WO2018095719A1 - Particle measurement device and method for determining a particle size - Google Patents

Abstract

The present invention relates to the determination of particle properties in an aerosol by means of a transmitted light process. For this purpose, a particle measuring chamber filled with an aerosol is transilluminated by means of two light beams of differing wavelengths. The ratio of intensities of the transmissive portions of the two light beams of differing wavelengths allows a conclusion to be drawn about the properties of the particles in the aerosol.

Description

 description

title

 Particle Measuring Device and Method for Determining a Particle Size The present invention relates to a particle measuring device and a method for determining a particle size of particles in an aerosol.

PRIOR ART Diesel engines are used both in commercial vehicles and in commercial vehicles

 Passenger cars used. For environmental reasons, the pollutant emissions of diesel engines should be minimized. To the

In order to check the functionality of the systems used, regular emission tests are required by law in many countries. These emissions tests include a check of soot and particulate emissions. This is currently done by means of opacimeters. Here, the optical attenuation of a light beam is measured by a filled with the sample gas chamber and the measured value as opacity or

Turbidity coefficient output.

The document DE 10 2005 006 368 AI discloses a device for

Determination of exhaust turbidity of diesel vehicles. For this purpose, an opacimeter is proposed in particular. The device is permanently installed adjacent to the exhaust line of the vehicle.

In the course of further developments in metrology and the current discussion about tightening of limit values, there is also a great interest in additional information about the particles contained in the exhaust gas.

Disclosure of the invention The present invention provides a particle measuring device according to independent claim 1 and a method for determining a particle size according to independent claim 8.

Accordingly, it is provided:

A particle measuring device having a particle measuring chamber, a first light source, a second light source, a light sensor and a

Evaluation. The particle measuring chamber is permeated by an aerosol. The first light source is designed to emit a first light beam having a first wavelength in the direction of the particle measuring chamber. The second light source is designed to emit a second light beam having a second wavelength in the direction of the particle measuring chamber. The first wavelength of the first light beam is different from the second wavelength of the second light beam. The light sensor is designed to transmit the portion of the first light beam transmitted through the particle measurement chamber and the portion of the second component that transmits through the particle measurement chamber

To capture light beam. The light sensor is further configured to be at an intensity of the detected transmitted portion of the first light beam

provide corresponding output signal. Furthermore, the

Light sensor configured to provide a corresponding to an intensity of the detected transmitted portion of the second light beam second output signal. The evaluation device is designed to determine and output a quantity corresponding to a particle size of particles in the aerosol based on the first output signal and the second output signal of the light sensor.

Furthermore, it is provided:

A method for determining a particle size of particles in an aerosol comprising the steps of emitting a first light beam having a first wavelength through an aerosol flowed through

Particle measuring chamber, detecting a first intensity of a through

Particle measuring chamber transmitted portion of the first light beam; of

Emitting a second light beam having a second wavelength through the particle measuring chamber; detecting a second intensity of a through the Particle measuring chamber transmitted portion of the second light beam; and determining an amount corresponding to the particle size of the aerosol based on the detected first intensity and the detected second intensity of the portions of the first and second light beams transmitted through the particle measurement chamber.

Advantages of the invention

The present invention is based on the finding that a

Conventional turbidity measurement of aerosols, such as diesel engine exhaust, provides only limited indication of the characterizing quantities of particles contained in the aerosol. Moreover, further analysis of aerosols for classifying the particles contained therein by conventional methods is relatively complex and therefore requires high costs. The high price and the high maintenance of such conventional devices, as well as the low ruggedness, therefore, currently prevent the use of more complex particle counters in the

Workshop area.

The present invention is therefore based on the idea to take into account this finding and a simple, inexpensive and robust

Particle measurement of aerosols, such as exhaust gases of a

Diesel vehicle to provide. In this case, the present invention is based on the observation that the proportion of the transmitted light varies through a filled with an aerosol particle measuring chamber for different wavelengths of light depending on the variables characterizing the particles. In other words, if a particle measuring chamber is irradiated by light of two wavelengths, the proportion of the transmitted light is different depending on particle size, particle concentration and / or particle mass.

Therefore, from the ratio of the attenuation of the light which radiates through a particle chamber filled with an aerosol, for two different wavelengths to further, the particles of the aerosol

characterizing properties are closed. The variation of the turbidity coefficient of the aerosol filled measuring chamber in Depending on the wavelength of the light which radiates through the measuring chamber, it is thus possible in a simple and cost-effective manner to provide a more detailed statement about the characteristic properties of the particles contained in the aerosol.

