DE3306484A1 - Exhaust-gas control system for internal combustion engines with a turbocharger and a catalytic converter for exhaust-gas detoxification - Google Patents

Abstract

An internal combustion engine (10) with a turbocharger (20) and an exhaust pipe (13) is provided with an exhaust-gas control system. A turbine (21) of the turbocharger (20) is arranged in the exhaust pipe (13) and is driven by the exhaust gases. The exhaust-gas control system comprises a catalytic converter (35) which is arranged downstream of the turbine (21) in the exhaust pipe (13) and serves to clean or detoxify the exhaust gases. A temperature sensor (75) serves to sense the temperature of the converter (35). The control system furthermore comprises a mechanism (42) which makes it possible to control the exhaust-gas flow in such a way that at least part of the exhaust gases by-passes the turbine (21) before entering the converter (35). A device (76, 50) controls the mechanism (42) in accordance with the sensed temperature of the converter (35) in such a way that the exhaust gases by-pass the turbine (21) if the sensed temperature is below a predetermined value. <IMAGE>

Description

DESCRIPTION

The invention relates to an exhaust gas control device for internal combustion engines according to the preamble of the main claim.

It is known internal combustion engines with an exhaust gas-driven turbocharger equipped to increase the performance of the machine. When the exhaust fumes the turbine pass through the tube charger, so their temperature generally decreases by about 100 "C as the exhaust gases lose a considerable amount of heat when driving the turbine.

If the internal combustion engine is equipped with a catalytic converter Exhaust gas decontamination is provided, the converter is downstream of the turbine of the Turbocharger arranged in the exhaust duct. The temperature of the converter must be above a certain value must be kept so that a sufficient effectiveness of the catalytic converter is guaranteed. Due to the temperature loss of the exhaust gases in the turbine, the temperature of the converter can under certain operating conditions the internal combustion engine, for example at low speed or low load, drop below the required operating temperature of the converter, so that the effectiveness of the catalytic converter is impaired.

The invention is to provide an exhaust gas control device for an internal combustion engine with one turbocharger and one downstream of the same arranged catalytic converter, which ensures that the effect of the converter is not affected by the turbocharger.

The invention results in detail from the characterizing part of the main claim. Advantageous design services of the invention are specified in the subclaims.

The control device according to the invention comprises a temperature sensor for sensing the temperature of the catalytic converter. A bypass facility allows at least a portion of the exhaust gases upstream of the turbine of the turbocharger derive and downstream of the turbine but upstream of the converter again to be introduced into the exhaust duct. The bypass device is activated by a Scanned converter temperature responsive device controlled in such a way that part of the exhaust bypasses the turbine when the sensed temperature falls below drops by a specified value.

The following are preferred embodiments of the invention explained in more detail with reference to the drawings.

FIGS. 1 to 3 each show schematically an internal combustion engine Turbocharger and catalytic exhaust gas converter and with an exhaust gas control device according to a first, second and third embodiment of the invention.

According to Fig. 1, an internal combustion engine 10 comprises combustion chambers 11 and an intake duct 12 leading to the combustion chambers for introducing air into the Combustion chambers 11.

An exhaust gas duct 13 emanating from the combustion chambers 11 is used for discharge the exhaust gases from the combustion chambers to the atmosphere. In the usual way are inlet valves 14 at the junctions of the intake duct 12 into the combustion chambers 11 and exhaust valves 15 arranged at the junctions of the exhaust gas duct 13 in the combustion chambers. In Fig. 1 is just a single combustion chamber with an inlet and an exhaust valve 14.15 shown. A throttle valve 16 for metering the air supply to the combustion chambers 11 is arranged in the intake duct 12.

A turbocharger 20 includes a turbine 21 and a compressor 22. The turbine 21 is arranged in the exhaust duct 13 and is carried out in a known manner the exhaust gases emitted from the combustion chambers 11 are driven. The compressor 22 is arranged upstream of the throttle valve 16 in the intake duct 12. The compressor 22 and the turbine 21 are mounted on a common shaft or axis, so that the compressor 22 is driven by the turbine 21. The rotation of the Compressor 22, the combustion chambers 11 are charged with compressed air.

