This application claims priority to Japanese Application No. 2017-167975, filed Aug. 31, 2017, and Japanese Application No. 2017-168234, filed Sep. 1, 2017, the disclosures of which are incorporated in their entirety by reference herein.
This invention relates to an exhaust gas analysis device, an exhaust gas analysis method and a storage medium recording programs for an exhaust gas analysis device
As this kind of the exhaust gas analysis device known is, as shown in the patent document 1, an exhaust gas analysis device that samples all amount of the exhaust gas discharged from an internal combustion engine, produces a mixed gas (hereinafter also called as a diluted exhaust gas) as being a mixture of the exhaust gas and a dilution gas such as atmosphere and is used with a constant volume sampling (CVS) mechanism to make a flow rate of the diluted exhaust gas constant.
In accordance with the above-mentioned CVS mechanism, it is possible to reduce a concentration of moisture contained in the mixed gas by diluting the exhaust gas discharged from the internal combustion engine. As this result, dew condensation becomes difficult to occur so that it is possible to restrain a measurement error due to change of the gas concentration resulting from condensation of water or due to melting loss of a water-soluble component.
However, in accordance with the exhaust gas analysis system using the dilution sampling method to dilute the sampled exhaust gas with atmosphere, a concentration value (more concretely, a value obtained by converting a concentration value of the diluted exhaust gas calculated by the exhaust gas analysis device into a concentration value of the exhaust gas prior to dilution) of the component to be measured in the exhaust gas calculated by an exhaust gas analysis device may be lower than a concentration value of the component to be measured in the exhaust gas calculated by a direct sampling method wherein the sampled exhaust gas is not diluted (more specifically, a measurement error occurs).
This kind of a problem may occur also in case that a particle mass or a particle number of a component to be measured is calculated by the use of the exhaust gas analysis system using the dilution sampling method.
Patent document 1: Japanese Unexamined Patent Application Publication No. 2014-174054
The present disclosure intends to solve the problems and a main object of this invention is to provide an exhaust gas analysis device for the exhaust gas analysis system using a dilution sampling method that can calculate the measured value such as the concentration of the component to be measured in the exhaust gas with higher accuracy.
In order to solve the above-mentioned problem, the present claimed inventors focused on a point that the viscosity of a fluid to be measured (more specifically, a diluted exhaust gas) introduced into an analyzing part of the exhaust gas analysis device changes when the exhaust gas is diluted with atmosphere.
The exhaust gas analysis device is usually provided with a fluid resistor part such as a capillary on an introducing path through which the diluted exhaust gas is introduced into the analyzing part so as to limit a flow rate of the diluted exhaust gas that is introduced into the analyzing part where a concentration of a component is measured to a flow rate that is necessary for the measurement. In accordance with the exhaust gas analysis system using the dilution sampling method, a component whose viscosity is high such as oxygen contained in the atmosphere is mixed with the exhaust gas by diluting the exhaust gas with atmosphere and the viscosity of the diluted exhaust gas becomes higher than the viscosity of the fluid (namely, the exhaust gas) prior to dilution.
As a result of intensive studies by the inventors, the inventors found that the influence of a rise in the viscosity of the diluted exhaust gas on the measurement result of the analyzing part becomes remarkable in case that the diluted exhaust gas passes the fluid resistor part of the introducing path, and this becomes a cause of the measurement error for the analyzing part. More specifically, the inventors found that the fluid resistance that the diluted exhaust gas receives from the fluid resistor part such as the capillary increases and the flow rate of the diluted exhaust gas that is introduced into the analyzing part decreases when the viscosity of the diluted exhaust gas becomes higher so that the sensitivity of the analyzing part decreases, resulting in decrease of the measured value of the component to be measured. For example, although the measured value of the component to be measured in the diluted exhaust gas relative to the previously determined introducing amount is previously corrected in the analyzing part, there is a gap between the calculated measured value and the actual value because the introducing amount of the diluted exhaust gas changes.
