EP2032820A1

EP2032820A1 - Method and device for monitoring an exhaust-gas turbocharger

Info

Publication number: EP2032820A1
Application number: EP07729728A
Authority: EP
Inventors: Rudolf Bierl; Martin Lesser; Andreas Meyer; Frank Steuber
Original assignee: Continental Automotive GmbH
Current assignee: Continental Automotive GmbH
Priority date: 2006-06-13
Filing date: 2007-05-31
Publication date: 2009-03-11
Also published as: JP2009540207A; WO2007144274A1; US20100000309A1; DE102006027422A1; DE102006027422B4; CN101473122A; US8291752B2; KR20090027210A

Abstract

The present invention relates to a method and a device for monitoring an exhaust-gas turbocharger of an internal combustion engine. In order to create a cheap and also reliably operating method and a corresponding device for monitoring an exhaust-gas turbocharger, it is proposed that a sound transducer (5, 11) which is designed to record rotational-speed-dependent turbocharger operating noise is provided, which sound transducer (5, 11) is connected to an electronic system (10) for frequency analysis for the output of a turbocharger rotational speed signal (figure 1).

Description

description

Method and device for monitoring an exhaust gas turbocharger

The present invention relates to a method and an apparatus for monitoring an exhaust gas turbocharger of an internal combustion engine.

In a known manner is in internal combustion engines

Air-fuel mixture brought under compression to combustion. The power output of the internal combustion engine depends on the ratio of fuel mass to air mass. The measurement of a respective air mass is carried out with an air mass sensor which sits in the intake tract of the combustion ^¬ engine. Many modern Verbrennungskraftma ^¬ machines are now equipped with a turbocharger, which causes pre-compression of the air mass. Be ^¬ already at the beginning of the development of internal combustion engines, the attempt of precompression of an internal combustion engine air supplied with the aim of increasing the engine power by increasing the air flow and fuel flow per stroke performed, so today the charging of gasoline internal combustion engines is no longer primarily from the performance point of view, but as a way to save fuel and reduce pollutants. In a known manner, a respective exhaust gas stream is deprived of energy for pre-compression of the air mass flow through a turbine running in the exhaust gas stream with mechanically-coupled fresh air compressor, so that, for example, a diesel engine no longer acts as a naturally aspirated engine but as a supercharged engine with supercharged air pressures of up to 1.5 or 2.5 bar with significant increase in performance and reduced emissions.

By using a turbocharger on the one hand increases the torque of an internal combustion engine, on the other hand but also the thermal load of the internal combustion engine, which is why engine block, cylinder heads, cylinder head gaskets, bearings, cylinders, connecting rods, valves, pistons and other engine components and the subsequent drive train for this additional stress must be designed accordingly. The higher power also requires a correspondingly larger cooling system for cooling the engine and the La ^¬ deluft. However, with supercharged gasoline engines it is still frequently observed that exhaust gas turbines even become red-hot after driving under high load. Can ^¬ chen such a strong thermal and mechanical stress of a component, the rotational speeds of up to 200,000 revolutions per minute Errei, makes a separate monitoring. Because with the use of turbochargers in modern motor vehicles, a considerable amount of stimulation is still triggered, which complicates damage diagnosis. Modern fully ^¬ electronic diagnostic systems act here by evaluating the speed of a turbocharger to monitor its function supportive. To determine a turbocharger speed, however, an extra developed sensor is provided. This sensor must withstand extremely adverse conditions, in particular high temperatures and high pressures, reliably detecting the blades of the turbocharger wheel and calculating the speed signal with downstream electronics. This sensor must be mounted directly on the turbocharger.

