EP2504564A1 - Laser spark plug - Google Patents

Abstract

The invention relates to a laser spark plug (100), in particular for an internal combustion engine of a motor vehicle or a large gas engine, having an antechamber (110) for receiving an ignitable medium and a combustion chamber window (140) which separates the antechamber (110) from a part (100a) of the laser spark plug (100) facing away from the combustion chamber. According to the invention, there is at least one current-conducting element (130) in the antechamber (110) arranged such that said element deflects a fluid flow (F) occurring in the antechamber (110) and moving toward the combustion chamber window (140) in a radially inward direction.

Description

 Description title

 Laser spark plug prior art

The invention relates to a laser spark plug, in particular for a

Internal combustion engine of a motor vehicle or a large gas engine, with an antechamber for receiving an ignitable medium and a

Combustion chamber window which separates the antechamber from a combustion chamber facing away from the laser spark plug.

Such a laser spark plug is already known from DE 10 2006 018 973 A1. A disadvantage of the known laser spark plug is the fact that in one of the antechamber facing surface region of the

Combustion chamber window no residual gas cushion from a burnt

Form the air / fuel mixture, or to obtain the protection of the combustion chamber window before the permanent entry of more

Could contribute to combustion products.

Disclosure of the invention

Accordingly, it is an object of the present invention to improve a laser spark plug of the aforementioned type such that the formation or the receipt of a Restgaspolsters is favored in the region of the combustion chamber window.

This object is achieved according to the invention in a laser spark plug of the type mentioned above in that at least one flow-guiding element is provided in the prechamber and arranged so that there is a fluid flow occurring in the prechamber, which towards the combustion chamber window moves, deflects in a radially inner direction. For the purposes of the present invention, the indication of the radially inner direction refers to a

Longitudinal axis or optical axis of the laser spark plug or the antechamber, i. the radially inner direction is substantially perpendicular to the longitudinal axis of the laser spark plug.

According to investigations by the Applicant, the provision of the flow-guiding element according to the invention advantageously results in an effective deflection of the combustion chamber window surface facing the prechamber in the case of conventional laser spark plugs

 Fluid flows, such as those that occur during a compression stroke of an internal combustion engine containing the laser spark plug, in which an ignitable air / fuel mixture flows into the prechamber. The deflection of the fluid flow according to the invention is advantageously carried out such that the fluid flow into a radially inner region of the

Antechamber continues and not one directly in the surface area of the

Brennraumfensters applied volume area. As a result, during the operation of the laser spark plug, a residual gas cushion in this

Form surface area that is not constantly new, out of the

Interrupted inside the antechamber fluid flows is disturbed.

A particularly efficient deflection of the Restgaspolsterbildung disturbing fluid flows is inventively possible in that the

flow-guiding element has a substantially concave flow-guiding surface. Other variants of the invention may also provide flow guiding surfaces, e.g. only partially formed concave, as long as a direct admission of the

Combustor window surface or an adjacent volume region is prevented by the fluid flow.

In a further variant of the invention is a particularly favorable

Fluid flow deflection achieved in that the flow

Surface facing a arranged in the antechamber ignition point, on which the laser spark plug bundles laser radiation, and / or at least one

Overflow, which provides a fluid connection between the antechamber and a Combustion chamber allows. This takes into account the fact that fluid flows in the pre-chamber usually propagate from the ignition point or from the overflow channel.

In a further very advantageous embodiment of the laser spark plug according to the invention, it is provided that the flow-guiding element is arranged directly in the region of the combustion chamber window, whereby an additional mechanical protection of that volume region in the region of

Combustion window results in which the desired Restgaspolster is to train.

Particularly advantageously, the flow-guiding element is designed so that it together with one of the antechamber facing surface of the

Combustion chamber window surrounds a substantially frusto-conical volume range, the base surface is in the region of the combustion chamber window or is formed by a surface of the combustion chamber window. A corresponding cover surface of the truncated cone-shaped volume region in this case represents a passage opening for the laser radiation to the interior of the prechamber. A particularly uniform flow deflection according to the invention is given according to a further variant of the invention in that the

flow-guiding element surrounds an optical axis of the laser spark plug, in particular concentrically.

A particularly stable structure is given according to a further variant of the invention, when the flow-guiding element is formed integrally with a housing of the laser spark plug.