As a result of further intensive studies by the inventors, the inventors found that there is a correlation between the variation of the measured value measured in the analyzing part and the viscosity of the diluted exhaust gas, and furthermore there is a correlation between the viscosity of the diluted exhaust gas and a concentration of a viscous component such as oxygen contained in the diluted exhaust gas. Then the inventors found that if the concentration of the viscous component in the diluted exhaust gas is grasped, an influence of the increased viscosity of the diluted exhaust gas on the measurement by the analyzing part, namely a drop amount of the measured value measured by the analyzing part can be calculated so that it is possible to correct the measured value of the component measured by the analyzing part. This led to the exhaust gas analysis device of this invention.
More specifically, the exhaust gas analysis device in accordance with this invention is an exhaust gas analysis device that analyzes a diluted exhaust gas as being a mixture of an exhaust gas and a dilution gas that dilutes the exhaust gas, and is characterized by comprising an analyzing part that measures a component to be measured in the diluted exhaust gas, an introducing path that introduces the diluted exhaust gas into the analyzing part and that has a resistance part as being a flow resistance of the diluted exhaust gas, a viscous component concentration determining part that determines a concentration of a viscous component that is in the diluted exhaust gas and that is different from the component to be measured, and a correction part that corrects the measured value measured by the analyzing part in accordance with the concentration of the viscous component determined by the viscous component concentration determining part.
In accordance with this arrangement, since the measured value of the component measured by the analyzing part is corrected in accordance with the concentration of the viscosity component that is different from a viscosity of the component to be measured contained in the diluted exhaust gas as being a fluid to be measured, it is possible to calculate the measured value of the component to be measured in the exhaust gas with high accuracy. More specifically, it is possible to reduce an influence generated by the change of the viscosity by diluting the exhaust gas on the measured value by correcting the measured value measured by the analyzing part in accordance with the concentration of the viscosity component.
The above-mentioned viscosity component (hereinafter just described as “viscosity component”) that is different from the component to be measured in the diluted exhaust gas is concretely the component whose viscosity is higher than the viscosity of the component to be measured.
The influence on the measured value measured by the analyzing part appears conspicuously if the viscous component having a viscosity higher than that of the component to be measured is contained in the diluted exhaust gas. As a result of this, it is possible to reduce an influence on the measured value by the change of the viscosity due to dilution of the exhaust gas by correcting the measured value by the use of the concentration of the viscous component whose viscosity is higher than that of the component to be measured among viscous components contained in the diluted exhaust gas.
It is preferable that the viscous component is oxygen.
In case that atmosphere is used as the dilution gas, the viscous component whose viscosity is the highest contained in the dilution gas is oxygen. As a result of this, the influence on the measured value measured by the analyzing part resulting from mixture of oxygen is the biggest. Then it is possible to effectively reduce the influence on the measured value by the change of the viscosity due to dilution of the exhaust gas by correcting the measured value by the use of the concentration of oxygen in the diluted exhaust gas so that it is possible to calculate the measured value such as the concentration of the component to be measured in the exhaust gas with higher accuracy.
As an object to be measured by the analyzing part represented is a concentration, a mass or a particle number of the component to be measured. In this case, the correction part corrects either of the measured values of the concentration, the mass (particle mass) and the particle number of the component measured by the analyzing part.
It is preferable that the viscous component concentration determining part calculates the concentration of the viscous component in the diluted exhaust gas based on the concentration of the viscous component in the dilution gas and the dilution ratio of the diluted exhaust gas.
In accordance with this arrangement, since there is no need of providing the exhaust gas analysis device with a sensor such as a concentration meter to measure the concentration of the viscous component in the diluted exhaust gas, it is possible to reduce an initial installation cost and a maintenance cost of the concentration meter, resulting in contributing to cost reduction.
The dilution ratio that is used for calculating the concentration of the viscous component in the diluted exhaust gas may be calculated based on a ratio of a theoretical CO2 concentration in the exhaust gas discharged from an internal combustion engine to a total concentration of measured carbon components in the diluted exhaust gas.
