DE3710268A1 - METHOD FOR MONITORING THE FUNCTION OF CATALYSTS - Google Patents

Abstract

In a process for monitoring the performance of catalysers, a heat energy is determined at a first point in the region of the catalyser (1) and the heat energy at at least a second point in the region of the catalyser (1) is also determined. The catalytic process occurs at least partially between the first and second points. The two heat energies are compared, and from this comparison a control value is derived and further evaluated.

Description

The invention is based on a method for Functional monitoring of catalysts by adding thermal energy is determined at a first location in the region of the catalyst.

Such a method is known from DE-PS 24 06 073. There a circuit arrangement is described which the Temperature monitoring on catalysts for the exhaust gases from Motor vehicle internal combustion engines is used. Such Temperature monitoring is required because the Catalyst can be overheated and destroyed. The circuit arrangement of DE-PS 24 06 073 enables Determination of thermal energy in one place, regardless of the Ambient temperature. When a certain one is exceeded critical temperature, an indicator lamp will flash brought, and the driver of the motor vehicle Overheating of the catalyst signals. The disadvantage is that the driver of the catalytic converter only after the Disturbance is signaled and a continuous Monitoring is not provided. Will continue to be disadvantageous only the catalyst overheating is monitored. A Function monitoring, d. H. monitoring to what extent the Catalyst performs its exhaust gas cleaning function not possible with the subject of DE-PS 24 06 073. A Aging process of the catalyst or a failure of the Catalyst, due to non-temperature-related disturbances, does not appear.

From DE-OS 22 22 498 is a temperature controller for one known catalytic reaction chamber. This is done by a Cooling flow cooled, the amount of cooling air flow in essentially proportional to the temperature increase of the chamber is regulated.  

Furthermore, DE-OS 22 44 227 is a device known that the exhaust gases from at elevated catalyst temperature Motor vehicle engines by means of a controller Bypass valve bypasses the catalytic muffler. A disadvantage of the subject of these two publications again that only temperature monitoring takes place. A Function monitoring does not take place.

Furthermore, it is known in automotive engineering Vehicle emissions according to various test regulations determine, these tests mainly on a Engine test bench can be used. This is usually done with gas analytical method of degree of conversion measured. The Degree of conversion, i.e. the percentage turnover is calculated from the Concentrations of the input and output products determined. This, for example, is the response behavior of Catalysts determined by the degree of conversion in Dependence on the exhaust gas temperature at the entrance to the Catalyst is measured. Such a gas analytical process requires a large and expensive apparatus construction and comes therefore for installation in a catalyst system for a permanent Function monitoring out of the question.

The invention has for its object a method for Function monitoring of catalysts of the beginning described type so that the function of Catalyst is constantly monitored and that the process is inexpensive and works reliably, and therefore for the Series installation in catalysts is suitable.

According to the invention this is achieved in that the Thermal energy at least at a second location in the area the catalyst is determined to be between the first location and the second place the catalytic process at least partially expires that the two thermal energies  be compared with each other that from this comparison a control variable is formed and that this control variable is evaluated. The operation of the catalyst is based insist that the energy thresholds for the initiation of Oxidation and reduction processes are reduced. in the The catalyst thus undergoes chemical reactions that are exothermic or endothermic in nature, i.e. they run under Release or consumption of thermal energy. At mixed reactions, such as those of today known three-way catalysts for motor vehicles occur the exothermic reactions predominate. Because of this endothermic or exothermic reactions in the catalyst Difference between the thermal energy of the entering gas and the thermal energy of the gas emerging from the catalyst. By determining the thermal energies in two places, the first Place before the catalytic process and the second place after the catalytic process, two result from each other different thermal energies, the size of each other in Comparison can be made, and from which conclusions can be drawn the catalyst is pulled in terms of its effectiveness can. Constant function monitoring is therefore easy possible. The constant function monitoring is therefore required because the catalyst is caused by chemical poisoning, for example lead, phosphorus or zinc, by thermal Aging, i.e. by decreasing the current surface or by mechanical poisoning like coverage of the active layer ages and thereby significantly reduces the effectiveness of the catalyst becomes or the catalyst its job, the exhaust gas cleaning not fulfilled at all. Furthermore, the catalyst can be deactivated by overheating, even melting. All these processes can be effective and be continuously monitored. This method is suitable to monitor all catalytic processes, as with Catalytic converters in motor vehicles or catalytic converters Exhaust gas detoxification systems of any kind, for example  Heating systems.

