DE102007060560A1 - Gas engine i.e. mixture-compressing gas-petrol engine, for combustion of gaseous air-fuel mixture, has heating element actively initiating self ignition temperature for igniting gaseous fuel during starting process - Google Patents

Abstract

The engine has an ignition device (2) for igniting a gaseous fuel-air mixture. An arrangement of a heating element (5) is selected with respect to a high pressure gas injection (4) such that gaseous fuel that is supplied by the high pressure gas injection defines a volume (7) within a region of the heating element. The heating element actively initiates a self ignition temperature, in the volume, for igniting the gaseous fuel during starting process so that the gaseous fuel serves again as the ignition device of the gas amount that is supplied to a main combustion chamber.

Description

The The invention relates to a gas engine, in particular a mixture-compressing Gas Otto engine with an ignition device according to the preamble of claim 1.

In gas engines, a gaseous fuel-air mixture is burned, wherein the gaseous fuel-air mixture is ignited by means of at least one ignition device of the gas engine. In known from the prior art gas engines, the ignition device is designed as a spark plug, which protrudes either in an undivided combustion chamber or in a partitioned from a main combustion chamber pre-chamber and ignites the gaseous fuel air mixture in the combustion chamber or in the pre-chamber. For ignition, high ignition energies and ignition temperatures are required, which increase disproportionately with increasing engine power. From the DE 102 17 996 A1 is a self-igniting Gemischverdichtende internal combustion engine, in which the ignition of the gaseous fuel air mixture by means of an ignition device, wherein the ignition energy providing ignition of the ignition directly or directly with the fuel to be ignited fuel mixture or a gaseous atmosphere from the fuel mixture to be ignited in contact , Here high ignition energies are provided by the injection, higher than in so-called spark plug method. According to this prior art, therefore, the ignition source of the ignition device is exposed to corrosive conditions, whereby premature wear of the same can occur. This ultimately results in shortened service lives or shortened service intervals and thus increased costs for a gas engine.

Of these, Based on the present invention, the problem is based a novel gas engine and a novel ignition device to create a gas engine. This problem is going through a gas engine according to claim 1 solved.

This Invention describes a spark-ignited mixture-compacting Internal combustion engine for gaseous fuel with a self-igniting ignition device, ie a gas engine, in particular gas engine, for burning a gaseous Fuel-air mixture, with at least one in a main combustion chamber or in a pre-chamber space projecting ignition device for igniting the gaseous fuel air mixture, wherein the ignition device a Hochdruckgaseinblasung and a Includes heating element with a thermal shield, and the spacing the heater selected by the high-pressure gas injection such is that supplied by means of high-pressure gas injection gaseous fuel in the region of the heating element a volume defines, in which the heating element is active during a startup process a self-ignition temperature for ignition of can provide highly compressed gaseous fuel, so that the highly compressed self-ignited gaseous Fuel in turn as an ignition of the main combustion chamber can serve supplied amount of gas.

Preferably has the gaseous fuel leaving the high-pressure gas injection a pressure that is about 1.5 to 3 times greater than the discharge pressure the thermodynamic process lies.

Prefers happens from 0.2% to 50%, in a particularly advantageous manner 0.5% 1.5% of the total gas intended for operation Fuel highly compressed by means of high-pressure gas injection the ignition device.

Of the preferably between about 0.5% to 1.5% of the total gaseous Fuel highly compressed supplied gaseous Fuel leads to optimal operating values and behavior.

In a first preferred exemplary embodiment, the ignition device is integrated in an antechamber which is divided off from the main combustion chamber and which is connected to the main combustion chamber by at least one blow-over opening. The ratio of the volume of the pre-chamber to the entire cross-section of the blow-over opening is then preferably between 50 and 80 cm ³ per cm ² . The volume of the pre-chamber is then preferably about 0.5 to 5% of the volume of the main combustion chamber at the compression end.