A first bypass duct 23 is connected to the exhaust duct 13 in such a way that that he bypasses the turbine 21. One arranged in the bypass channel 23 as a butterfly valve The first bypass valve 24 embodied in the form of a pendulum valve is used for opening and closing or to adjust the effective cross-section of the bypass duct 23. If that Bypass valve 24 closes the bypass channel 23, the entire runs out Exhaust gas emitted from the combustion chambers 11 passes through the turbine 21, and the turbine runs through driven by the exhaust gases flowing through. When the bypass valve 24 is the first bypass passage 23 keeps open, some of the exhaust gases can pass the turbine 21 through the bypass duct 23 bypass.

A first pressure-dependent actuator 25 is connected to the intake duct 12 downstream of the compressor 22, but upstream of the throttle valve 16 in connection, so that it is the output pressure of the compressor 22, i.e., the pressure in the suction duct 12 is sampled downstream of the compressor. The actuator 25 is through a linkage 26 is connected to the bypass valve 27 and controls that Bypass valve 24 as a function of the sensed air pressure. When the pressure of the compacted Air, that is, the output pressure of the compressor 22 has a predetermined overload exceeds the corresponding value, the actuator 25 causes the opening of the bypass channel 23 by the actuator 24. When the pressure of the compressed air is below the predetermined value, the actuator 25 keeps the bypass valve 24 closed, so that the bypass channel 23 is blocked. By opening the bypass channel 23 becomes the exhaust gas flow to the turbine 21 and thus the output power of the turbine decreased, so that the performance of the compressor 22 and the output pressure decreases drops below the specified value. In this way the pressure becomes the most compressed Air generally kept below the set level at which one overloaded could occur. If the bypass channel 23 is blocked, this will normally be the case all exhaust gas expelled from the combustion chambers 11 is directed to the turbine 21, so that the turbine is driven at the highest possible speed.

The actuator 25 includes a first housing 27, a diaphragm 28 and a spring 29. The deformable or movable membrane 28 divides the interior of the housing 27 into a reference chamber 30 and a working chamber 31. The reference chamber 30 is subjected to a constant reference pressure, for example atmospheric pressure, while the working chamber 31 through an opening of the housing 27 with the pressure of the compressed air is applied.

In this way, the membrane 28 deforms and moves accordingly the difference between the reference pressure and the pressure of the compressed air. the Spring 29 is in reference chamber 30 between the wall of housing 27 and the diaphragm 28 arranged so that it biases the membrane 28 with respect to the housing 27. The membrane 28 is connected to the linkage 26 so that it rods 26 actuates the bypass valve 24. When the pressure of the compressed air is the specified If the value exceeds the value, the membrane 28 actuates the bypass valve 24 in the sense of an opening of the bypass duct 23. When the pressure of the compressed air is below the predetermined Is the value, the membrane 28 keeps the bypass valve 24 closed, so that the Bypass channel 23 is blocked.

A catalytic converter 33 is downstream of the turbine 21 and the connection point of the first bypass duct 23 in the exhaust gas duct 13. Before the exhaust gas emitted from the combustion chambers 11 is released into the atmosphere it is subjected to a catalytic treatment in the catalytic converter 35, especially in the case of environmentally harmful substances, such as unburned matter, contained in the exhaust gas Petrol (HC), carbon monoxide (CO) and / or nitrogen oxides (NOx) into harmless substances such as water (H2O), carbon dioxide (wo2) and / or molecular nitrogen (N2) will. The converter 35 works satisfactorily only above a certain one Temperature. The temperature of the converter 35 should therefore be above this value being held.

A second bypass duct 40 is connected to the exhaust duct 13 in such a way that that he also bypasses the turbine 21.

The connection of the exhaust gas duct 13 is upstream of the turbine 21 with the second bypass channel 40 upstream of the connection with the first bypass channel 23 arranged.

