that the holding current voltage supplied to the electromagnet (6) of the safe ignition system from the voltage source (10) is converted to a DC voltage in the millivolt range. 9. The method according to claim 3, characterized in that the presence of thermal voltage is measured using an analog amplifier (20). 10. The method according to one of claims 1 to 3, characterized in that, for safety, after a certain period of time, the excitation of the electromagnet (6) of the safe ignition system is forcibly interrupted by means of a voltage source (10) using one or several connected in series and time-controlled devices (18) safety shutdown. 11. The method according to claim 5, characterized in that when following the first ignition process, repeated ignition processes before charging the ignition capacitor (C2), the storage capacitor (C1) is disconnected from the cascade (12). 12. The method according to claim 6, characterized in that when following the first ignition process, repeated ignition processes before charging the ignition capacitor (C2), the storage capacitor (C1) is disconnected from the cascade (12). 13. An electrical circuit for implementing a method of igniting a gas stream, comprising a DC voltage converter connected to a voltage source (10), a storage capacitor (C1) connected to an electromagnet (5) connected to an electromagnet (5) to actuate the valve (2) ) a safe ignition system, and an ignition capacitor (C2), which is connected in a known manner through an ignition transformer to an ignition electrode (9), an electromagnet (6) of a safe ignition system, which by means of a relay (17) connected either to a voltage source (10) or to a thermocouple (4), at least one safety shutdown device (18) installed between the voltage source (10) and the electromagnet (6) of the safe ignition system, element ( 4) to measure the voltage of the thermocouple, and the elements to be controlled are connected to the electronic control device through the ports intended for them. 14. The electric circuit according to claim 13, characterized in that the storage capacitor (C1) has a voltage monitoring and limiting element (14) intended for it, as well as a DC voltage converter for it. 15. The electric circuit according to item 13, wherein the ignition capacitor (C2) has an element (14) for monitoring and limiting voltage, and a DC / DC converter for it. 16. The electric circuit according to claim 14 or 15, characterized in that instead of the DC voltage converter, a self-oscillator (11) is connected to a voltage source (10), a cascade device (12/13) is turned on behind the auto-generator (11), and a cascade device ( 12/13) the element (14) for monitoring and limiting the voltage is installed. 17. The electrical circuit according to 14, characterized in that the oscillator (11) consists of a CMOS circuit (15), which has at least four logic elements formed as “NOT-OR” or “NOT-AND” logic elements or simple inverters, and of which at least one logic element is connected in front of other parallel-connected logic elements, or from several CMOS circuits, a power amplification stage 16 with complementary field-effect transistors, an LC oscillatory circuit (L1 / C1) connected behind it, and RC link serving as ETS phase regulator (19). 18. An electrical circuit according to one of claims 13-15 or 17, characterized in that the element for measuring the voltage of the thermocouple (4) is an analog amplifier (20). 19. The electrical circuit according to p. 18, characterized in that the analog amplifier (20) is an AC voltage amplifier, in front of which is included a synchronous voltage divider.