The theoretical CO2 concentration is a CO2 concentration calculated assuming that a fuel burns in the theoretical air fuel ratio and is determined by an average composition of the fuel. The total concentration of the carbon components in the diluted exhaust gas is a total concentration of the components such as CO2 produced due to complete combustion, CO produced due to incomplete combustion and/or THC.
In accordance with this arrangement, since the theoretical CO2 concentration is previously determined based on the composition of the fuel, it is possible to calculate the dilution ratio only based on the measurement of the concentration of carbon components such CO2, CO and/or THC in the diluted exhaust gas.
It is preferable that a part or all of the diluted exhaust gas is housed in a gas sampling bag that can house a gas, and the viscous component concentration determining part calculates the dilution ratio by the use of the total concentration of the carbon components in the diluted exhaust gas housed in the gas sampling bag.
Since the diluted exhaust gas housed in the gas sampling bag is in a state wherein the exhaust gas and the dilution gas are fully mixed, the concentration of each carbon component in the diluted exhaust gas is averaged. Then it is possible to calculate the dilution ratio more accurately by using the averaged concentration of each carbon component so that the concentration of the viscous component in the diluted exhaust gas can be calculated with higher accuracy. As a result of this, it is possible to calculate the measured value such as the concentration of the component to be measured in the exhaust gas with higher accuracy.
The dilution ratio of the diluted exhaust gas used for calculation of the concentration of the viscous component in the diluted exhaust gas may be calculated based on a ratio of a flow rate of the diluted exhaust gas to a flow rate of the exhaust gas.
The exhaust gas analysis device in accordance with this invention may further comprise a concentration sensor to measure the concentration of the viscous component and the viscous component determining part may obtain a concentration measured by the concentration sensor.
In addition, an exhaust gas analysis method in accordance with this invention is an exhaust gas analysis method to analyze a diluted exhaust gas as being a mixture of an exhaust gas and a dilution gas that dilutes the exhaust gas, and is characterized by comprising an analyzing step to measure a component to be measured in the diluted exhaust gas introduced through an introducing path having a flow resistance, a viscous component concentration determining step to determine a concentration of a viscous component that is in the diluted exhaust gas and that is different from the component to be measured, and a correction step to correct a measured value measured in the analyzing step in accordance with the concentration of the viscous component determined by the viscous component concentration determining step.
In addition, programs for exhaust gas analysis device stored in a storage medium in accordance with this invention are programs that analyze a diluted exhaust gas as being a mixture of an exhaust gas and a dilution gas that dilutes the exhaust gas, and are characterized by providing a computer with a function as an analyzing part that measures a component to be measured in the diluted exhaust gas introduced through an introducing path having a flow resistance, a function as a viscous component concentration determining part that determines a concentration of a viscous component that is in the diluted exhaust gas and that is different from the component to be measured, and a function as a correction part that corrects the measured value measured in the analyzing part in accordance with the concentration of the viscous component determined by the viscous component concentration determining part.
In accordance with the exhaust gas analysis method or the storage medium that stores programs for the exhaust gas analysis device, the same effect can be produced as that of the above-mentioned exhaust gas analysis device.
In accordance with the embodiments of the present invention, for the exhaust gas analysis system using a dilution sampling method it becomes possible to provide the exhaust gas analysis device that can calculate the measured value such as the concentration of the component to be measured in the exhaust gas with higher accuracy.
One embodiment of an exhaust gas analysis system comprising an exhaust gas analysis device in accordance with this invention will be explained with reference to drawings.
The exhaust gas analysis system 100 of this embodiment is used for measuring a concentration of a component to be measured in an exhaust gas discharged from an internal combustion engine such as, for example, an engine.
Concretely, as shown in
The CVS device 1 comprises, as shown in
The flow rate control part 12 is a critical flow rate venturi system comprises, as shown in
The above-mentioned CVS device 1 houses a part of the diluted exhaust gas in the diluted exhaust gas sampling bag (M) through the diluted exhaust gas sampling flow channel (SL) in a state wherein a total flow rate of the exhaust gas and the dilution gas, namely the flow rate of the diluted exhaust gas is constant.