The connection of the second bypass channel 40 to the exhaust gas channel 13 downstream of the turbine 23 is downstream of the confluence of the first Bypass channel 23, but upstream of converter 35. A second, in the second Bypass valve 41 arranged bypass channel 40 is used to open or close of the second bypass passage 40. When the second bypass valve 41 is the second bypass passage 40 holds open, can at least at least some of the from the combustion chambers 11 bypasses the turbine 21 through the second bypass duct 40. When the second bypass valve 41 keeps the bypass passage 40 closed, flows all exhaust gas through turbine 21, provided that the first bypass duct 23 is closed by the first bypass valve 24.

The second bypass valve 41 is pressure-dependent by a second Actuator 42 controlled. The actuator 42 comprises a solid housing 43, a membrane 44, a spring 45 and a plunger 46. The membrane 44 divides the interior of the Housing 43 in a reference chamber 47 and a working chamber 48. and is accordingly the pressure difference between the chambers 47 and 48 deformable and movable.

The reference chamber 47 is through an opening of the housing 43 with the Atmosphere in connection. The working chamber 48 is selectively either approximate maintained at atmospheric pressure or at a predetermined negative pressure as follows will be explained in more detail. The plunger 46 on which the second bypass valve 41 is fixed is mounted, is attached to the diaphragm 44, so that the displacement of the diaphragm 44 leads to a movement of the second bypass valve 41. The spring 45 is inside the working chamber 48 is supported between the wall of the housing 43 and the membrane 44 and biases the diaphragm 44 in the closing direction of the second bypass valve 41.

When the working chamber 48 is maintained at approximately atmospheric pressure is, the force of the spring 45 holds the diaphragm 44 in a position in which the second Bypass valve 41 closes the second bypass channel 40. When in the working chamber 41 the predetermined negative pressure is generated, the membrane 44 is against the force the spring 45 moved from the position described above to another position, in which the valve 41 opens the second bypass channel 40.

A pressure control device 50 is used to control the second actuator 42 controllable to supply either atmospheric pressure or the predetermined negative pressure. The control device 50 comprises a vacuum metering valve 51 and an electrically operated one Valve 52.

The vacuum metering valve 51 comprises a housing 53, a membrane 54, a valve body 55 and springs 56 and 57.

The membrane 54 divides the interior of the housing 53 into a primary chamber 58 and a secondary chamber 59 and is according to the pressure difference between the Chambers 58 and 59 movable. The spring 56 is in the primary chamber 58 between the Wall of the housing 53 and the membrane 54 supported. The other spring 57 is in the Secondary chamber 59 is supported between the wall of the housing 53 and the membrane 54. The diaphragm 54 is pretensioned with respect to the housing 53 by the springs 56 and 57. One end of a vacuum channel 60 is downstream of the throttle valve 16 with the intake channel 12 connected. The other end of the vacuum channel 60 extends to the secondary chamber 59 and is connected to this via a throttle bore 61, so that the secondary chamber 59 via the vacuum channel 60 with the vacuum in the suction channel 12 downstream of the Throttle valve 16, i.e., the suction negative pressure is supplied. The valve body 55 is attached to the membrane 54 and movable together with it.

The positions of the valve body 55 relative to the open end of the Vacuum channel 60 are chosen such that the throttle bore 61 or the open end of the vacuum channel 60 open and close by the movement of the valve body 55 leaves. The primary chamber 58 communicates with the atmosphere via an opening in the housing 53 in connection so that it is kept constant at atmospheric pressure. If the Pressure in the secondary chamber 59 below a predetermined value, for example -120 mm Eg (based on atmospheric pressure) drops, moves the Diaphragm 54 so far in the direction of the secondary chamber 59 that the valve body 55 the throttle bore 61, i.e., the open end of the vacuum channel 60 closes and thus a further drop in the pressure in the secondary chamber 59 is prevented. If the Pressure in the secondary chamber 59 rises above the preset value, moves the membrane 54 away from the secondary chamber 59, so that the valve body 55 the throttle bore 61 or the open end of the vacuum channel 60 opens and so does the secondary chamber the suction negative pressure connects and a further increase in pressure in the secondary chamber prevented. In this way, the pressure in the secondary chamber 29 becomes normal essentially held at the preset value. Under certain circumstances however, the pressure in the secondary chamber 59 may rise above the preset value, as will be explained in more detail later. The secondary chamber 59 is via a control channel 62 is connected to the working chamber 48 of the second actuator 42.

