AT515596A1 - Particle measuring apparatus and method for measuring mass emission and optical absorption of a particle-loaded sample gas - Google Patents

Abstract

For a simple determination of both the optical absorption and the mass emission of a particle-laden gas stream, a particle measuring device is provided, with a first, on a first temperature (T1) tempered measuring section (8), in which a first measuring device (10), preferably a measuring device for the determination of the mass emission, and with a second tempered to a second temperature (T2) measuring section (9) in which a second measuring device (11), preferably an optical absorption measuring device, is arranged the first and the second temperature (T1, T2) are independently adjustable and the first measuring device (10) and / or the second measuring device (11) via an input port (6) by means of a sample gas pump (14), a sample gas is supplied, said Sample gas the first meter (10) with a first sample gas sampling method and the second meter (11) with a second sample gas sampling method is supplied.

Description

Particle measuring apparatus and method for measuring mass emission and optical absorption of a particle-loaded sample gas

The present invention relates to a particle meter and a method for measuring the mass emission and the optical absorption of a particle-loaded sample gas.

The currently used measuring methods for statutory investigations for the particle measurement of exhaust gases of internal combustion engines, such as. Internal combustion engines are generally based on the principle of collecting the particles on or in a filter and measuring or analyzing the filter, or on the principle of direct measurement of the particles, or properties of the particles in a gas stream which are undiluted or diluted can.

In the filter method, the mass of the collected particles can be determined gravimetrically by weighing or it can be determined optical properties of the particles collected on the filter, for example by light extinction, light absorption or light scattering method, at one or more wavelengths or in certain wavelength ranges or even with respect to complete spectral ranges, also under different (room) angle ranges. Generally, the sum of absorption and scattering is considered as extinction. Likewise, in the filtering method, chemical analysis such as composition, nature, chemical activity, toxicity, etc., or thermal analysis, for example, with heating, evaporation, chemical post-reactions, combustion, etc., collected on the filter Particles take place.

In the direct measurement of the particles in a gas stream, optical properties, e.g. the opacity (extinction properties), the absorption (by measuring transmission or reflection properties), the scattered light (light scattering effects by Mie and Rayleigh scattering) or the particle composition are investigated by means of different wavelengths. Likewise, particle properties such as e.g. Particle number, particle distribution, particle diameter, particle composition or particle agglomerate structure (the three-dimensional structure of the particles) are investigated. Likewise, reflection properties can be examined, e.g. by Lidar.

There are a variety of measuring devices and measuring systems are known, which can measure one or more of the above properties quite accurate and detailed. Examples include not CVS (Constant Volume Sampler) systems, particle counter, Partial Flow measuring instruments such as Smart Sampler for measuring the particle emission of vehicles by gravimetric filter measurement, Smoke Meter (measurement of light absorption - without scattered light effects of the deposited particles - of on and in one Filter deposited particles by means of the optical reflection), opacimeter for measuring the light extinction (attenuation of the light by absorption + light scattering) by particles in a measuring cell, measurement in a typical broadband spectral range (eg with NDIR (nondispersive infrared sensor) principle), spectrometer for Measurement of Light Absorption Oversized Spectral Range, Photoacoustic Measurement, Laser Induced Measurement, Electrometers, Flame Ionization Detectors (FID), Corona Discharge Systems, Impactors, Scanning Mobility Particle Sizers (SSPS), and Differential Mobility Analyzers (DDMPS).

Particle measurement is useful with the aim of reducing particulate emissions both as a health policy requirement and as a requirement to minimize the impact of particulate emissions on global warming. However, these two requirements relate to different parameters of particulate emissions that do not correlate directly with each other, so minimizing one property of particulate emission does not necessarily mean that the second property is also minimized at the same time.

