DE19619621A1 - Mass concentration measuring device for particles in exhaust gases of IC engines using removable probe - Google Patents

Abstract

The system includes a removal probe (2), by which the exhaust gas (17) can be supplied to a filter (4) across a line (1L), to which is connected a radiation source (5) for beta radiation. A pump (3) is arranged between the removal probe (2) and the filter (4). At least respectively one measuring system (6, 7, 8) is provided for determining the intensity of the beta radiation, determining the through flow amount of the exhaust gas through the filter and the mass take up of the filter. The measuring systems (6, 7, 8) are connected to at least one evaluation unit (9). The removal probe (2) is integrated in a pipe line (16), through which at least one part of the exhaust gas (17) to be tested is passed. The filter (4) is designed as a strip, and a rotary slide vacuum pump (3) is integrated in the line (1L).

Description

The invention relates to a device for determining the mass concentration tration of particles in exhaust gases from internal combustion engines according to the Ober Concept of claim 1.

There are already a large number of devices for determining the mass concentrations tration of particles in exhaust gases known. However, these devices are on it aligned to record large mass concentrations, whereas the measured values a small number of particles, such as those found in gas exhaust from gas turbines occur, are inaccurate.

In one of these known devices, the absorption of β radiation is used Measurement of the mass concentration of particles used. Via a sampling probe the exhaust gas to be examined is sucked in through a filter belt. The ent in the exhaust held dust particles are separated on the filter belt. This is from the Radiation from a β-radiation source radiates through. On the opposite side the intensity of the β radiation is measured. From the intensity of the β radiation The separated dust mass can be determined by the passage through the filter belt will. Devices are known which continuously collect the particles and at the same time determine the mass concentration. Devices of this type are also known who work discontinuously. All of these devices are because of their relatively low flow of about 150 l / h only for higher concentrations or long measuring times of about an hour are suitable. In addition, the evaluation of the Mass growth through linear regression over a set number of Measuring points. It is therefore slow and inflexible.  

In another known device for measuring the mass concentration tion of particles in exhaust gases used gravimetric filters. Here is by a filter, the mass of which is determined before the measurement, a certain amount Exhaust gas sucked through. The masses can then be increased from the filter weight concentration of the exhaust gas can be determined. Procedures of this kind are in the VDI Guideline 2066 described. The gravimetric methods generally show high accuracy, but cannot be used continuously. The main area of application for these methods is acceptance measurements of systems.

Furthermore, optically operating devices are known with which the exhaust gas opacity or opacity is determined. Here, analyzers are used, which according to work on the principle of transmission or reflection. These optical measuring methods work with great accuracy. They can be used in very small quantities Dust particles are detected. The disadvantage of this optical process ren that the mass concentration can not be determined directly. The opti Measured variables can only be converted into mass concentrations in special cases count. These special cases are generally in internal combustion engines not given. Another disadvantage is the cross sensitivity to other exhaust gases ingredients such as NO₂.

The invention has for its object to show a device with the very small mass concentrations of particles in the exhaust gases from combustion power machines can be determined very quickly.

This object is achieved by the features of patent claim 1.

Further inventive features are characterized in the dependent claims.

The only related to Description FIG. 1 shows a device 1, the devices having a sampling probe 2, a pump 3, a filter 4, a radiation source 5, three measurement 6, 7 and 8 as well as an evaluation unit 9 is provided. The removal probe 2 is installed in line 16 . With it, the exhaust gas 17 to be examined is taken from the line 16 . The structure of the sampling probe 2 is known from the prior art. It is therefore not explained in more detail here. The line 16 is temperature-controlled, and can be heated as well as cooled. This ensures sichge that the device 1, the exhaust gas 7 can always be supplied at a temperature of more than 130 ° C. The exhaust gas 7 led through line 16 should have a temperature of 130 ° C. so that there is no deposition of particles 18 contained in the exhaust gas 17 . The distance between the device 1 and the point (not shown here) at which the line 16 branches off from the exhaust duct of an internal combustion engine (not shown here) is only so great that condensation of particles 18 is excluded. From the sampling probe 2 , the exhaust gas 17 is passed through a line 1 L, which belongs to the device 1 , and is also passed out of the device 1 again. The filter 4 , which is designed as a band, is integrated in the line 1 L behind the sampling probe 2 . The filter 4 is arranged perpendicular to the longitudinal axis of the line 1 L and spans the entire cross section of the line 1 L. The filter 4 in the area of the line 1 L can be replaced in a simple manner by further transport of the filter belt. The exhaust gas 17 coming from the sampling probe 2 is passed through the filter 4 . The filter 4 is designed such that the particles 18 carried in the exhaust gas are all deposited on it. With the help of the pump 3 , which in the embodiment shown here as a rotary vane vacuum pump 3
formed and connected between the sampling probe 2 and the filter 4 , the flow of the exhaust gas 17 through the filter 4 can be increased to 2000l / h.