According to one embodiment of the particle measuring device, the

Evaluation device a memory device. The storage device is designed to store at least one predetermined characteristic curve for the particle size as a function of a ratio of the first output signal of the light sensor to the second output signal of the light sensor. The

Evaluation device can then be designed to determine the particle size using the stored in the memory device characteristic. By using previously stored characteristic curves which characterize the particle size as a function of a different ratio of the light turbidity through the aerosol in the particle measuring chamber, a value dependent on the particle size of the aerosol can be determined in a simple manner. In addition, a plurality of characteristic curves or even multi-dimensional characteristic curves can be stored in the storage device, which specify a determination of the particle size in addition to the ratio of the detected light intensities also as a function of further parameters.

According to one embodiment, the particle measuring device comprises at least one further sensor which is designed to detect a further operating variable. The evaluation device can be designed to handle the

Particle size using the detected additional environmental size to determine. In particular, the further sensor may for example be a

Pressure sensor, a temperature sensor and / or a volumetric flow sensor for the flowing through the particle measuring chamber aerosol. In this way, a simple and reliable precise determination of the particle size of the particles contained in the aerosol is also variable

Ambient conditions possible.

According to a further embodiment, the first light source and / or the second light source comprises a light-emitting diode (LED). Such light-emitting diodes are usually very well suited to emit monochromatic light of a given wavelength. The light-emitting Diodes on a very good efficiency. In particular, the wavelengths of the light emitted by the first light source and the second light source may be visible light. In addition, at least one of the light sources can emit light in the infrared wavelength range or in the ultraviolet wavelength range. The wavelength of the light beam emitted by the first light source and the light beam emitted by the second light source preferably differ significantly.

By way of example, the first light source can emit light in the blue wavelength range, for example between 400 and 450 nm. The second light source may, for example, emit light in the red wavelength range, for example between 700 and 750 or 800 nm. But it is also possible that at least one light source emits, for example, light in the green wavelength range, for example between 500 and 650 nm.

According to one embodiment, the first light source and the second light source each alternately emit a light beam. The emitted from the first light source and the second light source light beams can be synchronized with a suitable synchronization signal.

In particular, it is thereby possible to respectively synchronize the output signal provided by the light sensor and the light beams emitted by the first light source and the second light source.

According to one embodiment of the method for determining the

Particle size in the aerosol, the method includes a step of introducing a calibrated aerosol into the particle measuring chamber. The calibration aerosol includes, for example, particles of a predetermined particle size. The method comprises a step for detecting a first calibration intensity of a portion of the first light beam transmitted through the particle measurement chamber, and detecting a second calibration intensity of a portion of the second light beam transmitted through the particle measurement chamber. Subsequently, the step of determining the particle size of the particles contained in the aerosol can be carried out using the detected first and second calibration intensities.

According to a further embodiment of the method, the emission of the first light beam and the detection of the first intensity, as well as the emission of the second light beam and the detection of the second intensity are respectively synchronized with each other.

The above embodiments and developments can, as far as appropriate, combine arbitrarily. Further refinements, further developments and implementations of the invention also include combinations of previously or below that are not explicitly mentioned with respect to FIG

Embodiments described features of the invention. In particular, the person skilled in the art will also consider individual aspects as improvements or

Add supplements to the respective basic forms of the invention.

Brief description of the drawings

The present invention will be explained in more detail with reference to the exemplary embodiments indicated in the schematic figures of the drawings.

Showing:

FIG. 1 shows a schematic representation of a particle measuring device according to an embodiment; and

FIG. 2 shows a schematic representation of a flowchart on which a method according to an embodiment is based.

Embodiments of the invention

FIG. 1 shows a schematic representation of a particle measuring device 1 according to an embodiment. The particle measuring device 1 comprises a particle measuring chamber 20 through which an aerosol can flow. The aerosol which flows through the particle measuring chamber 20 may be a gas or gas mixture in which particles are contained.

For example, the aerosol may be the exhaust gases of a vehicle, in particular the exhaust gases of a diesel vehicle. The

Particle measuring chamber 20 may, for example, one or more

Inlet openings 23 and one or more outlet openings 24 include. The embodiment shown here is for illustrative purposes only and is not intended to be limiting of the present invention. The aerosol can are introduced through the inlet opening 23 into the particle measuring chamber 20 and exit through the outlet openings 24 again from the particle measuring chamber 20. Preferably, the particle measuring chamber 20 can be traversed by a constant volume flow of the aerosol.