Another very advantageous embodiment of the invention

Laser spark plug is characterized in that at least one

 Overflow channel is provided, which has a fluid connection between the

Prechamber and a combustion chamber allows, and that the overflow is curved. Due to the unique nature of the curvature of the invention

Overflow, in contrast to conventionally designed as a bore overflow, is advantageously a further degree of freedom in the leadership of a

Fluid flow in the interior of the antechamber given, causing the flow-carrying elements according to the invention can be advantageously supported in terms of a desired fluid deflection.

A particularly favorable flow guidance in the region of the overflow channels is given by the fact that a longitudinal axis of a first portion of the

Overflow channel, which opens into an inner region of the prechamber, includes a larger angle with the optical axis of the laser spark plug as a longitudinal axis of a second portion of the overflow channel, which opens into an outer region surrounding the prechamber. The first longitudinal axis of the first section of the overflow channel may well include a right angle with the optical axis of the laser spark plug, while the second longitudinal axis of the second portion of the overflow preferably include an acute angle, in particular an angle <20 °, with the optical axis of the laser spark plug can.

Further advantages, features and details emerge from the

following description, in which with reference to the drawing, various embodiments of the invention are shown. The features mentioned in the claims and in the description may each be essential to the invention individually or in any desired combination.

In the drawing shows:

1 shows a first embodiment of a laser spark plug according to the invention in a partial cross section,

Figure 2 shows a second embodiment of an inventive

 Laser spark plug, and

FIG. 3 shows a third embodiment of a laser spark plug according to the invention.

FIG. 1 shows a partial cross section of a first embodiment of the laser spark plug 100 according to the invention. The laser spark plug 100 has an integrated laser device 105 which can generate laser radiation 20 and focus it on the ignition point ZP lying in a prechamber 110 of the laser spark plug 100. Alternatively, the laser spark plug 100 may also be configured to be supplied with laser radiation from a remote source (not shown) that concentrates it to the ignition point. In this case, the local

Laser device 105 omitted.

The interior of the prechamber 110 is separated from the combustion chamber remote part 100a of the laser spark plug 100 by a combustion chamber window 140.

Furthermore, the laser spark plug 100 or its prechamber 1 10 has over

Overflow 120, the fluid communication between the pre-chamber 1 10 and an outer area 200, in which it is in the installed position of

Laser spark plug 100 can act in an internal combustion engine, for example, to a combustion chamber of the internal combustion engine.

According to the invention, the laser spark plug 100 furthermore has at least one flow-guiding element 130, which in the present case has a substantially rotationally symmetrical design and is arranged in the region of a surface of the combustion chamber window 140 facing the prechamber 110.

Advantageously, the flow-guiding element 130 effects the deflection of a fluid flow F directed onto the combustion chamber window 140 into a radially inner region or a radially inner direction relative to the optical axis OA of the laser spark plug 100. The arrow F 'shown by dashed lines in FIG. 1 shows the deflected according to the invention fluid flow.

Due to the flow deflection from F to F 'according to the invention, a residual gas cushion 150 can advantageously form in the volume region 11, which advantageously protects the surface of the combustion chamber window 140 from dirt particles and other undesirable elements, such as during combustion due to laser ignition in the prechamber 1 10 arise.

The flow-guiding element 130 preferably has a substantially concave flow-guiding surface 130 a, which advantageously corresponds to the Ignition point ZP or an overflow 120 faces, so that an efficient flow deflection is possible in a radially inner region.

Although the flow-guiding element 130 according to the invention need not necessarily be arranged directly adjacent to the combustion chamber window 140, this advantageously results in the formation of a particularly good

flow-protected volume range 1 1 1, the formation and long-term maintenance of a Restgaspolsters 150 allows with high reliability. FIG. 2 shows a further embodiment of the invention

 Laser spark plug 100.

In contrast to the variant of the invention according to FIG. 1, this is

In the present case, flow-guiding element 130 is designed such that, together with the surface of combustion chamber window 140 facing prechamber 110, it surrounds a substantially frusto-conical volume region 11 whose base lies in the region of combustion chamber window 140 or is formed directly through the surface of combustion chamber window 140 is. A cover surface of the frustoconical volume range 1 1 1 still allows - albeit limited - fluid communication of the volume range 1 1 1 with the remaining volume of the prechamber 1 10 and the transmission of the laser radiation 20 to the ignition point ZP.

According to the invention, a particularly uniform flow guidance or deflection of the fluid flow F (FIG. 1) from the combustion chamber window 140 can take place in that the flow-guiding element 130 surrounds an optical axis OA of the laser spark plug 100, in particular concentrically.