With all the advantages, it is known as a disadvantage of a turbocharger that in a start-up / acceleration process as a transient operating state, a turbocharger can generate an insufficient boost pressure for the fresh air, so that a short-term negative pressure arises in the intake system. When accelerating from low speeds out first missing the right amount of exhaust gas to produce the desired boost pressure. Only with increasing speed, a sufficiently strong exhaust gas flow is provided to cause a charge to a required degree. This lack of power at low speeds is commonly referred to as a "turbo lag". Accordingly, the charging of the fresh air flow through the turbocharger begins with a sudden gas input delayed, since only a sufficient Abgasström must adjust. This peculiarity has been compensated in the past by appropriate control systems and by using smaller turbochargers to a part. As part of a new design approach using the planned 42 V electrical system could also be a combined charging by exhaust gas turbocharger and electric drive. This would additionally change the response positively. But even this approach requires for a control in real time a relatively accurate knowledge of a current turbocharger speed. This future control tasks can only be made using a monitoring of the exhaust gas turbocharger, which provides a turbocharger speed as an output signal.

It is therefore an object of the present invention to provide a price value and reliably operating method and a corresponding apparatus for monitoring a Abgasturbola ^¬ to provide id.

This task is solved by the features of the independent claims. Advantageous developments are the subject of the respective subclaims.

According to the invention an apparatus for surveil ^¬ distinguished monitoring an exhaust gas turbocharger is characterized in that it comprises a formed for receiving a speed-dependent turbocharger operating noise sound transducer which is connected to electronics for frequency analysis of the output of a turbocharger speed signal. The invention is therefore based on the finding that at operating speeds of 200,000 to about 400,000 revolutions per minute turbocharger equipped with up to 17 turbine blades in its normal operating speed range a very high-frequency operating noise emitted. This Betriebsge ^¬ is therefore commonly referred to as turbocharger whistling noise reduction. From one or more dominant frequencies within a sound spectrum emitted by a turbocharger, a respective current turbocharger speed can be determined. This is done for example in an electronics for frequency analysis, which then outputs a turbocharger speed signal.

A noise level of a present in the standard operating Turbola ^¬ DERS compared to other ambient noise inside a vehicle, is comparatively high. Because of the turbocharger resulting sound over long distances in particular ^¬ sondere in the intake tract without substantial attenuation propagates advantageously be must be provided according to the invention, transducer not attached itself directly to the turbocharger. Thus, a corresponding transducer is also not exposed to the known high temperatures and pressures in the turbocharger. Thus, according to the invention, less resistant and thus less expensive sound transducers with a lower operating temperature range, etc. can also be used.

In a particularly preferred embodiment of the invention, an ultrasonic transducer is used as a sound transducer. It has been found, the frequencies of an emitted by a turbocharger sound spectrum above the threshold of human hearing of about 16 kHz in Ultraschallbe ^¬ that are rich from 20 kHz, from which a respective current turbocharger speed is determined.

An electronics downstream of the sound transducer comprises a frequency analysis unit. This frequency analysis unit identi fied ^¬ preferably based on a fast Fourier transfor mation ^¬ or FFT, followed by band-pass filtering a frequency band of a supercharger operating noise and determines therefrom a respective current turbocharger speed. A turbocharger speed determination according to the invention is arranged in a particularly preferred embodiment of the present invention on the basis of a sound evaluation together with an air mass sensor in the intake of an internal combustion engine. An air mass sensor can work as a mass flow sensor according to a thermal principle, wherein a release of heat output of a heated sensor wire compared to a thermally insulated sensor wire is evaluated via a resistance bridge circuit as a measure of a respective flow rate. An alternative and electrical energy saving approach is generally described in the article "Flow Measurement - An Overview", in the journal "Technical Measurement tm", 1979, No. 4, pages 145-149. For this purpose, it is known to use a transmitting and a receiving ultrasonic measuring head for flow measurement. The two ultrasonic measuring heads serve as a transmitter and a receiver and require a transmitting / receiving device. Based on this, EP 0 535 364 A1 has disclosed, for example, a method for high-resolution flow velocity measurement by means of ultrasound, in which an ultrasound ^transmitter and an ultrasound receiver transmit sound pulses through a measuring tube at an angle of inclination to determine a phase difference dependent on a current flow velocity. Thus, already two ultrasonic transducers are used for air mass measurement in the intake use, and this assembly is completed in one embodiment of the invention by addition of a third ultrasonic transducer, said third ultrasonic transducer consistent, in terms of its operating frequency specific to the expected frequencies of the up abge operating ski turbocharger ^¬ is , Alternatively, a device with only two ultrasonic transducers can be provided, wherein the receiving ultrasonic transducer is designed so broadband that an air mass measurement is performed at a much higher frequency than the turbocharger speed measurement. Bandpass filtering separates the output of the Receiving ultrasonic transducer to each ^¬ Weil specifically supply the signal components of an air mass measurement and a speed determination in separate successor circuits.