The diluted exhaust gas housed in the diluted exhaust gas sampling bag (M) is supplied to the exhaust gas analysis device 2 and the concentration of the component to be measured in the exhaust gas is calculated by the exhaust gas analysis device 2.
The exhaust gas analysis device 2 comprises, as shown in
In this embodiment, the component to be measured is NOx (NO and NO2) and the viscous component that is different from the component to be measured contained in the diluted exhaust gas is oxygen (O2).
The analyzing part 21 measures the concentration of NOx as being the component to be measured contained in the diluted exhaust gas, and concretely is a CLD type NOx meter.
The CLD type NOx meter 21 can measure an amount (a concentration) of NOx in the diluted exhaust gas, and comprises, as shown in
The introducing path 21 introduces the measurement objective gas housed in the diluted exhaust gas sampling bag (M) into the analyzing part 21. A fluid resistor part 22a to be a flow resistance of the diluted exhaust gas is arranged in the introducing path 22, and the fluid resistor part 22a limits the flow rate of the diluted exhaust gas that is introduced into the analyzing part 21 to a flow rate that is necessary for measuring the concentration of NOx. As the fluid resistor part 22a represented is a flow control member such as a capillary or an orifice that controls the flow rate by lessening the flow channel area in the introducing path 22.
The arithmetic unit 23 is an electric circuit comprising, for example, a CPU, a memory and an AD converter. In addition, the arithmetic unit 23 produces functions as a viscous component concentration determining part 231, a memory part 232 and a correction part 233 by cooperatively working the CPU and its peripheral devices based on the programs stored in the memory.
Each part will be explained in detail.
The viscous component concentration determining part 231 calculates an oxygen concentration ([O2]sam) in the diluted exhaust gas.
The oxygen concentration determining part 231 calculates the oxygen concentration ([O2]sam) in the diluted exhaust gas based on the oxygen concentration ([O2]amb) in the dilution gas and a dilution ratio (DF) of the diluted exhaust gas. More concretely, the oxygen concentration in the diluted exhaust gas is determined in accordance with the following expression (1). 20.95% as being the oxygen concentration in the atmosphere may be used as the oxygen concentration ([O2]amb) in the dilution gas, or the oxygen concentration in the atmosphere may be directly measured and the obtained oxygen concentration may be used.
A principle to determine the oxygen concentration ([O2]sam) in the diluted exhaust gas by the above-mentioned expression (1) will be explained. Since the exhaust gas analysis system 100 in this embodiment samples and dilutes a total amount of the exhaust gas, the oxygen amount contained in the diluted exhaust gas equals to the sum of the oxygen amount contained in the exhaust gas and the oxygen amount contained in the dilution gas. More specifically, the product of the oxygen concentration ([O2]sam) in the diluted exhaust gas and an integrated value (Vmix) of the diluted exhaust gas flow rate equals to the sum of the product of the oxygen concentration ([O2]ex) in the dilution gas and an integrated value (Vex) of the exhaust gas flow rate and the product of the oxygen concentration ([O2]amb) in the dilution gas and the integrated value (Vamb) of the dilution gas flow rate so that the following expression (2) becomes true.
[O2]samVmix=[O2]exVex+[O2]ambVamb (2)
If the above-mentioned expression (2) is further converted, the following expression (3) will be introduced.
Since the oxygen concentration ([O2]ex) in the exhaust gas is extremely small compared with the oxygen concentration ([O2]amb) in the dilution gas, the product of the oxygen concentration ([O2]ex) in the exhaust gas and the integrated value (Vex) of the exhaust gas flow rate becomes small in such a degree that can be ignored compared with the product of the oxygen concentration ([O2]amb) in the dilution gas and the integrated value (Vamb) of the dilution gas flow rate (more specifically, [O2]exVex<<[O2]ambVamb). Then, the above-mentioned expression (3) can be further converted as follows.
As mentioned above, the above-mentioned expression (1) to determine the oxygen concentration ([O2]sam) in the diluted exhaust gas is developed.