For health policy considerations, in particular the minimization of the health risks from respirable particles is sought, which can be achieved by minimizing the mass of the emitted particles and / or by minimizing the number of emitted particles. For the effect of particle emission on global warming, however, the optical absorption of the emitted particles, both in the visible spectral range, as well as in the IR range and possibly also in other spectral ranges, crucial.

On the one hand, the mass emission and the optical absorption are not completely correlated, but on the other hand are not completely independent of each other. The scatter band widths of the resulting correlations between optical absorption and mass emission are in the range of a factor of about + 1-2. The measurement of either the optical absorption or the mass emission alone is therefore not sufficient to be able to reliably conclude on the other size, for example via correlation coefficients. With such a procedure one must therefore accept a considerable unknown measuring error.

While there are meters that can be calibrated on the basis of predetermined conversion factors of a size, e.g. optical absorption, to a different size, e.g. However, these conversion factors are not generally valid, ie for any particle-laden medium, any temperature or pressure range, etc., so that such a conversion is always fraught with errors and thus inaccurate.

However, for the reasons given above, it would be desirable to be able to determine both mass emission and optical absorption safely and accurately. For example, In the case of vessels operating in both national and international waters, there is a need for constraints on both parameters (mass / number of particles emitted and optical absorption) to be complied with. But this also requires a measurement of both parameters. For internal combustion engines and / or vehicles which use fuels with a high proportion of sulfur and / or metallic components / or ash components, the following problems are now additionally made more difficult:

If the particles are to be collected by means of a deposit on filters and then the mass emission by means of a balance is to be measured, undiluted sampling at temperatures greater than 110 ° C is required to ensure measurement artifacts by condensate formation, by formation of salts or acids, etc. on the filter to avoid. Main causes of Artefkatbildungen are that exhaust gases with high SOx and NOx proportions, when diluted with ambient air very sensitive to the formation of sulfuric acid and salts, where the humidity and the temperature of the dilution air, but also the degree of mixing, the dilution ratio, etc. has strong influence on the formation of condensate particles and the formation of salts of sulfuric acid or nitric acid. A method of measurement which still allows gravimetric measurements is, for example, the Method-5 of the USA, where heating of the undiluted sampling gases and the particle filter to 120 (+/- 14) ° C avoids the formation of most artifacts.

Measuring methods for determining the optical absorption but require completely different temperature ranges. For example, in a smokemeter, e.g. Temperatures from 50 ° C to 65 ° C +/- 5 ° C provided. A smokemeter is known to operate according to the filter method, in which the blackening of the filter paper is evaluated by deposited particles by means of a photoelectric measuring head and is output in the form of a blackening number or in the form of a particle concentration in mg / m3. The measurement principle here is based on measurement of the absorption of incident light and on and in the filter paper diffusely scattered light in the reflection mode, so that scattered light effects by the measured and deposited on the filter particles, such as in a measured in transmitted light mode Opazimeter occurrence, the smokemeter not more (relevant) can occur.

In addition, the different measuring methods also make completely different demands on the sampling. For a measurement according to Method-5, e.g. an isokinetic sampling is required, whereas in a smokemeter at constant flow rate or mass flow must be removed. In isokinetic sampling, the sample gas must be withdrawn at the same rate as the particle-laden gas stream, thereby varying the mass flow of the sample gas, while at constant volumetric flow, the sample gas volume withdrawn remains constant, but the flow rate of the sampled sample at the sampling location is strong can differ from the flow rate of the exhaust gas.

The measurement of the optical absorption and the mass emission thus require completely different procedures and different framework conditions. The measurement of these two parameters of a particle-laden gas stream is therefore associated with a high expenditure on equipment.

It is therefore an object of the present invention to provide a device, and an associated method for measuring the mass emission and the optical absorption of a particle-loaded sample gas, with which both the optical absorption and the mass emission of a particle-charged gas stream can be determined in a simple manner.