The particle measuring chamber 20 moreover has at least two

translucent areas 21 and 22 on. The transmissive regions 21 and 22 are preferably arranged on opposite sides of the particle measuring chamber 20.

Furthermore, the particle measuring device 1 comprises a first light source 11 and a second light source 12. The first light source 11 is designed to emit a first light beam having a predetermined first wavelength. The first light beam of the first light source 11 is aligned with the light source 11 in the direction of a first transparent region in the particle measuring chamber 20. In particular, the first light beam at the first

transparent region 21 into the interior of the particle measuring chamber 20 and on the opposite side of the optically transparent second region 22 again emerge from the interior of the particle measuring chamber 20. In this case, the intensity of the first light beam is attenuated by the aerosol contained in the particle measuring chamber 20. Particles contained in the aerosol may partially absorb or scatter the first light beam. Therefore, only a part of the first light beam through the

Particle measuring chamber 20 transmit through and back out of the

Particle measuring chamber 20 emerge. This transmitting portion of the first

Light beam can be detected by a light sensor 30. The light sensor 30 can thereupon correspond to the intensity of the detected portion of the first light beam transmitted through the particle measuring chamber

Provide output signal. For this purpose, the light sensor is on the side of the particle measuring chamber 20 opposite the first light source 11

arranged.

Furthermore, the particle measuring device 1 comprises a second light source 12, which is designed to emit a second light beam. This second one

Light beam has a different wavelength from the first wavelength of the first light beam. Also of the second light source 12th emitted second light beam is, as well as the first light beam, on the

Particle measuring chamber 20 directed enters the particle measuring chamber 20 at the first transparent region 21, and the portion of the second light beam transmitted through the particle measuring chamber 20 then exits the interior of the particle measuring chamber 20 again at the second transparent region 21 and then also strikes the light sensor 30. The light sensor 30 is designed to also detect the portion of the second light beam transmitted through the particle measuring chamber 20 and to provide a second output signal corresponding thereto.

The first light source 11 and the second light source 12 can be arranged in a common housing. In particular, it is also possible for the first light beam and the second light beam to be emitted by a common light source which is designed to emit two light beams with different wavelengths. Optionally, the wavelengths of the first light beam and / or the second light beam of the first light source 11 and / or the second light source 12 can be adjusted or

be adjustable.

For example, the first light source 11 and the second light source 12 may be a light emitting diode (LED) or the like. Here, separate light-emitting diodes are possible for each of the wavelengths which are emitted by the light sources 11, 12. Alternatively, a so-called multicolor LED is possible, this is a single light-emitting diode, which depending on the control light

can emit different wavelengths. In addition, are

Of course, any other light source allows, which are able to emit light of a given wavelength.

For example, as the light source 11 and / or 12, a laser light source or the like may be provided.

The wavelength of the first light beam and the wavelength of the second light beam can both lie in the range of visible light between 400 and 750 or 400 and 800 nm. In addition, the wavelength of the first light beam and / or the wavelength of the second light beam may also be in the infrared light range or in the ultraviolet light range. Preferably, the wavelength of the first light beam and the

Wavelength of the second light beam as far apart as possible. By way of example, the wavelength of the first light beam in the red wavelength range may be between 800 and 700 nm or 800 and 750 nm, and the wavelength of the second light beam in the blue wavelength range between 400 and 450 nm.

In addition, however, any other wavelengths, in particular wavelengths with a significant difference between the first

Wavelength and the second wavelength possible.

The first light beam and the second light beam can be emitted alternately, for example by the respective light sources 11, 12, so that in each case only light of the first wavelength or only light of the second

Wavelength transmitted through the particle measuring chamber 20. The emission of the first light beam and of the second light beam by the first light source or the second light source and the detection of the particles of the light beams transmitted through the particle measurement chamber 20 by the light sensor 30 can be synchronized with each other by means of a suitable synchronization signal. For example, the first light source 11 and the second light source 12 may receive a corresponding drive signal from the evaluation device 40 and then emit the first light beam or the second light beam, respectively. Accordingly, the evaluation device 40, the first output signal corresponding to the detected transmitted first portion of the first light beam and the second output signal of the light sensor, which corresponds to the detected transmitted portion of the second light beam during the time during which the corresponding light source 11 or 12 is controlled. In this way, an unambiguous assignment of the detected output signals from the light sensor 30 to the corresponding wavelengths of the respective light beams can take place. The evaluation device 40 can then the size of the first

