EP1519038B1 - Laser ignition device for combustion engine - Google Patents

Abstract

The device has a switched pumped solid laser with a light source, and a solid laser crystal enclosed in a resonator (9). A quality switch (4) increases power density, and a focusing device (7) focuses a laser beam into a combustion chamber. The source, resonator, crystal, switch, focusing device, an output mirror and a cooling device (11) that cools the resonator, are integrated into a single unit in a spark plug shaft of an engine.

Description

The invention relates to a laser ignition device for an internal combustion engine, according to the preamble of patent claim 1.

US 6,514,069 B1 discloses a laser ignition device which consists of an ignition laser and an excitation laser having a pump light source. Only the ignition laser is housed in a cylindrical tube, which corresponds to a spark plug well. The excitation laser, however, is spatially separated from the ignition laser and connected to this via optical fiber.

It is further known from the publication XP 002304489, Walter Koechner, "Solid State Laser Engineering", 1992, Sringer-Verlag, Germany, 3 ^rd Edition, ISBN 0-387-53756-2 (page 337, paragraph 6.3.1 - Page 352 ) known to use cooling devices in connection with solid-state lasers to stabilize the temperature. The described and laterally pumped and cooled solid-state lasers are due to their size and complexity but not readily suitable for use as housed in a spark plug shaft laser ignition device for an internal combustion engine.

From US 4,416,226 a laser ignition device for an internal combustion engine is known, wherein the resonator of the laser including photo-optical focusing device is screwed into a cylinder head bore so that the ignition device opens directly into the combustion chamber. The laser ignition device uses the principle of a solid-state laser with a pulsed pump light source. This has the advantage that high pulse energies can be achieved with relatively little expenditure of energy. As a pump light source while a flash lamp is used. To increase the power density, an actively switchable Q-switch is used. In the so-called "Q-switching", the energy is stored during the pumping of the active medium in the laser cavity and released during a very short emission time. This results in an extremely high-energy laser pulse. However, actively switchable Q-switches have the disadvantage that a considerable amount of circuitry is required for the controller, and that they are less well suited for fast pulse sequences. The photo-optical device of the known laser ignition device has three lenses. Together with the active Q-switch and by a flash lamp formed pump light source results in the most serious disadvantage that the device can not be housed entirely in a screwed into a spark plug shaft component. About the required for pumped solid state lasers cooling the laser crystal and the light source of the document no information can be found.

US Pat. No. 6,413,077 B1 describes a laser ignition device in which a plurality of lasers, namely an excitation laser and an ignition laser, are used. By means of a Q-switch, the pulses of the excitation laser and the ignition laser are added up and thus the energy density required for an ignition is provided. This known ignition device has the disadvantage of a very high design effort and requires too much space to be used instead of a spark plug in an internal combustion engine can.

The use of laser ignition instead of spark ignition offers a number of advantages. On the one hand, the relatively freely selectable location of the ignition plasma does not require any material structure which could disturb the combustion process. Furthermore, the choice of the ignition location allows an optimization of the combustion process, possibly also a multiple ignition. The high ignition pressures, such as occur in gas engines, are contrary to the laser ignition, since the required pulse energy decreases at higher pressures. The laser ignition ignites even lean mixtures, resulting in very low NO _x emissions.

From the literature it is known that a focused laser leads to a sufficiently small focus diameter with sufficient intensity to a plasma formation and to a local temperature increase and thus to an ignition of an explosive mixture. For practical gas mixtures, the avalanche effect of free electrons for plasma formation is mainly explained. The effect is then practically independent of the wavelength used.

In US 5,673,550 A, the ignition of fuel droplets under plasma formation within the fuel-air mist is described by means of a laser pulsed via a coherent light source.

The object of the invention is to provide a suitable for practical use in internal combustion engine laser ignition device, which takes up little space and which can be used with little design effort in internal combustion engines.

According to the invention, these objects are achieved by the features of claim 1.

By using a Q-switched, pumped solid state laser high pulse energies can be achieved. The most essential elements are compactly combined in a single component which can be screwed into the spark plug shaft of an internal combustion engine instead of a spark plug. It is also essential efficient cooling by a cooling device having a coolant circuit.

The pump diodes used as a pump light source have the advantage of higher efficiency compared to flash lamps.

The laser diodes are operated pulsed with a pulse energy of a few mJ and about 100-200μs, whereby the power per diode is limited to a few 10W.