Further features and advantages of the invention are given below ^¬ description with reference to two embodiments with Be ^¬ access to the figures of the drawing. In the drawing show:

Figure 1 is a block diagram of a device for measuring the speed of a turbocharger using two standard ultrasonic transducers of an ultrasonic air mass sensor and

2 shows a block diagram of a further embodiment for measuring the speed of a turbocharger and an ultrasonic air mass sensor when using an additional ultrasonic transducer with subsequent evaluation as a block diagram in a representation analogous to that of Figure 1.

Throughout the various exemplary embodiments and illustrations, the same reference numerals and designations are used for identical functional or assembly groups and method steps.

The figure of Figure 1 shows a simplified Blockdia ^¬ gram of a device 1 for measuring the speed of a symbolically reproduced exhaust turbocharger 2. This device 1 is arranged in an air inlet duct 3 of an internal combustion engine not shown and working ^¬ tet using two standardized Sound transducers 4, 5 of an ultrasonic air mass sensor 6.

The ultrasonic air mass sensor 6 operates in the present embodiment according to one disclosed in EP 0535364 Al publica ^¬ lished methods for determining an air mass in HO- flow velocities. For this purpose, sound waves 7 are emitted in the ultrasonic range of the first transducer 4 under control by an electronic unit 8. They pass through the through which a strong air flow, air intake passage 3 on a path α to increase the path length and thereby improving the measurement accuracy at an angle relative to the transverse sectional plane of the air inlet duct 3 ge ^¬ is prone. On the opposite side of the air inlet duct 3 ^¬ the sound waves 7 impinge on the second acoustic transducer 5, the received as the ultrasonic detector

Sound waves 7 converts into an electrical output signal ai. This electrical signal ai is returned to the electronics 8 for air mass measurement. For the implementation of the method in detail, the evaluation of the measurement results and the associated methods, reference is made in full to the teaching of EP 0 535 364 A1.

The receiving transducer 5 is designed very broadband in the ultrasonic range. Thus, the sound transducer 5 next to the sound waves emitted by the transducer 4 7 on the much lower frequency and yet located in the ultrasonic range sound waves 9 detect and convert, these sound waves 9 are generated by the operation of the turbocharger 2 and in their frequency characteristic of a respectively current turbocharger speed are. Accordingly, a respective measurement result of the second sound transducer 5 is evaluated in two ways below, as also indicated in the drawing: an output signal of the emp ^¬ scavenging transducer 5 is divided ai and a low frequency component of a ₂ to a higher frequency component. The ^¬ se shares ai, a ₂ are supplied to separate units for electrical processing. On the one hand, therefore, a much higher-frequency component, which has been emitted at a predetermined frequency by the first converter 4, is forwarded to the evaluation electronics 8 for determining an air mass. A comparatively low frequency and the turbo ^¬ loader 2 forth derived ultrasonic frequency portion is in the Signal component a ₂ for frequency analysis to an electronics 10 forwarded. A current turbocharger speed is determined by appropriate mathematical algorithms Filtermetho ^¬ and from the recorded frequency spectrum, a Fast-Fourier transformation is applied for determining a characteristic frequency of the turbocharger speed in the present case to a bandpass filtering. The downstream of the transducer 5 electronics 10 thus includes a frequency analysis unit for identifying a frequency band of a turbocharger operating ^noise and then on ^¬ building determining a respective current turbocharger speed as the output signal A.