The electrically operated valve 52 comprises a housing 63, a diaphragm 64, a valve body 65, a return spring 66 and a spool 67. The housing 63 is attached to the housing 53 of the vacuum metering valve 51. The membrane 64 is deformable or movable and delimits a part of an atmosphere chamber 68 within of the housing 63.

The valve body 65 is attached to the membrane 64 and is therefore common movable with this. The valve body 65 is made of magnetic material and is attached near the coil 67 so that it is fixed to the housing 63 by the Coil can be moved. The return spring 66 is between the wall of the housing 63 and the valve body 65 supported and tensioned the valve body 65 to that of the side facing away from the coil 67. When the coil 67 is energized, the valve body becomes 65 attracted against the force of the return spring 66 in the direction of the coil 67. After the coil 67 is de-energized, the Valve body 65 through the Return spring 66 moved away from the spool. The atmosphere chamber 68 is above a Atmospheric line 69 with intake duct 12 upstream of compressor 22 in Compound and is supplied through this with air under atmospheric pressure.

One end of a branch line 70 is connected to the control channel 62. The other end of the branch line 70 is facing the valve body 65 via a Valve opening 71 in the atmosphere chamber 68 is opened. The position of the opening 71 with respect to the valve body 65 is selected such that the valve body 65 when the coil 67 is de-energized, the opening 71 closes and when the coil 67 is energized, the opening 71 closes Opening 71 releases.

When the coil 67 is de-energized and thus the opening 71 through the valve body 65 is closed, is the connection between the control channel 62 and the atmosphere chamber 68 interrupted via the branch line 70, so that the working chamber 48 immediately is acted upon by the negative pressure in the secondary chamber 59. The vacuum supply the working chamber 48 of the second actuator 42 leads to the fact that the second bypass valve 41 opens the second bypass channel 40. This will create the second bypass channel 40 held open by bypass valve 41 when coil 67 is de-energized. if the coil 67 is energized and thus the opening 71 is opened, there is a connection between the control channel 62 and the atmosphere chamber 68, so that air under atmospheric pressure penetrates into the control channel 62 and the working chamber 48. This leads to an increase the pressure in the working chamber 48 to approximately atmospheric pressure, and the second Bypass channel 40 is closed by bypass valve 41. Although in this one Fall the throttle bore 61 due to the resulting pressure increase in the secondary chamber 59 is open, the working chamber 48 is approximately open Atmospheric pressure held, since the effective cross-section of the valve opening 71 is selected in such a way that that air flows in sufficient quantities through the opening 71 into the control channel 62.

A temperature sensor 75 is for sensing the temperature on the catalytic Converter 35 attached. The temperature sensor 75 comprises a series circuit a thermosensitive element, a resistor and a constant voltage source. The resistance value of the thermosensitive element depends on the Temperature of this element variable. The thermosensitive element is such arranged so that it is exposed to the temperature of the catalytic converter 35. This changes the resistance of the element and thus the voltage drop across this element as a function of the temperature of the catalytic converter 35. The voltage drop across the thermosensitive element is the output of the Temperature sensor 75 which indicates the temperature of the converter 35.

A control unit 76 is used to control the coil 67 as a function from the output of the temperature sensor 75. The control unit 76 includes a Comparator.

The first input of the comparator is with the output terminal of the temperature sensor 75 connected and receives its output signal, which is the temperature of the converter 35 corresponds. A reference voltage is applied to the second input terminal of the comparator at. The comparator produces a binary output signal that has a high value, when the temperature of the converter 35 is above one determined by the reference voltage predetermined value, and otherwise has a low value.

The control unit 67 supplies the binary output signal of the comparator to the coil 67. Thus, the coil 67 is energized by the control unit 76 when the temperature of the Converter 35 above the specified value is, while in the other case the coil 67 is de-energized. The one applied to the comparator Reference voltage is chosen in this case so that the switching point of the Comparator-determining temperature within the operating temperature range of the Converter 35 is located.

