RU2643880C1 - Laser igniter - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to power machines, specifically to laser spark plugs with an ignition cell, and can be useful in transport and heat power engineering. Solution of this problem was achieved in a laser spark plug containing a housing, a microchip-laser insulator installed in a cavity inside an insulator, connected to it a vacuum tube, optical window, focusing lens, ignition cell with a cylindrical cavity that is converted into a conical, bounded by a conical wall and frontal bottom, washer with a central hole – between the optical window and the ignition cell, several outlets, on the conical wall, that a cylindrical cavity is installed on the inner surface of the cylindrical cavity with a twisting apparatus, and an axial opening is formed on the frontal bottom. Spinning machine can be made with an outer hub. Disc may be formed with an inner surface having a parabolic shape. Laser plug may comprise an additional optical window with a protective cavity between the optical window and an additional optical window. Microchip laser can be installed on a shock absorber. On the insulator, from the side of the inner cavity, a metallized coating may be applied contacting the body. Outlets can be made tangentially.

EFFECT: technical effect: an increase in the service life of the laser spark plug by preventing contamination of the optics and the laser beam outlet.

7 cl, 7 dwg

Description

The invention relates to igniters (spark plugs, in particular laser ones with an integrated prechamber), which are able to significantly improve the efficiency of spreading the ignition flame and the efficiency of burning the air-fuel mixture due to the simultaneous use of a powerful electric field for fuel assembly ignition and heating and activation of the fuel-air mixture. The invention can find application when used in an internal combustion engine - internal combustion engine, both carbureted and injection and diesel, as well as in rotary engines, gas piston and other types of engines and in power plants.

State of the art

Usually, the lateral grounded electrode of the electric spark plug is bent and L-shaped, being perpendicular to the direction of the axial central electrode so that the cross section of the discharge part, the so-called "minicamera", facing the axial central electrode, is rectangular.

When a spark discharge occurs, the spark appears between the axial central electrode and the end discharge part of the grounded electrode located below the axial central electrode. The gas mixture in the spark gap formed by these electrodes is ignited by the spark so that the compressed gas mixture is ignited first in the "minicamera" between the electrodes, and then the horizontally expiring torch ignites the rest of the fuel assembly. In conventional designs, the high gas pressure caused by ignition can be blocked by the end discharge part so that the effect of the propagation of combustion on the air-fuel gas mixture in the combustion chamber is not good enough. And starting the engine at low temperatures generally causes difficulty due to the cooling of the flaming flame from the cold metal parts of the cylinder head.

When the residual carbon (the product of incomplete combustion of the fuel-air mixture - FA) remains in the spark gap between the electrodes, carbon can accumulate and change from the phase of the particles to the phase of the connection on the surfaces of the electrodes so that a short circuit can occur between the electrodes. In this state, even when voltage is applied, a spark may not occur, which leads to serious problems up to stopping the engine or releasing the air-fuel mixture through the exhaust pipe without combustion. When an unburned gas mixture is discharged into the exhaust pipe, a reverse flash effect is often manifested, with an emergency effect and a reduced combustion efficiency. Failure of one of several cylinders can remain unattended for a long time, which will lead to engine failure due to imbalance of rotor parts.

During the operation of the internal combustion engine, a crack may appear at the end of the axial central electrode due to corrosion, which leads to critical damage. Spark plug life may be reduced due to such a defect.

Known electric spark plug according to the patent of the Russian Federation for the invention No. 2366053, IPC Н01Т 13/20, publ. August 27, 2009. This spark plug contains a central electrode and a side electrode of a cylindrical shape, between them a “mini-chamber” is formed. Spark discharge is carried out on a cylindrical wall, and the output of combustion products is carried out in an annular gap.

The disadvantage of this candle is the possible clogging of the annular gap, due to the deposition of solid particles of combustion products on both electrodes, especially when working on an enriched mixture.

Known spark plug according to the patent of the Russian Federation for the invention No. 2366052, IPC Н01Т 13/00, publ. August 27, 2009. This candle contains a central electrode and a L-shaped side electrode, the plane of which is twisted along the length to create a vortex motion of the combustion products.

The disadvantage is poor engine starting at low temperatures.

Known laser spark plug according to the patent of the Russian Federation for the invention No. 22576691, IPC F02P 23/04, publ. 01/26/2015, the prototype

This candle is in a laser spark plug containing a housing, a microchip laser insulator installed in a cavity inside the insulator, an optical window, a focusing lens and a target mounted in a prechamber, into which several outlet openings enter at an angle.