This object is achieved for a particle measuring instrument with a first temperature-controlled measuring section, in which a first measuring device, preferably a measuring device for determining the mass emission, is arranged, and with a second, temperature-controlled measuring section, in FIG a second measuring device, preferably a measuring device for the determination of the optical absorption, is arranged, wherein the first and the second temperature are independently adjustable and the first measuring device and / or the second measuring device via an input port by means of at least one sample gas pump, a sample gas can be fed in which the sample gas can be fed to the first measuring device with a first sample gas sampling method and to the second measuring device with a second sample gas sampling method. For the method, the mass emission is measured with a first measuring device arranged in a first measuring section, wherein the first measuring section is tempered to a first temperature and sample gas is conveyed by the first measuring device by means of at least one sample gas pump through a first sample gas sampling method and the optical absorption with a second Measured in a second measuring section measuring device, wherein the second measuring section is heated to a second temperature and by means of a sample gas pump sample gas with a second sample gas sampling method by the second measuring device is promoted. This makes it possible in a simple manner to comply with the provisions for the two measurements with respect to the temperature of the measurement and sample gas sampling independently, whereby the two desired parameters of the particle-laden sample gas stream can be determined easily and accurately.

Switching to the various measuring devices can be done very easily if at least one first switching valve is provided in the particle measuring device, which is connected to the input connection of the particle measuring device and to the first measuring device and the second measuring device, wherein with the first switching valve the particle-laden sample gas flow to the first Measuring device or the second measuring device can be switched on and the particle measuring device further at least one sample gas pump is arranged, is sucked with the particle-loaded sample gas according to the first sample gas sampling method by the first meter or according to the second sample gas sampling method by the second meter. This can be measured alternately with a measuring device.

With a second reversing valve arranged upstream of the sample gas pump and connected to the output of the first measuring device and to the output of the second measuring device, the unintentional loading of the measuring device which is currently not in operation can be reliably prevented. In addition, with the second change-over valve, it is also possible to purge a measuring instrument with air or zero gas. In a variant of the invention, the second switching valve is arranged upstream of the at least one sample gas pump and downstream of the first and second measuring device.

A simultaneous measurement with the two measuring devices can be realized if a first sample gas pump and a second sample gas pump are provided in the particle meter, with the first sample gas pump sample gas according to the first sample gas sampling by the first meter and with the second sample gas pump sample gas according to the second sample gas sampling method the second measuring device is absorbable.

In a variant of the method according to the invention, a correction factor between the two measurements is determined from the measurements with the first measuring device and the second measuring device at an operating point of the internal combustion engine. This makes it possible to calculate the other size for this internal combustion engine or this type of internal combustion engine from knowledge of either the mass emission or the optical absorption. With knowledge of the correction factor so the measurement of one size can be sufficient to close with sufficient accuracy to the other size.

In a further variant, a correction factor between the two measurements is determined from measurements with the first measuring device and the second measuring device at different operating points of the internal combustion engine and a correction map is created from the correction factors determined in this way. By measuring various operating points and creating the correction map, at least over an operating range, preferably over the entire operating range, the internal combustion engine can be made a sufficiently accurate conversion of a known size to the respective other size.

The subject invention will be explained in more detail below with reference to Figures 1 to 3, which show by way of example, schematically and not by way of limitation advantageous embodiments of the invention. It shows

1 shows a first advantageous embodiment of a particle measuring device according to the invention,

A second advantageous embodiment of a particle measuring device according to the invention and

3 shows a measuring device according to the invention with two sample gas pumps.

The particle measuring device 1 according to the invention is shown schematically in FIG. 1 in one embodiment. From a particle-laden gas stream, e.g. an exhaust gas flow from the exhaust 3 of an internal combustion engine 2, e.g. an internal combustion engine, 4 particle-laden sample gas is removed by means of a well-known sampling probe and fed to the particle measuring device 1 via a sample gas line 5. For this purpose, the sample gas line 5 is connected to an input connection 6 of the particle measuring device 1. The input connection 6 is connected in the particle measuring device 1 via a line to a first changeover valve 7.