The determination of the thermal energy can be advantageous by Temperature measurement take place. Temperature measurements are easy feasible, and the necessary instruments are on the market available as standard for relatively low prices. With these Instruments is a temperature measurement with a relatively high level Accuracy possible.

The thermal energy of the gas stream is advantageously determined. This ensures that no heat conduction losses occur and falsify the determination of thermal energies. of course is it is also possible to use the thermal energies of the catalyst block, the and drain pipes under any combination thereof determine. However, the exothermic or endothermic process measured only indirectly. The indirect measurement, i.e. the measurement the extent to which other parts have heated up or cooled down, can affect the accuracy of the procedure.

The tax quantity can be determined by forming the difference between the Temperature in the first measuring location and the temperature in the second measurement location can be determined. The formation of the tax figure as Difference between the temperature in the first location and the Temperature in the second measuring location can easily be found on the market carry out existing elements. This difference value has is special for the further evaluation or display proven simple and effective.

According to the invention are in the device for performing the Method at least two measuring elements, one evaluation unit for Evaluation of the signals from the measuring elements and a display unit intended. With the help of the measuring elements is in a place that before the catalytic process and in a place that after the catalytic process lies, the temperature measured. The  Both signals of the measuring elements are an evaluation unit Provided that takes over the evaluation and then forwarded to an ad unit.

Two thermocouples can be provided as measuring elements the two thermocouples are connected to each other. Thermocouples are suitable for measuring temperatures in in a special way due to its fast response time Temperature fluctuations, their cheap manufacture and the Possibility, the resulting from the temperature Tap thermal voltage at any point. By the Interconnecting the thermocouples, i.e. the relocation of the Cold junction of the thermocouples to the respective other measuring location, you save yourself the arrangement of a normally required Device for keeping the cold point of the Thermocouples.

The two measuring elements can also consist of a thermocouple, where at the first location the sensor of the thermocouple and on the cold junction of the thermocouple is arranged at the second location. This arrangement saves a thermocouple without the accuracy of the measurement is impaired.

The evaluation unit can be an operational amplifier, an A / D Converter and a digital display unit and a recorder exhibit. These are all items that are commercially available can be purchased and so a cheap device contribute. These elements are mature and guarantee thus reliable operation.

Heat stores are advantageous for increasing the Thermal capacity of the thermocouples provided. So that becomes a stable display of an average value reached.  

A fastening device is advantageous for each measuring element provided, the individual fastening devices the have the same heat losses. So that the temperature drop due to heat conduction losses at both measuring points almost the same held, and with it a reliable and accurate measurement achieved.

The invention is based on preferred embodiments further described. Show it:

Fig. 1 is an illustration of the catalyst;

Fig. 2 is a catalyst with an evaluation unit;

Fig. 3 possible places where the thermal energy can be determined.