Disadvantages:

- soot deposition on the optics and the hole for the exit of the laser beam of the laser candle,

- the large required laser power with limited dimensions of the laser spark plug, which it is advisable to produce the dimensions as an exact copy of standard electric spark plugs,

- relatively low completeness of fuel combustion in the engine cylinder due to its ignition at one point and, as a result, the emission of harmful substances in exhaust gases.

The objective of the invention, corresponding to the achieved technical result, is to increase the life of the laser candle by preventing contamination of the optics and the outlet of the laser beam.

The technical result is an increase in the service life of the laser spark plugs by preventing contamination of the optics and the exit hole of the laser beam.

The solution to this problem was achieved in a laser spark plug containing a housing, a microchip-laser insulator installed in a cavity inside the insulator, a vacuum tube connected to it, an optical window, a focusing lens, a prechamber with a cylindrical cavity turning into a conical, bounded by a conical wall and end face, a washer with a central hole - between the optical window and the prechamber, several outlet holes, on a conical wall, so that inside the cylindrical cavity is mounted on the inner surface of the cylinder spin-symmetric cavity unit, and an end-bottom an axial hole.

The spin device can be made with an external hub. The washer can be made with an inner surface having a parabolic shape. The laser candle may contain an additional optical window with a protective cavity between the optical window and the additional optical window. A microchip laser can be mounted on a shock absorber. On the insulator from the side of the internal cavity, a metallized coating can be applied in contact with the housing. Outlets can be made tangentially.

The invention is illustrated in the drawings of FIG. 1 ... 7, where

- in FIG. 1 shows a laser spark plug,

- in FIG. 2 shows a prechamber,

- in FIG. 3 shows a section aa,

- in FIG. 4 shows view B,

- in FIG. 5 shows the triangles of speeds,

- in FIG. 6 shows the process of entering the combustion products into the outlet before the implementation of the invention,

- in FIG. 7 shows the process of entry of combustion products into the outlet after the implementation of the invention.

The laser spark plug (Fig. 1) contains a housing 1 (metal), an insulator 2, in the inner cavity 3 of which a microchip laser 4 is installed, an internal high-voltage wire 5 connects it to the terminal tip 6.

The microchip laser 4 is installed in the inner cavity 3 on the shock absorber 7, a vacuum tube 8 is attached to it. The vacuum tube 8 is a metal and ceramic tube inside which a vacuum is created. The vacuum tube 8 is installed along the longitudinal axis of the laser spark plug. At the opposite end 9 of the vacuum tube 8, a focusing lens 10 is fixed.

An optical window 11 and an additional optical window 12 with a protective cavity 13 between them are mounted under the focusing lens 10.

Under the additional optical window 12, a washer 14 is installed with a central hole 15 made in the center of the washer 14 to exit the laser beam 16. The washer 14 has an inner surface 17 made of a parabolic shape.

A prechamber 18 is made under the washer 14, having a cylindrical cavity 19 turning into a conical cavity 20 in the form of a truncated cone. The conical cavity 20 is limited by the end face 21 and the conical wall 22. The cylindrical cavity 19 is limited by the inner cylindrical surface 23. Outlets 24 are made in the conical wall 22 (Figs. 1, 2, 5). The outlet openings 24 may be performed tangentially.

To supply energy to the microchip laser 4 (ground contact), a metallized coating 25 is provided on the inner surface of the insulator 2 and contact 26 on the shock absorber 7 from the inside.

The laser spark plug is screwed into the cylinder head 27 through a thread 28. The cylinder head 27 is connected by a ground wire 29 to ground 30.

On the inner cylindrical surface 23 is installed a spin device 31 having an impeller 32 with an external hub 33 (Figs. 1 and 2).

An axial hole 34 is made on the end face 21.

Foreign particles are shown in pos. 35 in FIG. 2.

In FIG. 2 shows in more detail the prechamber 18.

In FIG. 3 shows a section AA of the spinning apparatus 31.

Outlets 24 can be made tangential (Fig. 4).

In FIG. 5 shows the triangles of speeds before and after the implementation of the proposed technical solution. The designations used in FIG. 4 ... 7:

V ₁ - the rate of combustion products prior to the implementation of the invention,

V ₂ - the rate of combustion products after the implementation of the invention,

V ₀ is the axial component of the velocity of the combustion products,

V _u1 is the peripheral component of the velocity of the combustion products prior to the implementation of the invention,

V _u2 is the peripheral component of the velocity of the combustion products after the implementation of the invention.