By the inventively predetermined ratio from pre-chamber volume to blow-out cross-section to the main combustion chamber low cycle fluctuations, so that a more advantageous stable Operation of the internal combustion engine adjusts.

To a further advantageous embodiment of the invention the ignition device integrated into the main combustion chamber and while the volume with the ignitable mixture for the ignition initiation of the beam propagation (f (t)) of the highly compressed injected gaseous fuel.

preferred Further developments of the invention will become apparent from the dependent claims and the description below. Embodiments of the Invention are, but are not limited to, below Reference to the drawing explained in more detail below. In the drawing shows:

1 : a highly schematic representation the principle of the gas engine according to the invention, in particular the ignition device according to the invention.

2 a highly schematic representation of a gas engine according to the invention according to a first embodiment of the invention, and

3 a highly schematic representation of a gas engine according to the invention according to a second embodiment of the invention.

1 shows a highly schematic representation of a gas Otto engine, wherein in an unspecified combustion chamber of the gas engine an ignition device ( 2 protruding to ignite a gaseous fuel-air mixture, which has been supplied directly to the combustion chamber. The ignition device ( 2 ) comprises a high-pressure gas injection ( 4 ) and a heating element ( 5 ) with a thermal shield ( 6 ), the spacing of the heating element ( 5 ) from the high-pressure gas injection ( 4 ) is chosen so that the by means of high-pressure gas injection ( 4 ) supplied gaseous fuel in the region of the heating element ( 5 ) a volume ( 7 ), in which the heating element ( 5 ) can actively provide a self-ignition temperature for ignition of the highly compressed gaseous fuel at a startup process.

Ignition is achieved by injecting a small amount of gaseous fuel with high pressure gas ( 4 ) in the vicinity of a hot surface of the heating element ( 5 ) realized. This surface of the heating element ( 5 ) is actively heated during the starting process, after completion of the starting process, this surface acts as a thermal storage, which is heated by the combustion energy. This surface can be used for active and passive heating either in a component ( 5 ) (left illustration of the 1 ), or in the form of two separate components ( 5a . 5b ). The high-pressure gas injection ( 4 ) may include a high pressure injection valve, which is designed analogously to an injector concept of a common rail system.

In the embodiment according to the 2 is the ignition device in one of the main combustion chambers ( 1 ) divided pre-chamber space ( 3 ), which by at least one Überblasöffnung with the main combustion chamber ( 1 ) connected is. The antechamber ( 3 ) is designed so that the ratio of the volume of the antechamber ( 3 ) to the entire cross section of the overflow opening between 50 and 80 cm ³ per cm ² . The volume of the antechamber 3 is about 0.5 to 5% of the volume of the main combustion chamber ( 1 ) designed at compression end.

For self-ignition of the fuel gas, the pressure in the antechamber rises ( 3 ) quickly, so that the partially burned gas through the Überblasöffnungen in the combustion chamber ( 1 ) is blown over there and ignites the fuel gas-air mixture. By the predetermined ratio of the volume of the prechamber ( 3 ) to cross-section of the overflow opening can be an optimal pressure increase in the antechamber ( 3 ) with subsequent intensive blow-out into the main combustion chamber ( 1 ), whereby an advantageous stable ignition of the fuel gas mixture in the main combustion chamber ( 1 ) is achieved.

Even in passive operation, the heating element ( 5 ) as an ignition source, since the energy supplied by the ignition energy of the antechamber the ignition device ( 2 ) keeps to auto-ignition temperature (principle: carrier passive heat storage).