The flow-guiding element 130 may preferably also be integrally formed with the housing 101 of the laser spark plug, whereby a mechanically particularly stable configuration is achieved.

FIG. 3 shows a further advantageous embodiment of the laser spark plug 100 according to the invention, in which the lateral transfer passages 120 'are curved. In the present case, a longitudinal axis L1 of a first section of the

Überströmkanals 120 ', which opens into the interior of the pre-chamber 1 10, a larger angle or od with the optical axis OA of the laser spark plug 100 as a second longitudinal axis L2 of a second portion of the

Overflow 120 ', which in a prechamber 1 10 surrounding

 Outside area 200 opens. The angle oc2 between the second longitudinal axis L2 and the optical axis OA is preferably less than about 50 °, more preferably less than about 20 °.

This ensures, on the one hand, when charging the prechamber 110 with an ignitable air / fuel mixture from the outer region 200 or combustion chamber, that the mixture flows directly to the ignition point ZP or at least not directly to the combustion chamber window 140. On the other hand, is advantageous by the inventive arrangement of the second longitudinal axis L2

ensures that from the antechamber 1 10 emerging Zündfackeln that serve to ignite the mixture present in the combustion chamber 200, do not extend purely radially away from the pre-chamber 1 10, but rather at least to a certain extent in the axial direction with respect to the longitudinal axis or optical axis OA of the laser spark plug 100, ie in figure three to the right, spread out.

According to the invention, the shaping of the curved overflow channels 120 'and of the flow-guiding element 130 is coordinated such that an optimized flow deflection is ensured by the volume region 11 (FIG. 2) to be protected, while at the same time ignition torches (not shown) are in a particularly favorable orientation out of the Pre-chamber 1 10 can escape into the combustion chamber 200.

To the formation of the Restgaspolsters 150 (Figure 1) not by the

To affect laser ignition itself, the ignition point ZP is preferably selected so that it is outside the volume range to be protected 1 1 1, in particular in a right in Figure 1 room half of the pre-chamber 1 10th

Claims

claims

1 . Laser spark plug (100), in particular for an internal combustion engine of a motor vehicle or a gas engine, with an antechamber (1 10) for receiving an ignitable medium and a combustion chamber window (140), the prechamber (1 10) of a brennraumabgewandten part (100a) of the laser spark plug (100) separates, characterized in that in the

 Prechamber (1 10) at least one flow-guiding element (130) is provided and arranged so that it in the pre-chamber (1 10) occurring fluid flow (F), which moves to the combustion chamber window (140), in a radially inner direction deflects.

2. laser spark plug (100) according to claim 1, characterized in that the flow-guiding element (130) has a substantially concave

 formed flow-guiding surface (130a).

3. laser spark plug (100) according to claim 2, characterized in that the flow-guiding surface (130 a) in a pre-chamber (1 10) arranged ignition point (ZP) faces, on which the laser spark plug (100) laser radiation (20) bundles, and / or at least one

 Overflow channel (120), which allows a fluid connection between the prechamber (1 10) and a combustion chamber (200).

4. laser spark plug (100) according to any one of the preceding claims, characterized in that the flow-guiding element (130) is arranged directly in the region of the combustion chamber window (140).

5. laser spark plug (100) according to claim 4, characterized in that the flow-guiding element (130) is formed so that it together with one of the prechamber (1 10) facing surface of the combustion chamber window (140) has a substantially frusto-conical volume range (1 1 1), whose base surface lies in the region of the combustion chamber window (140) or is formed by a surface of the combustion chamber window (140).

6. laser spark plug (100) according to any one of the preceding claims, characterized in that the flow-guiding element (130) an optical axis (OA) of the laser spark plug (100), in particular concentrically surrounds.

7. laser spark plug (100) according to any one of the preceding claims, characterized in that the flow-guiding element (130) is integrally formed with a housing (101) of the laser spark plug (100).

8. laser spark plug (100) according to any one of the preceding claims, characterized in that at least one overflow channel (120 ') is provided, which has a fluid connection between the prechamber (1 10) and a

 Combustion chamber (200) allows, and that the overflow channel (120 ') is curved.

9. laser spark plug (100) according to claim 8, characterized in that a longitudinal axis (L1) of a first portion of the overflow channel (120 '), which opens into an inner region of the prechamber (1 10), a larger angle (a1) includes with the optical axis (OA) of the laser spark plug (100) as a longitudinal axis (L2) of a second portion of the overflow channel (120 '), which opens into an outer region (200) surrounding the prechamber (110).