When the internal combustion engine 10 is running at low speed or at low speed When the load is running, the pressure of the compressed air is generally less than that value corresponding to an overload, and the first bypass valve 24 holds the first Bypass channel 23 closed. If the second bypass channel 40 also passes through the second bypass valve 41 is closed, in this case the whole is off Exhaust gas ejected from the combustion chambers 11 to drive the turbine onto the turbine 21 before it enters the catalytic converter 35. Generally lose The exhaust gases generate a significant amount of heat or kinetic energy while they are entering the turbine 21 drive. If all the exhaust gases flow through the turbine 21, the Temperature of the turbine 21 leaving and entering the condenser 35 Exhaust gases drop to such a value that the converter 35 is below its predetermined value Operating temperature cools. As soon as the temperature of the converter 35 falls below the predetermined If the temperature drops, the coil 67 is de-energized by the control unit 76.

As a result, the second bypass valve 41 opens the second bypass passage 40, so that at least some of the exhaust gases emitted from the combustion chambers 11 Turbine 21 bypasses through the second bypass duct 40 and so the converter 35 without Heat loss reached. This increases the temperature of the converter 35 entering exhaust gas, so that the temperature of the converter again above the predetermined Value increases. If the temperature of the converter exceeds the specified value again, the coil 67 is excited by the control unit 76 and thereby the Bypass channel 40 closed with the aid of the bypass valve 41, so that all exhaust gases ejected from the combustion chambers are directed to the turbine 21 and drive them with the greatest possible torque. Through the control operations described above the temperature of the catalytic converter 35 becomes close to the predetermined value within the operating temperature range of the converter. if the internal combustion engine 10 is running at high speed or at high load, is the Compressed air pressure normally above the overload threshold, see above that the first bypass valve 24 normally opens the first bypass passage 23 holds. Some of the exhaust gases expelled from the combustion chambers therefore bypasses the turbine 21 through the first bypass channel 23, so that overloading is avoided. At high Speed or high load, the temperature of the exhaust gas is naturally proportionate high and a relatively large amount of exhaust gas is emitted, so that the temperature of the converter 35 is kept above the predetermined value, although the first Bypass channel 23 is open and part of the exhaust gases bypasses the turbine 21. In in this case, due to the high temperature of the converter 35, it becomes the second bypass channel 40 held closed by the second bypass valve 41, so that the turbine 21 supplied amount of exhaust gas is not reduced too much.

Figure 2 shows a second embodiment of the invention with Except for the changes described below similar to the first embodiment is constructed. The control device according to the second embodiment comprises a comparator 80 and a solenoid operated actuator 81. The first input terminal the comparator 80 is connected to the output terminal of the temperature sensor 75 and takes the signal corresponding to the temperature of the catalytic converter 35 on. A reference voltage is applied to the second input terminal of the comparator 80 VREF at. The comparator 80 produces a binary output signal that has a low value when the temperature of the converter 35 is a voltage through the reference VREF exceeds predetermined value, and otherwise has a low value. The output terminal of the comparator 80 is electrical with the solenoid operated actuator 81 connected so that the actuator 81 is controlled by the binary signal. the Coil of the actuator 81 is at a high value of the output signal of the comparator 80 energized and de-energized when this signal is low. The actuator 81 controls the second bypass valve 41 to which it is mechanically connected. That second bypass valve 41 forms in connection with the actuator 81 a common one ON-OFF solenoid valve that closes bypass passage 40 when the actuator solenoid is de-energized and opens when the coil is energized. Holds similar to the first embodiment therefore the second bypass valve 41, the second bypass line 40, is closed, when the temperature of the converter 35 is above the predetermined value, while it opens the bypass channel 40 when the temperature of the converter 35 falls below the specified value drops.

Figure 3 shows a third embodiment of the invention, the differs from the first exemplary embodiment in the features described below differs. The device according to the third embodiment of the invention comprises an electric motor 100 which is used to actuate the second bypass valve 41 is mechanically connected to this. The connection of the engine 100 to the second Bypass valve 41 includes a clutch that controls the rotation of engine 100 in a linear or axial movement of the bypass valve 41 converts. In this case is the degree of opening of the bypass valve 41, i.e. the position of this valve with the aid of a servo device or feedback control described below un- speaking of the temperature of the catalytic converter 35 steadily changeable.