In the embodiment according to the 3 is the ignition device ( 2 ) in a main combustion chamber ( 1 ) integrated. The volume with the ignitable mixture for ignition initiation is determined by the beam propagation (f (t)). The gaseous fuel is injected at a pressure into the volume ( 7 ), which is about 1.5 to 3 times higher than the compression end pressure of the thermodynamic process. In this case, between 0.2 and 50% of the total gaseous fuel used for operation is highly compressed into the volume ( 7 ), but preferably only 0.5 to 1.5% of the total amount of gaseous fuel used for operation. This is due to the high pressure injection ( 4 ) in the vicinity of the heating element ( 5 ) with shielding ( 6 ) is formed by providing the necessary autoignition temperature through the hot surface of the heating element ( 5 ) brought to auto-ignition. The self-ignited fuel gas serves as an ignition device for the direct supply ( 8th ) into the main combustion chamber ( 1 ) supplied main fuel in the form of a gas-air mixture (λ about 2.2) so that the principle of a foreign-fired internal combustion engine is realized here.

In the described embodiments, the high-pressure gas injection ( 4 ) a high pressure injection valve. This gas valve is characterized by a needle seat with a movable needle, which releases a cross section between the needle seat and needle through a switching device, through which an amount of gas is blown, which is determined by the released cross-section and the applied pressure difference. The gas pressure applied to the gas injection valve is about 1.5 to 3 times greater than the compression end pressure of the thermodynamic process.

1

Main combustion chamber

2

ignition device

3

antechamber

4

Hochdruckgaseinblasung

5

heating element

5a, 5b

heating element as separate components

6

thermal shielding

7

volume

8th

supply for the main fuel

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10217996 A1 [0002]

Claims (10)

Gas engine, in particular mixture-compressing gas Otto engine, for burning a gaseous fuel-air mixture, with at least one in a main combustion chamber or in an antechamber projecting ignition device for igniting the gaseous fuel-air mixture, characterized in that the ignition device ( 2 ) a high-pressure gas injection ( 4 ) and a heating element ( 5 ) with a thermal shield ( 6 ), and the arrangement of the heating element ( 5 ) with regard to high-pressure gas injection ( 4 ) is selected such that the by means of high-pressure gas injection ( 4 ) supplied gaseous fuel in the region of the heating element ( 5 ) a volume ( 7 ), in which the heating element ( 5 ) can actively provide an auto-ignition temperature for ignition of the highly compressed gaseous fuel during a starting process, so that the high-compression self-ignited gaseous fuel can in turn be used as ignition device of the main combustion chamber ( 1 ) can serve supplied amount of gas. Gas engine according to claim 1, characterized in that the gaseous fuel when initiating the Hochdruckgaseinblasung ( 4 ) has a pressure of about 1.5 to 3 times the compression end pressure of the thermodynamic process. Gas engine according to claim 2, characterized in that 0.2% to 50% of the total gaseous fuel used for operation is highly compressed by means of high pressure gas injection ( 4 ) the ignition device ( 2 ) happens. Gas engine according to claim 2, characterized in that 0.5% to 1.5% of the total gaseous fuel used for operation high ver seals by means of high-pressure gas injection ( 4 ) the ignition device ( 2 ) happens. Gas engine according to claim 1, characterized in that the high-pressure gas injection ( 4 ) includes a high pressure injection valve. Gas engine according to claim 1, characterized in that the surface of the heating element ( 5 ) in the case of active and passive heating by a component ( 5 ) or as two separate components ( 5a . 5b ) is executed. Gas engine according to claims 1 to 6, characterized in that the ignition device ( 2 ) in one of the main combustion chamber ( 1 ) divided antechamber ( 3 ) is integrated, which by at least one Überblasöffnung with the main combustion chamber 1 connected is. Gas engine according to claim 7, characterized in that the ratio of the volume of the pre-chamber ( 3 ) to the entire cross section of the Überblasöffnung between 50 and 80 cm ³ per cm ² . Gas engine according to claims 7 and 8, characterized in that the volume of the pre-chamber ( 3 ) about 0.5 to 5% of the volume of the main combustion chamber ( 1 ) at the compression end. Gas engine according to claim 1 to 6, characterized in that the ignition device ( 2 ) in the main combustion chamber ( 1 ) and the volume ( 7 ) with the ignitable mixture for ignition initiation is determined by the beam propagation (f (t)) of the highly compressed injected gaseous fuel.