According to the invention, a further pump (not shown here) can be installed in line 16 in order to increase the transport of the exhaust gas 17 to 20 m³ / h. In this case, it makes sense to install the sampling probe 2 in a bypass line (not shown here), which is arranged in the area of the device 1 parallel to the line 16 . By using pumps, the determination of the mass concentration is significantly accelerated. Β radiation is emitted by the radiation source 5 , which is connected downstream of the filter 4 . This β radiation is directed onto the filter 4 . The intensity of the β radiation is reduced by the particles 18 which hang on the filter 4 . The reduction of the β radiation is determined with the aid of the measuring device 6 . A probe 65 , which belongs to the measuring device 6 , is arranged between the filter belt 4 and the pump 2 . The measurement signals of the measuring device 6 are fed to the evaluation unit 9 . For this purpose, the signal output 6 A of the measuring device 6 is connected to the signal input 9 A of the evaluation unit 9 . The evaluation unit 9 is designed as a process computer in the embodiment shown here. The values of the intensity of the β radiation which are emitted by the radiation source 5 are stored in it. The evaluation unit 9 determines from the stored values and the supplied measurement signals the reduction in the radiation intensity of the β radiation that has passed through the filter 4 .

With the help of the measuring device 7 , which is in contact with the filter 4 , the mass increase of the filter 4 is determined, which is experienced by the stuck particles 18 . The measuring device 8 is integrated in the flow direction of the exhaust gas 17 hen behind the filter 4 in the line 1 L. It is used to determine the amount of exhaust gas 17 through which the filter 4 flows for a defined time, for example one hour. The signal outputs 6 A, 7 A and 8 A of the measuring devices 6 , 7 and 8 are connected to the signal inputs 9 A, 9 B and 9 C of the evaluation unit 9 . The mass concentration of the particles 18 contained in the exhaust gas 17 is determined with the aid of the evaluation unit 9 .

When calculating the mass concentration, both statistical methods are used as well as knowledge of the operation of the internal combustion engine. Becomes the incinerator, for example, operated stationary, so the Massenkon concentration by linear regression of a certain number of mass values certainly. If the incinerator is operated transiently, for example when starting certain operating states, the concentration from the Mas values in an interval in which the operating state of the machine is constant, certainly. As a result, the calculation of the mass concentration is essential accelerates. In addition to linear regression, you can also use for evaluation whose statistical methods are used.

Claims (4)

1. Device for determining the mass concentration of particles in exhaust gases from internal combustion engines with a sampling probe ( 2 ), from which the exhaust gas ( 17 ) can be fed via a line ( 1 L) to a filter ( 4 ) to which a radiation source ( 5 ) for β-radiation is connected downstream, characterized in that a pump ( 3 ) is arranged between the sampling probe ( 2 ) and the filter ( 4 ), that at least one measuring device ( 6 , 7 , 8 ) each for determining the intensity of the β-radiation , to determine the flow rate of the exhaust gas ( 17 ) through the filter ( 4 ) and to determine the increase in mass of the filter ( 4 ) is provided, and that the measuring devices ( 6 , 7 and 8 ) are connected to at least one evaluation unit ( 9 ) . 2. Apparatus according to claim 1, characterized in that the Ent probe ( 2 ) is installed in a line ( 16 ) through which at least part of the exhaust gas to be checked ( 17 ) can be conducted that the sampling probe () downstream filter ( 4 ) formed as a band and a rotary vane vacuum pump ( 3 ) is installed in the line ( 1 L) between the filter ( 4 ) and the removal probe ( 2 ). 3. Device according to one of claims 1 or 2, characterized in that a probe ( 6 S) of the measuring device ( 6 ) is arranged between the filter ( 4 ) and the pump, that the measuring device ( 7 ) with the filter ( 4 ) is connected and that the measuring device ( 8 ) downstream of the filter ( 4 ) and at least partially integrated in the line ( 1 L). 4. Device according to one of claims 1 to 3, characterized in that the signal outputs ( 6 A, 7 A and 8 A) of the measuring devices ( 6 , 7 , 8 ) to the signal inputs ( 9 A, 9 B and 9 C) of Evaluation unit ( 9 ) are connected, and that the evaluation unit ( 9 ) is designed as a process computer.