In the particle measuring device 1, a first measuring section 8 and a second measuring section 9 are provided, which are individually and independently tempered to a specific first temperature T1 and second temperature T2. For this purpose, suitable heating devices, indicated by the hatched areas, can be provided in the particle measuring device 1. In the first measuring section 8, a first measuring device 10 and in the second measuring section 9, a second measuring device 11 is arranged, which are consequently held on the prevailing in the measuring sections 8, 9 temperature T1, T2.

The first switching valve 7 is connected with its two output ports 12, 13 via lines in the particle measuring device 1 each with one of the measuring sections 8, 9 and with the input of the measuring device 10, 11 arranged therein. Thus, by switching over the first switching valve 7, the withdrawn particle-laden sample gas stream can be switched to either the first measuring device 10 or the second measuring device 11.

In the particle measuring device 1, at least one sample gas pump 14 is provided, which is connected to the outputs of the two measuring devices 10, 11 in order to suck sample gas through the particle measuring device 1 and thus also through one of the measuring devices 10, 11.

After the two measuring devices 10, 11 can cause different temperatures T1, T2 and also different sample gas sampling methods, a control unit 15 is provided in the particle measuring device 1, which on the one hand ensures the correct temperature control of the measuring section 8, 9 and on the other hand regulates the sample gas pump 14 to those for the respective meter 10, 11 ensure required sample gas withdrawal. The control unit 15 also controls the first switching valve 7 to conduct the sample gas through the desired meter 10, 11.

2, another embodiment of the particle measuring device 1 according to the invention is shown. Here, the first switching valve 7 is arranged in the first measuring section 8 and is thus also held at the temperature T1 prevailing therein. Furthermore, the sample gas line 5 can also be tempered by means of suitable heating elements 22. In this way, a certain temperature of the sample gas can be ensured up to the first measuring device 10 in the first measuring section 8. Too large temperature fluctuations in the sample gas can be so easily avoided. In addition, the sample gas pump 14 may also be arranged in a section 20 of the particle measuring device 1 which is tempered to a third temperature T3, in order to avoid undesired formation of condensation in the sample gas pump 14. For an isokinetic sample gas sampling, a pressure sensor 23 can also be arranged in the exhaust 3 in the region of the sampling. Together with a pressure sensor 24 in the sample gas line 5, the control unit 15, a differential pressure Δρ are supplied, by means of which an isokinetic removal can be controlled. For isokinetic sampling, the differential pressure Δρ must typically be zero. Of course, other methods for isokinetic sampling are known. Thus, e.g. also directly the velocity of the exhaust gas and the sample gas are measured in the sample gas line 5, which must be the same for an isokinetic extraction. Possible methods for isokinetic sampling are described, for example, in the standard ISO 8178-1: 2006.

Upstream of the sample gas pump 14, a second changeover valve 21 may also be provided, either in the tempered section 20 of the mammalian pump 14 or else in one of the measuring sections 8, 9 or at another suitable location of the particle measuring device 1.

In this way sample gas can be selectively guided via one of the measuring devices 10, 11, without loading the respective other measuring device 10, 11 with sample gas. Likewise, a measuring device 10, 11 can also be purposely flushed with it, if e.g. no sample gas line 5 is connected to the inlet port 6, but air is sucked through the particle measuring device 1. Alternatively, one could also supply a defined zero gas for rinsing at the inlet connection 6.

To carry out a measurement with the particle measuring device 1, first the first measuring device 10 is supplied with sample gas via the switching valve 7. For this purpose, the control unit 15 ensures the correct temperature T1 in the first measuring section 8 and by regulating the sample gas pump 14, the correct sample gas sampling method. After the first measurement, the changeover valve 7 is switched over, which now measures with the second measuring device 11. Again, the control unit 15, the correct temperature T2 in the second measuring section 9 and the correct sample gas sampling method by the control of the sample gas pump 14 safely. Of course, the sequence can also be reversed. Moreover, it is also possible to carry out several consecutive measurements with one of the measuring devices 10, 11 before switching to the other measuring devices 10, 11.