Figure 2 shows a block diagram of another exemplary form for measuring the speed of a turbocharger and an ultra sound ^¬ air mass sensor. This device operates using an additional ultrasonic transducer 11 with subsequent evaluation electronics and is shown as a block diagram in a representation analogous to that of Figure 1. In the embodiment of Figure 2, the formed for receiving a speed-dependent turbocharger operating noise transducer 11 is provided as a separate component in the Lufteinlasska ^¬ nal. 3 Again, this is an ultrasonic transducer based on a piezoelectric material. However, compared to the sound transducer 5 of the exemplary embodiment according to FIG. 1, this sound transducer 11 is tuned comparatively narrowband in its operating frequency to the frequencies to be expected, which are caused by the respective operating speeds of the turbocharger 2. For voting estimate of a possible frequency range can range from speeds below 100,000 to about 450,000 revolutions per ^¬ Mi nute and more are expected 5 up to 17 turbo blades as. Thus, approximate frequencies of the fundamental frequencies from 8 kHz to more than 113 kHz and easily measurable harmonics, for example, at the third harmonic or three times the frequency of 24 kHz to 0.35 MHz are to be expected. As a nominal speed range and the number of turbo blades already Depending on the application, a more or less narrow-band range for the operating frequency of the sound transducer 5 can be selected in the mentioned lower ultrasonic range.

Compared to the first embodiment, Figure 2 this results in accordance with a certain apparatus additional effort by the provision of an additional separate sound transducer 11 in the air inlet duct 3, however, an overall simpler evaluation processing the electrical measurement signals, as in particular no Fre ^¬ quenzaufspaltung an output signal into two portions ai , a _{2 is to be} provided. Furthermore, the two ultrasonic transducers 3, 4 for the air mass measurement must have an operating frequency which is significantly above the operating frequency and thus, for example, also a center frequency of the ultrasonic transducer 11, which is provided for the turbocharger speed measurement.

Since the noise level of the turbocharger 2 is compared to jewei- time ambient noise is very high and is relatively dominant in particular in the ultrasonic range and the resulting noise also propagates over long distances in Ausaugtrakt 3 without we ^¬ sentliche attenuation of the ultrasound must air mass sensor 6 with its Sound transducers 4, 5 and provided in the second embodiment separate sound ^{¬ converter} 11 are not mounted directly on the turbocharger 3. Thus, a turbocharger speed sensing can be installed at that position at the well-known mass air flow sensors are installed. In this case, the ultrasonic sensors 4, 5, 11 generally have the advantage that they are comparatively insensitive to temperature, dirt and pressure, for example in quartz converter designs. In addition, such sensors are much cheaper to produce or available as standard components, as would be the case with a now to be saved turbocharger speed sensor known design.

Claims

claims

1. A device for monitoring an exhaust gas turbocharger of an internal combustion engine, since you rchgekennzeichnet that designed to accommodate a speed-dependent turbocharger operating noise trained transducer (5, 11) is connected to an electronics (10) for frequency analysis for outputting a turbocharger speed signal ,

2. The device according to claim 1, since there is no such that the sound transducer (5, 11) is designed to detect a turbocharger speed as an ultrasonic transducer

3. Device according to one of the preceding claims, since you rchgekennzeichnet that a the sound transducer (5, 11) downstream electronics (10) ne ne frequency analysis unit for identifying a Fre ^¬ quenzbandes a turbocharger operating noise and He ^¬ averaging each current turbocharger Speed includes.

4. Device according to one of the preceding claims, since there c h e c e n e c e s in that the sound transducer (11) is specially tuned to the frequency band of an expected turbocharger operating noise.

5. Device according to one of the preceding claims, since you rchgekennzeichnet that the sound transducer (4, 5, 11) of the device (1) in an air inlet duct (3) of the internal combustion engine is arranged.

6. A method for monitoring an exhaust gas turbocharger (2) of an internal combustion engine, since a speed-dependent operating noise of the turbocharger (2) is recorded by a sound transducer (5, 11) and evaluated in an electronic system (10).

7. The method according to the preceding claim, since you rchgekennzeichnet that the sound transducer (5, 11) is used in parallel as part of ei ^¬ nes air mass sensor.

8. The method according to any one of the preceding claims 6 or 7, since you rchgekennzeichnet that an output signal ^¬ a receiving transducer (5) in a higher-frequency component (ai) and a low-frequency component (a ₂ ) is divided and separate these shares Units are supplied for electrical processing.