The input terminal of a function generator 102 is with the output terminal of the temperature sensor 75 and takes the temperature of the converter 35 indicating voltage signal. The function generator 102 comprises an analog / analog or voltage / voltage converter, which converts the temperature signal into a function of the Temperature of the converter 35 converts variable voltage signal that one desired position of the second bypass valve 41 corresponds. A potentiometer 104 is for sensing the position of the bypass valve 41 mechanically with the bypass valve tied together. The output voltage of potentiometer 104 is a function of position of the bypass valve 41 variable and thus gives the actual position of the Bypass valve.

A first input terminal of a differential amplifier 106 is connected to the Function generator 102 is connected and takes the setpoint position of the bypass valve 41 corresponding voltage signal. A second input terminal of the differential amplifier 106 is connected to the output terminal of potentiometer 104 and takes that of the Actual position of the bypass valve 41 corresponding voltage signal. Dependent on The differential amplifier 106 generates one of the actual and desired position signals Voltage as a function of the difference between the actual position and the target position of the bypass valve 41 is variable and thus indicates this difference. The input terminal of a driver or amplifier 108 is connected to the output terminal of the differential amplifier 106 connected and takes the difference between the actual and target position of the bypass valve corresponding signal.

The output terminal of driver or amplifier 108 is for control of the motor 100 electrically with the motor tied together. The driver 108 converts the difference signal of the differential amplifier 106 into a suitable signal to drive the motor 100 µm. The differential amplifier 106, the driver 108, the The engine 100 and the second bypass valve 41 are designed in the manner and with each other connected that the actual position of the bypass valve 41 in each case in the sense an approach to the target position is changed when the actual position of deviates from the target position. In this way, the second bypass valve 41 is im essentially held in a position close to the desired target position. The function generator 102 is designed such that the second bypass valve 41 keeps the second bypass channel 40 closed when the temperature of the catalytic Converter 35 is above a predetermined value, and that the bypass valve 41 the bypass line 40 opens continuously when the temperature of the converter 35 drops below the specified value. The continuous control of the position of the second bypass valve 41 allows more stable and smooth control the temperature of the converter 35.

Claims (5)

EXHAUST CONTROL DEVICE FOR COMBUSTION ENGINES WITH TURBOCHARGER AND CATALYTIC CONVERTER TO EXHAUST GAS POISONING PRIORITY: April 27, 1982, Japan, No. 57-61455 PATENT CLAIMS Exhaust gas control device for internal combustion engines, in their Exhaust channel a turbine driven by the exhaust gases of a turbocharger and downstream the turbine a catalytic converter for exhaust gas decontamination is arranged, gek e n n z e i c h ne t by means (75) for sampling the temperature of the Converter (35), a controllable Bypass device (40.41) for diverting at least part of the exhaust gases upstream of the turbine (21) and for forwarding the diverted exhaust gases into the exhaust gas duct (13) between the turbine (21) and the converter (35) and one responsive to the sensed temperature Device (76,50,42; 80,81; 100,102,104,1O6, 108) for opening the bypass device (40,41) when the sampled temperature drops below a predetermined value. 2. Control device according to claim 1, characterized in that g e -k e n n z e i c Note that the temperature-responsive device (76, 50, 42; 80, 81) the Bypass device closes when the sensed temperature exceeds the specified Value exceeds. 3. Control device according to claim 1, characterized in that g e -k e n n z e i c h n e t that the bypass device (40,41) continuous control of the the turbine (21) allows bypassing the amount of exhaust gas and that on the temperature appealing device (100 - 108) which increases the amount of exhaust gas bypassing the turbine (21), when the sampled temperature drops below the specified value. 4. Control device according to one of the preceding claims, characterized it is not indicated that the bypass device interferes with the turbine (21) bypass channel (40) and one opening or closing the bypass channel (40) Includes valve (41). 5. Control device according to claim 4, characterized in that g e -k e n n z e i c Not that the device controlling the opening and closing of the bypass device a comparator (80) for comparing the sampled temperature of the converter (35) with the given temperature temperature value and a device (50.42; 81) for actuating the valve (41) as a function of the comparison result.