The first measuring device 10 is for example a measuring device that determines the mass emission, e.g. a measuring device according to Method-5 of the USA. In the case of a Method-5 measuring instrument, the temperature T1 in the first measuring section is kept at 120 ° C +/- 12 ° C and the sample gas is taken isokinetically. Advantageously, the sample gas line 5 is tempered to this temperature T1 for this purpose. In sulfur-free fuels of the internal combustion engine 2, a temperature T1 of 80 ° C may be sufficient, with CNG (Compressed Natural Gas) as a fuel, at least a temperature T1 of 100 ° C is observed. The particle-loaded filter (indicated by the thick horizontal line) of the method-5 measuring device 10 can then be removed and analyzed, for example by gravimetric measurement of the particles deposited thereon by means of a balance. In this way one obtains very accurate mass emission measurements.

Alternatively, the first meter 10 could also include a meter for measuring dilute particles, such as e.g. a smart sampler, his. For this purpose, a temperature T1 of up to 55 ° C be sufficient, the mass emission is determined gravimetrically again.

The second measuring device 11 is, for example, a known smokemeter for determining the density number (FSN) or a particle concentration as a measure of the optical absorption. For this purpose, the temperature T2 in the second measuring section 9 is preferably maintained at 55 ° C. to 70 ° C. and the sample gas pump 14 regulates to a constant volume flow of the sample gas.

It is also an embodiment of the particle measuring device 1 conceivable in which the optical absorption and the mass emission are measured simultaneously, as shown in Figure 3. For this purpose, two separately controlled sample gas pumps 14-1, 14-2 are provided in the particle measuring device 1, each of the sample gas pumps 14-1, 14-2 being assigned to one of the measuring devices 10, 11. Otherwise, the above applies analogously.

An embodiment of a particle measuring device 1 would also be conceivable in which more than two measuring devices are arranged.

By accurately determining the optical absorption and the mass emission in the particle meter 1, it would now be possible for different operating points of the internal combustion engine 2, e.g. in terms of torque and speed, determine these two quantities. Thus, for this type of internal combustion engine 2, a correlation between the two measurements and also a correction function or a correction map can be determined in order to convert at given operating point from the knowledge of one of the two variables to the other size. The correction function (correction map) can be approximated, for example, by known methods to the values at the measured operating points. With knowledge of this correction function is then sufficient for this type of internal combustion engine 2, the measurement only one of the two sizes in order to determine the other size with good accuracy - at least with better accuracy than previously possible. For this one could e.g. As described below, the usual and required methods and methods for treating the filters for gravimetric particle measurement are not specifically illustrated here, as they are described in detail in the respective regulations (e.g., standards and laws) of the various methods.

It must be carried out for at least one or more representative operating points of the internal combustion engine 2 comparative measurements with both measuring devices 10, 11, so that from a valid correlation relationship between the two measured values can be created. a) Measurement with first measuring instrument 10 (eg Method-5): • Isokinetic sampling via the filter of the measuring instrument 10 (typically a glass fiber paper with or without coatings) • Measurement of the weight of the particles deposited on the filter (possibly including chemical or physical pre- and post-treatments ) in mg • Measurement of the device measured volume flow through the filter in m3 • Measurement of the cross-sectional ratio of sampling probe 4 to the cross-sectional area of the exhaust 3 at the location of the sampling (this may also be known) • Calculation of the measured concentration in mg / m3 • Calculation of the measured Mass emission in mg / MJoul or mg / test, depending on the law or regulation applied. b) Measurement with second measuring instrument 11 (eg a Smoke Meter): • Sample gas sampling with constant volume flow over the filter paper • Measurement of the blackening number (FSN value) and paper blackening PS of the particles deposited on the filter • Measurement of the volume flow via the measuring instrument 11 via the Filter in m3 or cm3 (can also be known) • Calculation of the measured concentration of the measuring instrument 11 in mg / m3, eg by means of the correlation curve between density and concentration stored in measuring device 11

