DE102010033027A1 - Method for measuring concentration of fuel in combustion chamber of internal combustion engine, involves vaporizing fuel so that phase boundary surface is formed between solid or liquid particles in fuel and fuel mixture - Google Patents

Abstract

The method involves injecting liquid or gaseous fuel (K) into combustion chamber (B) and vaporizing the fuel so that a phase boundary surface is formed between the solid or liquid particles (T) in the fuel and fuel mixture. The solid or liquid particles are excited by laser light from one or more directions and scattered light from the particles are imaged with a camera to measure concentration and/or flow rate of fuel.

Description

The present invention relates to a method for laser-optical measurement in an internal combustion engine having the features of patent claim 1.

The invention relates to the use of an optical laser measuring technique for speed and concentration measurement. In order to optimize internal combustion engines with regard to fuel consumption and pollutant emissions, combustion process developments are carried out. For modern combustion process development, it is necessary to obtain detailed knowledge of the internal engine processes in reciprocating engines. A component here is the fuel distribution or the local fuel concentration and also the gas movement that prevails in the combustion chamber to determine. For this purpose, more and more laser-optical measurement techniques are used, which are adapted to the respective measurement tasks.

To determine the flow processes in the combustion chamber of reciprocating engines, laser-optical measuring techniques are used which evaluate the scattered light on small particles. For this purpose, the gas flow particles are added, which have a phase interface to the surrounding medium. As a phase boundary two-dimensional extensions are called, which form between substances of different states of matter, so-called phases, or immiscible liquids. By illuminating the particles by means of a laser, which is realized via an optical access into the combustion chamber, occurs at the phase interface, a scattering of light, which is observed by a camera system. This signal is evaluated differently depending on the measurement technique. On the one hand, a frequency shift relative to the laser frequency of the irradiated light due to the movement of the irradiated particles can be observed, which is a measure of the velocity of the particle, or by observing a change in position of the particles in a known time interval to a flow rate and a flow direction to be led back. Thus, the velocity of the particle is determined and due to the follow-up behavior with respect to the surrounding medium is returned to its flow velocity.

In order to measure the fuel distribution or fuel concentration in the combustion chamber of an internal combustion engine, laser-optical measuring techniques based on fluorescence are used. The fuel itself is excited by laser light for the spontaneous emission of light. To increase the fluorescence of conventional fuel, an additive can be added to the fuel. This addition should not change the properties of the fuel as possible. It is possible to measure the concentration of liquid and gaseous fuels.

The selection of the particles which are supplied for the different measurement techniques is a decisive criterion. For the flow measurement, a phase interface is required at which the laser light can be scattered. For conventional concentration measurement, a fluorescent substance must be provided.

When using gaseous fuel from the outset no particles are available for flow measurement.

Functionally, the liquid fuel in real engine operation forms a phase mixture of liquid fuel droplets and already vaporized gaseous fuel, wherein continuously takes place a phase transition from liquid to gaseous, ie the proportion of vaporized fuel constantly increasing and the proportion of fuel droplets steadily decreases. Therefore, no particles are present in the gaseous phase which may be available for flow measurement beyond the injection and vaporization phase.

However, if, for example, an analysis of the cylinder internal flow and / or the concentration distribution of gaseous or liquid fuel in the combustion chamber of an internal combustion engine by means of a laser-optical measuring method carried out evaluate the scattered light on liquid or solid particles, such as LDA (Laser Doppler Anemometry), PIV (Particle Image Velocimetry) or DGV (Doppler Global Velocimetry), there is the problem that in actual operation of the internal combustion engine, ie oscillating piston, just a vaporization of the fuel takes place or a gaseous fuel is used and consequently no more phase interfaces are available and the selected laser-optical Measuring method, such as DGV, is no longer feasible.

Accordingly, it is an object of the present invention to provide a method which allows an analysis of the cylinder internal flow and / or the concentration of the fuel in the combustion chamber of an internal combustion engine, both during operation of the internal combustion engine and in the model experiments.

• • gasförmiger Kraftstoff mit Feststoffteilchen als Zugabe
• • gasförmiger Kraftstoff mit Flüssigkeitstropfen als Zugabe
• • gasförmiger Kraftstoff mit Flüssigkeitslösung als Zugabe bei der nach Verdampfung Feststoffteilchen ausfallen
• • flüssiger Kraftstoff mit Feststoffteilchen als Zugabe
• • flüssiger Kraftstoff mit Flüssigkeitstropfen als Zugabe (Emulsion)
• • flüssiger Kraftstoff mit Flüssigkeitslösung als Zugabe bei der nach Verdampfung Feststoffe ausfallen

To solve this problem, a method for measuring the concentration and / or flow rate in the combustion chamber of reciprocating engines is proposed according to claim 1. For this purpose, the liquid or gaseous fuel, substances are added, which can be designed as a solid and / or as a liquid. In addition, the liquid as an additive can also be present as a solution in which solid particles precipitate after evaporation of the liquid. So there are always particles available, which are available for a measurement. The following combinations result:

• • gaseous fuel with particulate matter added
• • gaseous fuel with drops of liquid as an additive
• • gaseous fuel with liquid solution as an addition to precipitate after evaporation of solid particles
• • liquid fuel with particulate matter added
• • liquid fuel with liquid drop added (emulsion)
• • liquid fuel with liquid solution added as an additive to precipitate after evaporation solids

When using a gaseous fuel, the added solid particles or liquid drops always have a phase interface to the fuel and to the surrounding gas mixture. When using a liquid fuel, the solid particles always have, in the case of drops of liquid only after the evaporation of the fuel and in the use of the solution after the evaporation of the solvent after the precipitation of the solid particles, a phase interface with respect to the surrounding fuel or gas mixture. The liquid drops may form an emulsion with the liquid fuel, i. H. that the liquids do not mix.