High-power laser diodes consist of an array of many single diodes and thus achieve a very high pulse energy. Due to the large emission area and the non-continuous distribution (low quality), the laser beam can only be focused very badly. Due to the long resonator, a much higher beam quality and thus a smaller focus diameter can be achieved with a solid-state laser

The pulsed solid-state laser used for the laser ignition device according to the invention is composed of the four main components pump diode, crystal rod, resonator with Auskoppelspiegel, Q-switch and focusing device. The radiation of the pump diodes stimulates metastable energy levels in the laser crystal and thus stores the energy. Due to a low spontaneous emission, the laser crystal begins to emit light at the laser wavelength (1064nm).

For amplification and coherence of the light, the laser crystal is embedded in an optical resonator whose quality is increased in a pulse-like manner with the Q-switch when the desired power density is reached. This gives the output mirror a short, high laser pulse. It becomes a passive Q-switch used, which on the one hand a high gain, on the other hand allows short energy pulses without complex control.

The geometry of the resonator results from the requirement that the pump diodes must be arranged at the upper end of the spark plug well. To achieve a high quality, the largest possible distance between the laser crystal and the output mirror is necessary. This results in the elongated design, with the head area with laser crystal at one end and the output mirror at the other end of a tube.

At the Auskoppelspiegel includes the existing of a single focus lens focusing device. This allows a very small construction.

Since the wavelength of the pump diodes changes with the temperature of the laser substrate and the laser crystal has only a very narrow absorption line, the pump diodes must be thermally stabilized. Investigations have shown that at least two, preferably three different cooling systems for thermal stabilization of the resonator are advantageous. For at least one cooling system, the temperature-controlled cooling water of the internal combustion engine offers. However, since the pump diodes must be operated at a much lower temperature level than the cooling water temperature, the use of thermoelectric cooling elements (Peltier cooling elements) is required in this case. At least one cooling system therefore has at least one Peltier cooling element. It is provided that for cooling the laser crystal and / or the pump diodes, the resonator has a first inner coolant circuit. The heat of the inner circuit is derived via a heat spreader to at least one Peltier cooling element. It is particularly advantageous if the resonator has at least one outer second coolant circuit for heat removal from the Peltier cooling element. At least one of the cooling systems can also be designed to warm the pump diodes. It is particularly advantageous if, during a cold start, the pump diodes can be heated by the Peltier cooling element to the operating temperature.

In principle, the laser crystal can consist of either ND: YAG (neodymium: YAG) or ND: YVO ₄ (neodymium: vanadate). ND: YAG is widely used, inexpensive and mechanically strong, but has a much narrower absorption line than ND: YVO ₄ . The use of ND: YAG laser crystals thus requires a particularly good cooling device.

A very effective heat removal from the laser crystal is achieved when the laser crystal is surrounded by at least one preferably annular first cooling channel.

In order to enable a very compact design of the ignition device, it is provided in the invention that a plurality of pump diodes are arranged concentrically around the laser crystal, wherein preferably at least three, more preferably at least six pump diodes are arranged uniformly around the laser crystal. The pump diodes are advantageously connected in series. The laser crystal is thus pumped laterally by the pump diodes, that is radially. To increase the pulse energy, several rings of pump diodes can also be arranged concentrically one behind the other around the laser crystal.

As the cooling medium, water can be used at least for the second outer cooling circuit.

Fig. 1

eine erfindungsgemäße Laser-Zündeinrichtung in einer Schrägansicht,

Fig. 2

den Kopfteil der Laser-Zündeinrichtung im Detail in einer Schrägansicht,

Fig. 3

die Laser-Zündeinrichtung in einem Längsschnitt,

Fig. 4

den Kopfteil der Laser-Zündeinrichtung in einer geschnittenen Schrägansicht gemäß der Linie IV-IV in Fig. 1,

Fig. 5

den Fußteil der Laser-Zündeinrichtung in einer geschnittenen Schrägansicht,

Fig. 6

die Laser-Zündeinrichtung schematisch in einem Längsschnitt gemäß der Linie VI-VI in Fig. 7,

Fig. 7

die Laser-Zündeinrichtung in einem Schnitt gemäß der Linie VII-VII in Fig. 6 und

Fig. 8

einen Zylinderkopf mit einer eingebauten Laser-Zündeinrichtung.

The invention will be explained in more detail below with reference to FIGS. Show it

Fig. 1

a laser ignition device according to the invention in an oblique view,

Fig. 2

the head part of the laser ignition device in detail in an oblique view,

Fig. 3

the laser ignition device in a longitudinal section,

Fig. 4

the head part of the laser ignition device in a sectional oblique view along the line IV-IV in Fig. 1,

Fig. 5

the foot part of the laser ignition device in a sectional oblique view,

Fig. 6

the laser ignition device schematically in a longitudinal section along the line VI-VI in Fig. 7,

Fig. 7

the laser ignition device in a section along the line VII-VII in Fig. 6 and

Fig. 8

a cylinder head with a built-in laser ignition device.