In case of determining the oxygen concentration in the diluted exhaust gas by the use of the above-mentioned expression (1), similar to the following expression (4), the oxygen concentration determining part 231 calculates the dilution ratio (DF) as a ratio of the theoretical CO2 concentration ([CO2]ideal) in the exhaust gas to the total concentration ([CO2]sam)+[CO]sam+[THC]sam) of the carbon components (CO2, CO, THC) in the diluted exhaust gas.
The theoretical CO2 concentration is a CO2 concentration that is calculated assuming that the fuel that burns in an internal combustion engine burns in the theoretical air fuel ratio. More specifically, in case that the fuel whose average composition is CxHyOz burns in the theoretical air fuel ratio, the reaction in accordance with the following reaction formula (a) occurs.
Accordingly, the theoretical CO2 concentration ([CO2]ideal) can be calculated by the following expression (5).
where, HCR is a ratio (y/x) of a hydrogen atom number to a carbon atom number in one mole of fuel, OCR is a ratio (z/x) of an oxygen atom number to a carbon atom number in one mole of fuel, and βOs2 is a mole ratio (about 3.774) between the inert gas and oxygen in dry air. Since both of HCR and OCR are determined based on the average composition of the fuel, the theoretical CO2 concentration is a value previously determined according to the fuel.
The exhaust gas analysis device 2 in this embodiment comprises a CO2 meter, a CO meter and a THC meter (not shown in drawings) each of which measures the CO2 concentration, the CO concentration and the THC concentration in the diluted exhaust gas in the diluted exhaust gas sampling bag (M) respectively. The viscous component concentration determining part 231 obtains the values measured by the above-mentioned CO2 meter, the CO meter and the THC meter, and calculates the dilution ratio (DF) by the use of these measured values.
The memory part 232 is formed in a predetermined area of the memory, and stores NOx concentration correction data as being data associating the oxygen concentration ([O2]sam) in the diluted exhaust gas and a lowering rate of the NOx concentration measured by the analyzing part 21.
The correction part 233 corrects the concentration value of the NOx measured by the analyzing part 21 based on the oxygen concentration in the diluted exhaust gas determined by the viscous component concentration determining part 231 and the NOx concentration correction data stored in the analyzing part 21, and calculates the NOx concentration in the exhaust gas based on the corrected concentration value of NOx. More concretely, the correction part 233 refers the NOx concentration correction data stored in the memory part 232 and determines the correction value (or the correction ratio) relative to the concentration value of NOx measured by the analyzing part 21. The NOx concentration value measured by the analyzing part 21 is corrected based on the determined correction value (or the correction ratio). Then the NOx concentration in the exhaust gas is calculated based on the corrected NOx concentration.
In accordance with the exhaust gas analysis device 2 of this embodiment having the above-mentioned arrangement, since the concentration value of NOx measured by the analyzing part 21 is corrected based on the oxygen concentration in the diluted exhaust gas, it is possible to calculate the concentration of NOx in the exhaust gas with high accuracy. More specifically, it is possible to reduce an influence on the concentration value of NOx by the change of the viscosity due to dilution of the exhaust gas by correcting the concentration value of NOx measured by the analyzing part 2 in accordance with the concentration of oxygen.
In addition, since the measured value by the analyzing part 21 is corrected based on the concentration of the oxygen among the viscous component contained in the diluted exhaust gas, it is possible to further reduce an influence on the concentration value of NOx due to the change of the viscosity resulting from diluting the exhaust gas so that the concentration of NOx in the exhaust gas can be calculated with higher accuracy.
In addition, since the viscous component concentration determining part 231 calculates the oxygen concentration in the diluted exhaust gas based on the oxygen concentration in the dilution gas and the dilution ratio (DF) of the diluted exhaust gas, there is no need of providing the exhaust gas analysis device 2 with a sensor such as an oxygen concentration meter to measure the oxygen concentration in the diluted exhaust gas. As a result of this, it is possible to reduce an initial installation cost or a maintenance cost of the concentration meter, resulting in contributing to cost reduction.