Fig. 1 shows a catalytic converter 1 through which a gas indicated by an arrow 2 and flows in accordance with arrow 3 flows out again. The catalytic converter 1 has an inlet pipe 4 and an outlet pipe 5 . A thermocouple 6 is provided on the feed pipe 4 and a thermocouple 7 on the drain pipe 5 . The thermocouples 6 and 7 are fastened to the feed pipe 4 and the discharge pipe 5 by fastening devices 8 . The temperature difference between the exhaust gas flowing into the catalytic converter 1 and the exhaust gas leaving the catalytic converter 1 is measured by means of the thermocouples 6 and 7 . The inflowing gas is heated in the catalyst 1 by a predominantly exothermic reaction, so that it has a higher temperature at the outlet from the catalyst 1 than at the inlet. This temperature difference occurring in the functioning catalyst 1 (temperature increase in exothermic reactions) is measured in front of and behind the catalyst 1 using two thermocouples 6 and 7 . NiCr-Ni thermocouples, for example, can be used as thermocouples 6 and 7 . However, it is of course also possible to determine the temperature by means of other measuring methods or measuring methods. For retrofitting for catalysts, the thermocouples are fastened to the feed pipe 4 or the drain pipe 5 by means of fastening devices 8 . The fastening device 8 can consist of a mounting plate with suitable clamps. After the cold start of the engine, the measuring point in the supply pipe 4 first heats up more quickly than in the discharge pipe 5 , since the exhaust gas heated in the engine gives off heat to the colder exhaust gas pipes and the catalyst block. During this phase, a lower temperature is measured on the thermocouple 7 , which is connected to the discharge pipe 5 , than on the thermocouple 6 . As soon as the catalytic converter 1 starts to work after the so-called starting temperature has been reached, the exhaust gas absorbs additional thermal energy from the catalytic converter 1 due to the predominant exothermic catalytic processes. The result is that the sign of the temperature difference is reversed. The temperature at the discharge pipe 5 rises above the temperature at the supply pipe 4 . This temperature difference serves as a measure of the functionality of the catalytic converter 1 .

Fig. 2 shows the catalyst 1 with its inlet tube 4 and the outlet tube 5 and with its thermal elements 6 and 7. The thermocouples 6 and 7 are connected to an evaluation unit 9 via the inputs 10 and 11 . The evaluation unit 9 contains an operational amplifier 12 , an AD converter 13 , and a digital display 14 . A recorder 16 is connected to an output 15 of the evaluation unit 9 . The evaluation unit 9 permits the acquisition and processing of the measured temperatures in various ways. The inputs 10 and 11 of the evaluation unit 9 are supplied with the differential thermal voltage of the thermocouples 6 and 7 connected to one another. The temperature difference between the two locations of the measurement is displayed by a digital display 14 . The analog value proportional to this temperature difference is fed from the output 15 to a recorder 16 . Test runs with a measuring system according to FIG. 2 in a car with a 66 KW engine and a regulated three-way catalytic converter showed that when the engine is warm, the temperature of the discharge pipe 5 is more than 20 K higher than that of the supply pipe 4 . Furthermore, it was found that a negative display occurs during the first few minutes during a cold start, that is to say the temperature at the inlet pipe 4 is higher than at the outlet pipe 5 , since the minimum temperature required for the catalytic converter 1 to work is not yet reached. It is of course also possible to use a simple analog or digital temperature difference display. This is particularly suitable for practical use in motor vehicles. The two thermocouples 6 and 7 are attached at suitable locations, in the vicinity of the catalyst 1 . The function of the catalytic converter 1 is monitored by reading the temperature difference display. If the temperature difference drops by a certain value, a fault in the catalyst system is suspected, the cause of which can be clarified, for example, by an exact exhaust gas analysis. If, on the other hand, the temperature difference rises above the normal values usual for driving, an increased delivery of unused fuel by the engine is suspected, the cause of which can be, for example, faults in the ignition system. In the event of such faults, the heat energy output in the catalytic converter increases significantly, which can quickly lead to the deactivation and destruction of the catalytic converter 1 . The method proposed here can detect all such errors and make it possible to prevent the consequential damage to the catalytic converter 1 resulting therefrom.