The laser ignition device 1 consists of the main components laser crystal 2, pump light source 30, passive Q-switch 4, tube 5, Auskoppelspiegel 6 and focusing 7 with a focus lens 8, and a cooling device 11th

A high efficiency can be achieved if the pump light source 30 is formed by pump diodes 3.

Via the irradiation of the pump diodes 3 (808nm), metastable energy levels in the laser crystal 2 are excited and the energy is thus stored. Due to a low spontaneous emission, the laser crystal 2 emits light at the laser wavelength (1064nm).

For amplification and coherence of the light, the laser crystal 2 is embedded in an optical resonator 9 whose quality is increased in a pulse-like manner with the passive Q-switch 4 when the desired power density is reached. As a result, a short, strong laser pulse 26 is obtained at the outcoupling mirror 6.

Individual pump diodes 3 are connected in series and arranged annularly laterally around the laser crystal 2.

The pump diodes 3 must be operated at relatively low temperature of about 30 ° C due to greatly reduced lifetime at higher operating temperature. In addition, the wavelength of the pump diodes 3 changes with the temperature. Since the rod-shaped laser crystal 2 consisting of neodymium: YAG (ND: YAG) has only a very narrow absorption line, the pump diodes 3 must be thermally stabilized. For this purpose, the cooling device 11 is provided in the head region 10 of the laser ignition device 1.

The cooling device 11 includes three different cooling systems A, B, C. The first cooling system A has annularly distributed around the heat spreader 28 Peltier cooling elements 12. For better heat dissipation further cooling systems B, C with two liquid cooling circuits 13, 14 are provided. The coolant of the cooling circuit 13 flows through the head part 10 substantially in the direction of the axis 1 a of the laser ignition device 1.

The first cooling circuit 13 has the task to thermally stabilize the laser crystal 2 and to transfer its heat loss to the heat spreader 28. The laser crystal 2 is surrounded by at least one first cooling channel 16, which may be formed as an annular channel, as can be seen from Fig.7. Instead of an annular channel, a plurality of first inlet channels 16 may be arranged around the laser crystal 2. Via at least one inlet opening 19a and one distributor ring space 19, the coolant is supplied to the first cooling channel 16, and discharged again via a collecting ring space 20 and outlet openings 20a. The heat loss of the laser crystal 2 is at least partially transmitted when flowing through the annular spaces 19, 20 to the flange plate 17 and the connection plate 23, these in turn transmit the heat by heat conduction to the heat spreader 28th

Optionally, the heat spreader 28 may have axial cooling channels 15, as indicated in Fig. 4 and 6 by dashed lines. The cooling medium enters through the access openings 19a in the Verteilerringraum 19, flows through the first cooling channels 15 of the heat spreader 28 and is passed via the transfer channel 18 in the cooling channel 16. Thereafter, it flows through the collecting ring space 20 and outlet openings 20a to an external pump.

The second cooling circuit 14 has inlet openings 21 in the outer heat exchanger 29, which lead to second cooling channels 24 and on to outlet openings 22. The coolant formed for example by water passes through the inlet openings 21 into the second cooling channels 24, flows through the outer heat exchanger 29 and leaves the laser ignition device 1 again in the region of the outlet openings 22. Cooling elements 12 discharged via the outer heat exchanger 29.

By the three cooling systems A, B, C - namely Peltier cooling elements 12, the first cooling circuit 13 and second cooling circuit 14 - existing cooling device 11, it is possible, as a material for the laser crystal 2, the widely used, inexpensive and mechanically strong neodymium: YAG and to use pump diodes 3 as the pump light source. By the cooling device 11, the pump diodes 3 can be thermally stabilized to about 30 ° C, which has an advantageous effect on their life. On the other hand, it can be achieved by the thermal stabilization that the wavelength of the pump diodes 3 always remains within the narrow absorption line of the laser crystal 2.

The laser crystal 2 is mirrored in the area of the end-side connection plate 23 for the laser wavelength (1064 nm) and antireflective coated on the other end.

The shape of the laser ignition device 1 results from the requirement that it should be mounted instead of a spark plug in the spark plug well 31 of a cylinder head 32 and from the boundary condition that the pump diodes 3 in the head region 10 of the laser ignition device 1 must be arranged. To achieve a high beam quality, the largest possible distance between the laser crystal 2 and the output mirror 6 is necessary. The Auskoppelspiegel 6 is therefore arranged in the foot region 25 of the laser ignition device 1 near the combustion chamber. Shortly after the Auskoppelspiegel 6 is the focusing device 7 with a single focus lens 8, which simultaneously forms the window to the combustion chamber and is designed as a plano-spherical lens. As a material for the focusing lens 8, for example, sapphire is suitable.