c) Determination of the correction factor K • Calculation of a correction factor of the measured operating point for the gravimetric correlation between the two measuring devices 10, 11, e.g. Correction factor K - (mg / m meter 1 o) / (mQ / lTl meter 1l) • The following applies to this operating point: mg / m3 meter * Correction factor K corresponds to mg / m meter 10 ·

If required, several points of a characteristic map can be measured in this way, and from this a correction map can be created, which also makes it possible to reconstruct measurements of one measuring device 10, 11 by the measurements of the other measuring device 10, 11.

Of course, a similar procedure is also possible for the measurement of the optical absorption coefficient, so that a correction factor or a correction characteristic field can also be determined in this regard.

Claims (7)

1. Particle measuring device with a first, to a first temperature (T1) tempered measuring section (8) in which a first measuring device (10), preferably a measuring device for determining the mass emission, is arranged, and with a second, to a second Temperature (T2) tempered measuring section (9) in which a second measuring device (11), preferably a measuring device for the determination of the optical absorption, is arranged, wherein the first and the second temperature (T1, T2) are independently adjustable and the the first measuring device (10) and / or the second measuring device (11) via an input port (6) by means of at least one sample gas pump (14), a particle-laden sample gas can be supplied, wherein the sample gas to the first measuring device (10) with a first sample gas sampling method and the second measuring device (11) can be supplied with a second sample gas sampling method. 2. Particle measuring apparatus according to claim 1, characterized in that in the particle measuring device (1) at least a first switching valve (7) is provided, with the input terminal (6) of the particle measuring device (1) and with the first measuring device (10) and the second measuring device (11) is connected, wherein with the first switching valve (7) the particle-laden sample gas flow to the first measuring device (10) or the second measuring device (11) is aufschaltbar and with the sample gas pump (14) the particle-laden sample gas according to the first sample gas sampling method by the first Measuring device (10) or according to the second sample gas sampling method by the second measuring device (11) is sucked. 3. Particle meter according to claim 2, characterized in that upstream of the sample gas pump (14), a second changeover valve (21) is arranged, which is connected to the output of the first measuring device (10) and the output of the second measuring device (11). 4. Particle measuring apparatus according to claim 1, characterized in that in the particle measuring device (1) a first sample gas pump (14-1) and a second sample gas pump (14-2) are provided, with the first sample gas pump (14-1) sample gas according to the first Sample gas sampling method by the first measuring device (10) and with the second sample gas pump (14-2) sample gas according to the second sample gas sampling method by the second measuring device (11) is sucked. 5. A method for measuring the mass emission and the optical absorption of a particle-laden sample gas, which is taken from the exhaust gas stream of an internal combustion engine (2), wherein the mass emission with a in a first measuring section (8) arranged first measuring device (10) is measured, the first measuring section (8) is heated to a first temperature (T1) and by means of at least one sample gas pump (14) sample gas with a first sample gas sampling method by the first measuring device (10) is promoted and arranged the optical absorption with a in a second measuring section (9) second measuring device (11) is measured, wherein the second measuring section (9) is heated to a second temperature (T2) and by means of the sample gas pump (14) sample gas with a second sample gas sampling method by the second measuring device (11) is promoted. 6. The method according to claim 5, characterized in that from the measurements with the first measuring device (10) and the second measuring device (11) at an operating point of the internal combustion engine (2) a correction factor (K) between the two measurements is determined. 7. The method according to claim 5, characterized in that from measurements with the first measuring device (10) and the second measuring device (11) at different operating points of the internal combustion engine (2) in each case a correction factor (K) between the two measurements is determined and from the thus determined correction factors (K) a correction map is created.