Fig. 3 shows various locations for attachment of the thermal elements 6 and 7. When retrofitting, the sensors of the thermocouples 6 and 7 will usefully be arranged on the outside of the supply pipe 4 and the discharge pipe 5 at the locations 17 and 18 . An accommodation is also possible in bores 19 and 20 in the connecting flanges 21 and 22 of catalyst 1 and the feed pipe 4 or the drain pipe 5 . In these cases, however, it should be noted that heat conduction losses measure a temperature that is lower than the exhaust gas temperature. The two sensors should therefore be arranged thermally as symmetrically as possible in order to keep the temperature drop due to heat conduction losses at both measuring points approximately the same. This is achieved in practice if the supply pipe 4 and the discharge pipe 5 in material and wall thickness on both sides of the catalytic converter 1 match as closely as possible and identical fastening devices 8 are used for fastening the sensor. When attaching the sensors of the thermocouples 6 and 7 in the connecting flanges 21 and 22 , the holes 19 and 20 should be the same depth. If the temperature sensors of the thermocouples 6 and 7 are arranged directly in the exhaust gas flow, there are no heat conduction losses. The locations 23 and 24 on the supply pipe 4 and the discharge pipe 5 are shown here, for example. However, it should be noted that the temperature changes during load changes in the gas flow are considerable and do not take place in the feed pipe 4 synchronously with those in the discharge pipe 5 . It has been shown that when the measured temperature differences are averaged in the most varied of driving modes, there is an average increase in temperature of the exhaust gas flow in the catalytic converter 1 of more than 20 K. To achieve a stable display of this mean value, for example, an increase in the heat capacity of the temperature sensors of the thermocouples 6 and 7 by heat accumulators is conceivable. Of course, a stable display can also be achieved electronically.

Furthermore, there is the possibility of installing the temperature sensors of the thermocouples 6 and 7 directly in the catalytic converter 1 . In addition to the measurement in the free exhaust gas flow at locations 25 and 26 , the sensors can also be integrated in the catalyst block at locations 27 , 28 or 29 . The fluctuations in the display that occur during measurements in the gas flow during load changes can thus be largely suppressed from the outset. Finally, the attachment of a measuring point at location 30 , which is located on the catalyst housing, is shown.

However, this location 30 should generally not be highly recommended because the thermal resistance between the catalyst block and the housing is usually relatively high.

• 1 Catalyst
  2 arrow
  3 arrow
  4 feed pipe
  5 discharge pipe
  6 thermocouple
  7 thermocouple
  8 fastening device
  9 evaluation unit
  10 entrance
  11 entrance
  12 operational amplifiers
  13 AD converters
  14 digital display
  15 exit
  16 writers
  17 place
  18 place
  19 hole
  20 hole
  21 connecting flange
  22 connecting flange
  23 place
  24 place
  25 place
  26 place
  27 place
  28 place
  29 place
  30 place

Claims (10)

1. A method for monitoring the function of catalysts by determining a thermal energy at a first location in the region of the catalyst, characterized in that the thermal energy is determined at least also at a second location in the region of the catalyst ( 1 ) that between the first location and In the second place, the catalytic process takes place, at least in part, that the two thermal energies are compared with each other, that a control variable is formed from this comparison, and that this control variable is evaluated. 2. The method according to claim 1, characterized in that the Determination of the thermal energies is carried out by temperature measurement. 3. The method according to claim 1, characterized in that the Thermal energies of the gas stream can be determined. 4. The method according to claim 2, characterized in that the Control variable by forming the difference between the temperature the first measuring point and the temperature at the second measuring point is determined. 5. Device for performing the method according to claim 1, characterized in that at least two measuring elements are provided, that an evaluation unit ( 9 ) for evaluating the signals of the measuring elements and a display unit is provided. 6. The device according to claim 5, characterized in that two thermocouples ( 6 , 7 ) are provided as measuring elements, and that the two thermocouples ( 6 , 7 ) are connected to one another. 7. Apparatus according to claim 5, characterized in that the two measuring elements consist of a thermocouple (6), that the thermocouple (6) is disposed at the first location of the probes and is provided at the second location, the cold junction of the thermocouple (6) . 8. The device according to claim 5, characterized in that the evaluation unit ( 9 ) has an operational amplifier ( 12 ), an AD converter ( 13 ) and a digital display ( 14 ) and a recorder ( 16 ). 9. Apparatus according to claim 6 or 7, characterized in that heat accumulators for increasing the thermal capacity of the thermocouples ( 6, 7 ) are provided. 10. The device according to claim 5, characterized in that a fastening device ( 8 ) is provided for each measuring element, wherein the individual fastening devices ( 8 ) have the same heat losses.