RU2000109971A - HIGH FREQUENCY IGNITION SOURCE - Google Patents

Claims (13)

1. The magnetic core-coil assembly and the electronic excitation circuit for generating and supplying high-voltage excitation pulses with a given pulse repetition rate to the surface gap, J gap or altered J gap of the spark plug, to create a spark discharge that ignites gas turbine and diesel engines, different the fact that it includes a core-coil unit, which contains a magnetic core of a ferromagnetic amorphous metal alloy on which the primary winding is wound, rednaznachennaya excitation core-coil low voltage unit, and a secondary winding designed to produce high output voltage; a core-coil assembly, which comprises a magnetic core of a ferromagnetic amorphous metal alloy, on which a primary winding is designed to drive a low-voltage core-coil assembly, and a secondary winding intended to produce a high voltage output voltage, said core-coil assembly comprising a plurality sub-nodes core-coil, to which energy is simultaneously supplied from the specified primary winding of the specified node core-coil, to obtain in their heart the magnetic field in which energy is accumulated, while energy is supplied to the specified core-coil unit from the specified primary winding to obtain a magnetic field in which the energy is stored in its core, wherein said core-coil subunits are connected to the current interruption means in the primary the winding of the specified node of the core-coil, as a result of which, due to the energy stored in the magnetic field, a voltage is induced in the secondary winding formed by the secondary windings of these subnodes, and secondary The windings of the indicated subassemblies are alternately wound counterclockwise and clockwise and connected to each other in series, so that with the indicated interruption of the current, voltages are induced on them, which, after summing, are supplied to the spark plug, while the indicated core-coil unit is connected to the interruption means current in the primary winding, as a result of which, due to the energy stored in the magnetic field, a voltage is induced in the secondary winding, which enters the spark plug, moreover, as the indicated block the core-coil and each sub-core-coil subunit are configured to generate voltage in the secondary winding for a short period of time after its excitation, while both the specified core-coil unit and each core-coil subnode are configured to perform fast charge and discharge cycle, which allows you to work with a pulse repetition rate of more than 500 Hz.  2. The node according to claim 1, characterized in that the core-coil unit and each core-coil subassembly provide a slew rate of 200-500 ns, have an output impedance of approximately 30 to 100 ohms, and provide an open-circuit voltage of approximately 25 kV and give a peak spark discharge current of more than 0.5 A, provide a charge time of approximately less than 150 μs and a discharge time of approximately less than 200 μs, and also provide spark energy of more than 5 mJ per pulse.  3. The node according to claim 1, characterized in that the electronic excitation circuit receives power from a voltage source of at least 5 V and generates pulses with a frequency of at least 500 Hz, and the specified electronic excitation circuit is connected between the output of the core-coil unit or assembly core-coil and surface clearance, J clearance or J-gap of the spark plug, to create a spark discharge for ignition of a gas turbine or diesel engine.  4. The node according to claim 1, characterized in that said magnetic core of a ferromagnetic amorphous metal alloy is subjected to heat treatment.  5. The node according to claim 1, characterized in that its magnetic core is formed by a set of cores.  6. The node according to claim 1, characterized in that the output voltage on the secondary winding reaches 25 kV for 25-150 μs with the number of primary ampere turns less than 70, and reaches 20 kV with the number of primary amperes from 75 to 200.  7. The node according to p. 3, characterized in that the ferromagnetic amorphous metal alloy is an alloy based on iron, which further includes nickel and cobalt, as well as glass-forming elements containing boron and carbon, and, in addition, semiconductor elements, containing silicon.  8. The node according to claim 3, characterized in that the magnetic core does not have a gap.  9. The node according to p. 3, characterized in that the magnetic core has a gap.  10. The node according to p. 7, characterized in that the magnetic core is subjected to heat treatment at a temperature close to the crystallization temperature of the alloy, at which partial crystallization of the alloy occurs.  11. The node according to p. 8, characterized in that the magnetic core is subjected to heat treatment at a temperature below the crystallization temperature of the alloy, so that upon completion of the heat treatment, the alloy remains mainly in an amorphous state.  12. The node according to claim 1, characterized in that it is formed by many individual subnodes, each of which contains a secondary winding wound on a toroid, and these subnodes are connected in such a way that the resulting voltage is the sum of the voltages of the individual subnodes, when all subnodes are excited from the total primary winding.  13. The node according to claim 1, characterized in that it has an internal stepwise voltage distribution from bottom to top, from one sub-node to another.