In FIG. Figure 6 shows the process of entering the combustion products V ₁ into the outlet 24 before the invention is introduced, it can be seen that the direction of the velocity vector V ₁ and the axis of the outlet 24 do not coincide, which leads to large aerodynamic losses.

In FIG. 7 shows the process of entry of combustion products V ₂ into the outlet 24 after the introduction of the invention, while the velocity vector V ₂ coincides with the axis of the outlet 24.

Device operation

When the laser spark plug, for example, as part of an internal combustion engine - ICE (Fig. 1 ... 7), which includes this spark plug engine, is started with a starter (not shown). After injection of the fuel assembly (air-fuel mixture), part of it through the outlet openings 24 enters the pre-chamber 18. At the time of ignition advance, a distributor (not shown) supplies the potential to the terminal tip 6 and then to the microchip laser 4, which generates laser radiation. Laser radiation through a vacuum tube 8 is transmitted to a focusing lens 10, which creates a laser beam 16. The laser beam 16 passes through the optical windows 11 and 12 and the central hole 15 of the washer 14 and focuses on the focus point F. The FA located in the prechamber 18 is ignited and the front flame in the form of a ball radially goes to the outlet holes 24 and the axial hole 34 and leaves them in the combustion chamber of the engine cylinder (not shown). The inner surface 17 of the parabolic handicap reflects the flame front toward the outlet openings 24. This increases the efficiency of the laser spark plug.

In this case, the swirl apparatus 31 swirls the flow passing through it and discards foreign particles 35 (Fig. 2) to the periphery.

In the intake cycle of the fuel-air mixture - fuel assembly part of it, passing through the spin device 31, cools it.

The use of a swirl apparatus 31 reduces the peripheral component of the velocity of the combustion products in front of the outlet openings 24 and significantly reduces aerodynamic losses on them. This leads to an increase in the power of flammable flames emanating from the outlet openings 24 (FIGS. 6 and 5).

Foreign particles 35 (unburned carbon) are discarded by centrifugal forces to the periphery and the central hole 15 in the washer 14 is not clogged.

Such an organization of the fuel assembly ignition process will provide 100% ignition even in the worst conditions at low temperature and high humidity at low power of the laser microchip 4 (Fig. 1). Also, this approach can be applied on engines operating on cryogenic fuels: hydrogen and liquefied natural gas. To ignite a cryogenic fuel having a very low temperature, it is not necessary to significantly increase the power of the spark plug. This effect will be especially well manifested on high power engines and on engines running on natural gas.

As a result, the application of the invention will allow:

1. To prevent the deposition of foreign parts (soot) on the focusing lens and in the Central hole for the exit of the laser beam and thereby significantly extend the life of the laser spark plug.

2. Reduce the overall dimensions of the laser spark plug to the dimensions of standard electric spark plugs.

3. Reduce the required laser power through the use of a parabolic shape of the inner surface of the washer.

4. Simplify the design of the ignition system by reducing the number of parts when combining a laser spark plug and a prechamber.

7. Reduce fuel consumption due to its more complete combustion, provided more accurate ignition of the fuel assemblies in the combustion chamber of the internal combustion engine with a powerful prechamber torch.

8. Reduce the emission of harmful substances due to more complete combustion of the fuel.

Claims (7)

1. Laser spark plug containing a housing, an insulator microchip - a laser mounted in a cavity inside the insulator, a vacuum tube connected to it, an optical window, a focusing lens, a prechamber with a cylindrical cavity turning into a conical, bounded by a conical wall and end face, a washer with a central a hole - between the optical window and the prechamber, several output holes, on a conical wall, characterized in that inside the cylindrical cavity is installed on the inner surface of the cylindrical cavity of the device twist rat, and an axial hole is made on the end bottom. 2. The laser spark plug according to claim 1, characterized in that the twist apparatus is made with an external hub. 3. The laser spark plug according to claim 1, characterized in that the washer is made with an inner surface having a parabolic shape, 4. The laser spark plug according to claim 1, characterized in that it contains an additional optical window with a protective cavity between the optical window and the additional optical window. 5. The laser spark plug according to claim 1, characterized in that the microchip laser is mounted on a shock absorber. 6. The laser spark plug according to claim 1, characterized in that on the insulator from the side of the inner cavity a metallized coating is applied in contact with the housing. 7. The laser spark plug according to claim 1, characterized in that the outlet openings are made tangentially.

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