According to the invention thus particles, d. H. Used solids and / or liquids, which have a phase interface with respect to the surrounding gas mixture and have a higher boiling point than the fuel, so that they do not evaporate until the initiation of combustion and thus are available for speed and / or concentration measurement. In particular, the invention provides for the use of particles (solid particles or liquid droplets) whose spatial extent is in the range from 1 to 100 nanometers. Due to the small size of the particles, these can follow the flow of gas and do not pose a risk to the engine in terms of wear.

The illumination of the particles is effected by a light source from at least one direction and the detection of the scattered light is effected by at least one camera.

The flow measurement can thus be carried out in the conventional sense using laser-optical measuring methods. The light scattered at the phase boundary can be evaluated with respect to a frequency shift with respect to the laser light entering the measurement space. The frequency shift occurs due to the movement of the particle relative to the transmitter of the laser light (laser) and relative to the receiver of the laser light (camera). This effect is known as a Doppler effect. Alternatively, the scattered laser light can also be evaluated in terms of a particle track method in which the change in position of a particle in a certain time allows conclusions about the flow velocity.

The concentration measurement is based on a further possibility of evaluating the scattered laser light. The intensity of the scattered light is used. The intensity of the scattered light gives information about the number of particles in a certain area. On the assumption of a homogeneous distribution of the particles in the previously supplied fuel, a concentration of the fuel in the gas mixture can be derived. By comparison measurements with and without doping, the concentration of the fuel droplets can be distinguished from the concentration of doped particles. By measuring without the addition of particles, the distribution of the liquid fuel, with the addition of particles, the liquid and gaseous distribution of the fuel in the combustion chamber determined. From the difference of the results of the two measurements, the distribution of the vaporized fuel can be determined and thus determine the time of evaporation.

Thus, the invention provides a method by which a speed measurement of the cylinder inner flow and a concentration measurement in the combustion chamber of a reciprocating engine are also made possible during operation of the internal combustion engine under hot operating conditions. The result is locally resolved flow and / or concentration fields.

Since the same measurement signal can be used both for speed determination and for concentration measurement, simultaneous measurement of speed and concentration is possible.

Further advantageous embodiments of the present invention will become apparent from the following embodiment and the dependent claims.

embodiment

By way of example, the application of the inventive method is shown here. In the accompanying figures show:

1 : the schematic test arrangement of a laser-optical measuring technique,

2a : The schematic representation of the inventive method during an injection and

2 B : The schematic representation of the inventive method after the completion of an injection.

In 1 is a laser-optical measurement technology shown schematically. Particles of a fluid flow S are added, which are illuminated by a laser light from one or more directions BR. For a flat illumination, the laser light is formed as a light band LB. The light reflected at the phase interface of the particles is observed by one or more cameras from the respective direction KBR. The measurement images recorded by the cameras are evaluated on the one hand with regard to flow velocity and on the other hand with regard to concentration distribution.

In 2a the method according to the invention is shown schematically. It is an injector I, which injects the offset with particles T fuel K into the combustion chamber B, mapped. Furthermore, an inlet valve E and a piston P are shown. During injection, the liquid fuel itself is available for the measurement because it has a phase interface with the surrounding gas.

In 2 B the method according to the invention is shown schematically. The injection is finished and the liquid fuel K has evaporated. There are now only the particles T in the combustion chamber B for a laser-optical measurement available, which are not evaporated with the previously liquid fuel. The particles may be present as liquid droplets or particulates. Furthermore, it is possible for the particles to be present as a crystalline substance (for example sodium chloride) which has been produced from a liquid phase in the fuel by precipitation. The particles are illuminated by the laser light and the reflected light in the viewing direction KBR is recorded by a camera. The resulting image is then further evaluated according to the method described above.

Claims (8)

Method for measuring the concentration and / or the flow velocity in the combustion chamber of reciprocating engines, characterized in that: • solids and / or liquids are added to a fuel, • the added solids and / or liquids have a phase interface to the surrounding gas mixture and / or fuel, the particles are illuminated by a light source from at least one direction, the scattered light is detected by at least one camera. Method according to claim 1, characterized in that the local concentration and / or flow rate of a liquid fuel is measured. A method according to claim 1 to 2, characterized in that the local concentration and / or flow rate of the added solids and / or liquids is measured. A method according to claim 1 to 2, characterized in that the local concentration and / or flow rate of precipitated from the added liquid solution solids is measured. A method according to claim 1 to 4, characterized in that the scattered light is used at the phase interface of the liquid fuel as a measurement signal. A method according to claim 1 to 5, characterized in that the scattered light is used at the phase interface of the added solids and / or liquids as a measurement signal. Method according to claim 1 to 6, characterized in that the same measurement signal can be evaluated both in terms of concentration and in terms of flow velocity and flow direction. Method according to claims 1 to 7, characterized in that the solids and / or liquid drops at the phase boundary surface of the reflected light is evaluated, have a spatial extent in the range of 1 to 100 nanometers

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