 Output signal from the light sensor 30 with the size of the second

Compare output signal from the light sensor 30. Based on the ratio of the size of the first output signal to the size of the second output signal from the light sensor 30, the evaluation device 40 may then be a measure of the particle size in the by the

Particle measuring chamber 20 to determine passing particles of the aerosol. For this purpose, the evaluation device 40 can calculate, for example, the ratio of the first output signal to the second output signal and adjust this calculated ratio with a previously determined characteristic curve. Such a previously determined characteristic can, for example, in a

Memory device of the evaluation device 40 may be stored in the form of a lookup table or the like. For example, a corresponding particle size can be stored in the storage device of the evaluation device 40 for a multiplicity of different ratios. Alternatively, the relationship between the ratio of the output signals from the light sensor 30 and the corresponding particle size may also be referred to as

Calculation rule or the like stored.

Furthermore, it is also possible, before the actual measurement by the

Particle measuring device perform a calibration. For this purpose, an aerosol with particles of a predetermined size and optionally also other predetermined parameters, such as a known concentration of particles and / or a known particle mass in the particle measuring chamber 20 are eigeleitet. Then, in each case the intensity of the transmitting portion of the first light beam and the second light beam can be detected for this calibration aerosol. Based on these detected intensities and the output signals corresponding thereto by the light sensor 30, the measurements can then be taken during measurements of unknown aerosols

Intensities or the ratio of the intensity of the transmitted portion of the first light beam to the transmitted portion of the second light beam are related. From this it can be deduced whether the

Particle properties in the unknown aerosol deviate upwards or downwards from the particle properties of the calibrated aerosol. Further

Of course, calibration options are also possible.

The particle measuring device 1 may additionally comprise one or more further sensors 50 for detecting further operating variables. For example, the particle measuring device 1 may include a pressure sensor, which detects the pressure of the aerosol in the particle measuring chamber 20 and provides the evaluation device 40. Further, the particle measuring device 1 Also include a temperature sensor that detects the temperature of the aerosol in the particle measuring chamber 20, at the inlet openings 23 and / or the outlet opening or openings of the particle measuring chamber 20. Furthermore, the particle measuring device 1 can also comprise a volume flow sensor which detects the volume flow of the aerosol flowing through the particle measuring chamber 20 and has a corresponding size on the aerosol

Evaluation device 40 provides. Further sensors for detecting operating variables of the particle measuring device 1 are also possible.

If further information about one or more further operating variables of the particle measuring device 1 is available from one or more further sensors 50, then this information can also be included in the determination of the particle size. For example, several calibration operations for variations of these further operating variables can be performed. Additionally or alternatively, also for variations of the operating variables several

Characteristics or characteristic fields are stored. In this way, in each case the determination of the particle size in the aerosol can be adapted depending on the current operating variable such as temperature, pressure or volume flow.

As previously described, the evaluation device 40 may infer the particle size of the particles in the aerosol in the particle measurement chamber 20 based on the ratio of the intensity of the transmitted portion of the first light beam to the intensity of the transmitted portion of the second light beam. This particle size is usually an average mean particle size, as the aerosol may also contain particles of different sizes.

Subsequently, on the basis of this determined average particle size of the particles in the aerosol of the particle measuring chamber, an estimate of the particle concentration in the aerosol and an average particle mass of the particles in the aerosol can be made.

The determined data on particle size, particle concentration and / or particle mass can then, for example, at an interface in digital or analogous form. Furthermore, the evaluation device 40 can also display the determined data such as particle size, particle concentration or particle mass on a display device (not shown) or store the data in a further memory for subsequent further processing.

FIG. 2 shows a schematic representation of a flow chart as it is based on a method for determining a particle size of particles in an aerosol according to an embodiment. In step S 1, a first light beam is emitted at a first wavelength, which radiates through a particle chamber through which an aerosol flows. In step S2, a first intensity of a through the particle measuring chamber 20th

detected transmissive portion of the first light beam. In step S3, a second light beam having a second wavelength is emitted. This second light beam also penetrates through the aerosol

Particle measuring chamber 20. In step S4, a second intensity of the portion of the second light beam transmitted through the particle measuring chamber 20 is detected. The emission and detection of the first light beam or of the second light beam can take place, for example, alternately. In particular, the emission of the respective light beam and the detection of the intensity can be synchronized with each other.