Furthermore, since the viscous component concentration determining part 231 calculates the dilution ratio (DF) by the use of the total concentration of the carbon components in the diluted exhaust gas housed in the diluted exhaust gas sampling bag (M), it is possible to calculate the dilution ratio (DF) with higher accuracy by the use of the concentration of each carbon component which is fully averaged. Accordingly, it is possible to calculate the oxygen concentration in the diluted exhaust gas more accurately. As this result, it is possible to calculate the NOx concentration in the exhaust gas with high accuracy.
In case that the NOx concentration value measured by the CLD type NOx meter is not corrected in accordance with the oxygen concentration, a measurement error of the NOx concentration value in the exhaust gas becomes large as the oxygen concentration in the diluted exhaust gas increases. In case that the oxygen concentration in the diluted exhaust gas is 20%, about 3% error generates in the obtained NOx concentration value in the exhaust gas.
Meanwhile, in case that the NOx concentration value measured by the CLD type NOx meter by the use of the exhaust gas analysis device 2 of this embodiment is corrected according to the oxygen concentration, the measurement error of the NOx concentration value in the exhaust gas falls within 0.10% even though the oxygen concentration in the diluted exhaust gas increases.
According to these results, if the exhaust gas analysis device 2 in accordance with this embodiment is used for the exhaust gas analysis system using the dilution sampling type, it is possible to reduce the measurement error of the concentration value of the component to be measured resulting from the change of the viscosity of the diluted exhaust gas so that it becomes clear that the concentration value of the component to be measured in the exhaust gas can be calculated with higher accuracy.
This invention is not limited to the above-mentioned embodiment.
In the above-mentioned embodiment, the exhaust gas analysis system 100 measures the concentration of the component as the object to be measured in the exhaust gas, however, the object to be measured is not limited to this. In the other embodiment, the exhaust gas analysis system 100 may measure a mass or a number of particles of the component to be measured in the exhaust gas.
In case that the exhaust gas analysis system 100 measures the number of the particles of the component to be measured in the exhaust gas, the analyzing part 21 may be a solid particle number measuring device (SPCS) using a laser scattering type condensation particle counter (CPC). In case that the exhaust gas analysis system 100 measures the mass of the component to be measured in the exhaust gas, the analyzing part 21 may be a PM collection filter as being a PM measuring device to collect particulate matters (PM) contained in the diluted exhaust gas. In addition, the analyzing part 21 may be other measuring device that can make a measurement by the use of the diluted exhaust gas. Furthermore, the exhaust gas analysis system 100 may measure the mass of the discharged component based on the product of the concentration value of the calculated component to be measured in the exhaust gas and the flow rate of the exhaust gas.
In the above-mentioned embodiment, the viscous component concentration determining part 231 calculates the dilution ratio by the ratio of the theoretical CO2 concentration in the exhaust gas to the total concentration of the obtained carbon components in the diluted exhaust gas, however, it is not limited to this. In the other embodiment, the dilution ratio may be calculated as a ratio (a volume ratio) of the integrated value Vmix (a volume of the diluted exhaust gas) of the diluted exhaust gas flow rate to the integrated value Vex (a volume of the exhaust gas) of the exhaust gas flow rate. The above-mentioned CVS device 1 is so controlled that the flow rate of the diluted exhaust gas becomes constant, namely the total flow rate of the exhaust gas flow rate and the dilution gas flow rate becomes constant. As this result, the integrated value Vex of the exhaust gas flow rate can be calculated by measuring the integrated value Vmix of the diluted exhaust gas flow rate and the integrated value Vamb (a volume of the dilution gas) of the dilution gas flow rate, and the dilution ratio can be calculated by the use of the integrated value Vex of the exhaust gas flow rate.
In the above-mentioned embodiment, the viscous component concentration determining part 231 calculates the concentration of the viscous component in the diluted exhaust gas based on the concentration of the oxygen component in the dilution gas and the dilution ratio of the diluted exhaust gas, however, it is not limited to this. In the other embodiment, the exhaust gas analysis device 2 may further comprise an oxygen concentration meter such as a zirconia type oxygen sensor that measures the oxygen concentration in the diluted exhaust gas, and the viscous component concentration determining part 231 may obtain the oxygen concentration measured by the oxygen concentration meter.