The second cooling circuit 14 may be coupled to the existing water cooling of the engine. For the first cooling circuit, higher optical, qualitative and thermal conditions have to be fulfilled, so that a separate coolant is required here.

The pump diodes 3 must be operated at a higher operating temperature at about 30 ° C due to greatly reduced lifetime. The waste heat flow is derived via a heat spreader 28, which consists of copper, to the Peltier cooling elements 12, which transform the heat flow to the temperature level of the engine cooling water and deliver it via the outer heat exchanger 29 thereto.

Since the wavelength of the pump diodes 3 shifts with temperature and the absorption band of the laser crystal 2 is extremely narrow, a fast and accurate temperature control must be provided. The temperature on the cold side should deviate by a maximum of +/- 1.5 ° C from the nominal value. To this To reach the Peltier cooling elements 12 are operated with at least one temperature sensor and a power source in a closed loop.

Via the preferably six pump diodes 3 arranged around the laser crystal 2, light pulses are supplied to the laser crystal 2. Via the irradiation of the pump diodes 3 (808nm), metastable energy levels in the laser crystal 2 are excited and the energy is thus stored. Due to a low spontaneous emission, the laser crystal 2 emits light at the laser wavelength (1064nm). For amplification and coherence of the light, the laser crystal 2 is embedded in an optical resonator 9 whose quality is increased in a pulse-like manner with the passive Q-switch 4 when the desired power density is reached. As a result, a high, short laser pulse 26, which is focused via the focusing lens 8 in a focal point 27, is obtained at the outcoupling mirror 6.

As can be seen from FIG. 8, the laser ignition device 1 can be arranged entirely in the spark plug shaft 31 of a cylinder head 32 of an internal combustion engine. The laser ignition device 1 is thus suitable for use in existing conventional cylinder head concepts for spark-ignition internal combustion engines. In order to minimize contamination of the focusing device, the focusing lens 8 is flush with the cylinder head cover surface 34 toward the combustion chamber 33.

Claims (11)

1. Laser ignition device (1) for an internal combustion engine, comprising a Q-switched, pumped solid-state laser with a pulsed pump-light source (30), a solid laser crystal (2) embedded in a resonator (9), a Q-switch (4) for increasing power density, at least one output mirror (6) and a focussing device (7) which serves to focus the laser ray (26) into a combustion chamber, with the pump-light source (30), the resonator (9) including the laser crystal (2), the Q-switch (4), the output mirror (6) and the focussing device (7) forming an integrated unit, characterized in that the pump-light source (30) consists of pumping diodes, the Q-switch (4) is of the passive type, and that a cooling assembly (11) for cooling the resonator (9) is provided, which has at least one coolant circuit (13, 14), and which is also integrated in said unit, said unit being configured as a single element that may be inserted into the spark plug bore (31) of the internal combustion engine.
2. Ignition device (1) according to claim 1, characterized in that the focussing device (7) has a single focussing lens (8).
3. Ignition device (1) according to claim 1 or 2, characterized in that the cooling assembly (11) comprises at least two, preferably three cooling systems (A,B,C).
4. Ignition device (1) according to any of claims 1 to 3, characterized in that the resonator (9) is furnished with at least one Peltier cooling element (12) for cooling the pumping diodes (3).
5. Ignition device (1) according to any of claims 1 to 4, characterized in that the resonator (9) has a first inner coolant circuit (13) for cooling the laser crystal (2).
6. Ignition device (1) according to claim 4 or 5, characterized in that the resonator (9) has at least one outer, second coolant circuit (14) for draining heat from the Peltier cooling element (12).
7. Ignition device (1) according to any of claims 1 to 6, characterized in that the laser crystal (2) is surrounded by at least one, preferably annular, first cooling channel (16).
8. Ignition device (1) according to any of claims 1 to 7, characterized in that several pumping diodes (3) are placed concentrically around the laser crystal (2).
9. Ignition device (1) according to claim 8, characterized in that at least three, preferably at least six, pumping diodes (3) are placed uniformly around the laser crystal.
10. Ignition device (1) according to any of claims 1 to 9, characterized in that in the cold start situation the pumping diodes (3) can be heated to operating temperature by the Peltier cooling element (12).
11. Ignition device (1) according to any of claims 1 to 10, characterized in that the pumping diodes (3) are connected in series.

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