In step S5, a particle to the particle size of the particles contained in the aerosol is calculated. The calculation of the particle size is carried out based on the detected intensity of the transmitting portion of the first light beam and the detected intensity of the transmissive through the particle measuring chamber portion of the second light beam. By forming a ratio of the two intensities, it is possible to draw conclusions about the particle size.

In particular, the ratio of the two intensities formed during the measurement can be set to a ratio of the intensities which occurs during a calibration procedure with a calibration aerosol. This

Calibrated aerosol may comprise particles of a known particle size, a known particle concentration and / or a known particle mass. In summary, the present invention relates to the determination of

Particle properties in an aerosol by means of a transmitted light method. For this purpose, a particle filled with an aerosol particle measuring chamber is illuminated with two light beams of different wavelengths. From the ratio of the intensities of the transmissive components of the two light beams with different

Wavelengths can then be made to draw conclusions about the properties of the particles in the aerosol.

Claims

claims

1. Particle measuring device (1), comprising: a particle measuring chamber (20) through which an aerosol can flow; a first light source (11) adapted to receive a first light source (11)

 Light beam having a first wavelength in the direction of

 Send particle measuring chamber (20); a second light source (12) adapted to emit a second light beam having a second wavelength in the direction of

 Send particle measuring chamber (20); a light sensor (30) which is adapted to a through the

 Particle measuring chamber (20) transmitting portion of the first light beam and the second light beam to detect a corresponding to an intensity of the detected transmitted portion of the first light beam to provide a first output signal and an intensity of the detected transmitted portion of the second light beam

 to provide a corresponding second output signal; and an evaluation device (40), which is adapted, based on the first output signal and the second output signal of the light sensor (30) to a particle size of particles in the aerosol

 to determine the corresponding size.

2. particle measuring device (1) according to claim 1, wherein the

 Evaluation device (40) comprises a memory device which is adapted to a predetermined characteristic for the particle size in

Store dependence on a ratio of the first output signal to the second output signal of the light sensor (30), and wherein the evaluation device (40) is designed to determine the particle size using the characteristic stored in the memory device.

Particle measuring device (1) according to claim 1 or 2, with a further sensor (50) which is designed to detect a further operating variable, wherein the evaluation device (40) is adapted to determine the particle size using the detected further operating variable.

Particle measuring device (1) according to claim 3, wherein the further sensor (50) comprises at least one pressure sensor, a temperature sensor and / or a volumetric flow sensor for the aerosol flowing through the particle measuring chamber (20).

Particle measuring device (1) according to one of claims 1 to 4, wherein the evaluation device is further adapted to determine based on the determined particle size, a particle concentration and / or a particle mass of the particle through the measuring chamber (20) flowing aerosol.

Particle measuring device (1) according to one of claims 1 to 5, wherein the first light source (11) and / or the second light source (12) has a

Light emitting diode, LED, or includes a laser.

A particle measuring apparatus (1) according to any one of claims 1 to 6, wherein the first light source (11) and the second light source (12) respectively emit alternately the first light beam and the second light beam.

Method for determining a particle size of particles in an aerosol, comprising the steps of:

Emitting (Sl) a first light beam having a first wavelength through a particle measuring chamber (20) through which the aerosol flows; Detecting (S2) a first intensity of a portion of the first light beam transmitted through the particle measuring chamber (20);

Emitting (S3) a second light beam having a second wavelength through the particle measuring chamber (20);

Detecting (S4) a second intensity of a portion of the second light beam transmitted through the particle measuring chamber (20); and

Determining (S5) a quantity corresponding to the particle size of the aerosol based on the detected first intensity and the detected second intensity of the portions of the first and second light beams transmitted through the particle measuring chamber (20).

Method according to claim 8, comprising the steps:

Introducing a calibrated aerosol having a predetermined particle size into the particle measuring chamber (20);

Detecting a first calibration intensity of a through the

Particle measuring chamber (20) transmitting portion of the first light beam; and

Detecting a second calibration intensity of a through the

Particle measuring chamber (20) transmitting portion of the second

Light beam; wherein determining the particle size of the aerosol is accomplished using the sensed first and second calibration intensities.

The method of claim 8 or 9, wherein the emission of the first light beam and the detection of the first intensity as well as the emission of the second light beam and the detection of the second intensity are respectively synchronized.