In the above-mentioned embodiment, the analyzing part 21 is the CLD type NOx meter, however, a detector using other principle such as an NDIR method detector, an FID method detector, an FTIR method detector and a QCL-IR method detector may be used.
In the above-mentioned embodiment, the component to be measured is NOx or the particles, however, it is not limited to this, and a carbon compound such CO, CO2, HC and THC or the like or a sulfur compound such as SO2, and H2S or the like may be the object to be measured.
In the above-mentioned embodiment, the viscous component concentration determining part 231 calculates the dilution ratio (DF) by the use of the total concentration of the carbon components in the diluted exhaust gas housed in the diluted exhaust gas sampling bag (M), however, it is not limited to this. In the other embodiment, a sampling line that samples the diluted exhaust gas may be arranged in a downstream side of a point where the mail flow channel (ML) of the CVS device 1 and the dilution gas flow channel (DL) converge and a concentration meter that can continuously measure the concentration of the carbon component in the diluted exhaust gas may be connected to the sampling line. In accordance with this embodiment, the viscous component concentration determining part 231 may calculate the dilution ratio (DF) by the use of the concentration value that is continuously measured by the concentration meter connected to the sampling line.
In the above-mentioned embodiment, the concentration of the component to be measured is corrected in accordance with the oxygen concentration while the viscous component that is different from the component to be measured in the diluted exhaust gas is set as oxygen, however, it is not limited to this. In the other embodiment, the concentration of the component to be measured may be corrected by the use of a concentration of a component that is contained in the dilution gas and that is a viscous component other than oxygen whose viscosity is higher than that of the component to be measured.
The exhaust gas analysis system 100 in accordance with other embodiment may comprise a dilution gas sampling bag that samples and houses the dilution gas. The exhaust gas analysis device 2 may calculate the NOx amount contained in the exhaust gas by means of a background correction by subtracting the measured NOx concentration of the dilution gas housed in the dilution gas sampling bag from the NOx concentration in the diluted exhaust gas housed in the diluted exhaust gas sampling bag. In this case, the arithmetic device 23 may correct the concentration value output by the analyzing part 21 in accordance with the concentration of the viscous component (oxygen) that is different from the component (NOx) to be measured contained in the dilution gas. The arrangement to correct the concentration value of the component to be measured contained in the dilution gas is the same as the arrangement to correct the concentration value of the component to be measured contained in the above-mentioned diluted exhaust gas.
In the above-mentioned embodiment, the exhaust gas analysis system 100 samples all amount of the exhaust gas and dilutes it, however, it is not limited to this. In the other embodiment, a part of the exhaust gas may be sampled and diluted.
In the above-mentioned embodiment, the exhaust gas analysis system 100 measures the component to be measured in the exhaust gas discharged in the test using the chassis test device, however, it is not limited to this. In the other embodiment, the component to be measured in the exhaust gas discharged in a test using a driving test device such as an engine test device or a power train may be measured.
In the above-mentioned embodiment, the viscous component that is different from the component to be measured is the component whose viscosity is higher than the viscosity of the component to be measured, however, it is not limited to this. In the other embodiment, the viscosity of the viscous component that is different from the component to be measured may be higher than the viscosity of the exhaust gas. In accordance with this, the effect of the above-mentioned invention can be also obtained.
In the above-mentioned embodiment, the gas analysis system 100 measures the component to be measured in the exhaust gas discharged from the internal combustion engine such as the engine, however, it is not limited to this. In the other embodiment, the component to be measured in the exhaust gas discharged from an external combustion engine such as a thermal power station or a factory may be measured.
In addition, it is a matter of course that the present claimed invention is not limited to the above-mentioned embodiment and may be variously modified without departing from a spirit of the invention.
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2017-167975 | Aug 2017 | JP | national |
2017-168234 | Sep 2017 | JP | national |
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