EP1657418B1 - Internal combustion engine and method of stop position control - Google Patents

Description

The invention relates to an internal combustion engine with a crankshaft and a flywheel, which is arranged on the crankshaft.

Furthermore, the invention relates to a method for the controlled shutdown of such an internal combustion engine.

First, the two explicitly mentioned components of the internal combustion engine, namely the crankshaft and the flywheel, will be discussed before referring to the method and to devices for carrying out such a method.

The crankshaft of an internal combustion engine receives the connecting rod forces, which are composed of the gas forces due to the fuel combustion in the combustion chamber and the mass forces due to the non-uniform movement of the engine parts. In this case, the oscillating lifting movement, in particular of the pistons, is transformed into a rotating rotational movement of the crankshaft. The crankshaft transmits the torque to the drive and to the flywheel.

The crankshaft has a certain torsional elasticity and together with the hinged to them components, in particular the connecting rods and pistons, a vibratory system which can be excited by the acting on the crank pin gas and inertial forces to torsional vibrations.

To dampen the torsional vibrations, torsional vibration dampers can be provided. By a relative movement of the mass of the vibration damper to the crankshaft, a part of the torsional vibration energy is reduced by friction work.

To reduce the speed fluctuations, the mass of the described oscillatory system is increased by the arrangement of a flywheel on the crankshaft. Due to the larger mass, the system has increased inertia, which makes the system more insensitive to speed variations and makes the rotational motion of the crankshaft more uniform. The flywheel stores energy and transmits it to the crankshaft as the speed drops. Ie. the flywheel serving as an energy reservoir releases energy to the crankshaft as it decelerates, giving the crankshaft and the entire system a degree of inertia by attempting to counteract the deceleration and sustain movement by releasing energy. In this way, the flywheel acts both for accelerations and delays for a smooth and smooth running of the crankshaft and coupled to the crankshaft components.

Conveniently, the flywheel or the high mass therefore also affects misfires and misfires. Due to the inertia of the flywheel, the rotational motion of the crankshaft remains more or less uniform, i. the rotational movement is only slightly disturbed.

The flywheel can also be designed as a two-mass flywheel and then assumes the additional function of a vibration damper, which reduces the torsional vibrations between the clutch and the drive. In general, the flywheel is attached on one side to the crankshaft and connected on the other side via the clutch to the transmission. In the two-part flywheel usually the two disc-shaped parts are connected to each other by means of internal coil springs.

According to the prior art, the crankshaft and the flywheel are manufactured as separate independent components and then screwed together during assembly ie inextricably linked. For this purpose, both components have flanges and arranged in the flanges slugs or holes.

A method for the controlled shutdown of an internal combustion engine generally follow the reduction of the fuel consumption of the internal combustion engine. Due to the limited resources of fossil fuels, in particular due to the limited mineral oil reserves as a raw material for the production of fuels for the operation of internal combustion engines, the development of internal combustion engines is constantly striving to minimize fuel consumption. On the one hand, the improved i.e. more effective combustion in the forefront of the effort. On the other hand, certain strategies with regard to the basic operation of the internal combustion engine can also be effective.

One concept for improving the fuel consumption of a vehicle is, for example, to switch off the internal combustion engine - instead of continuing to run it in the leelauf - when there is no momentary power requirement. In practice, this means that at least when the vehicle is stationary, the internal combustion engine is turned off. One application is the stop-and-go traffic, as it sets, for example, in traffic jams on highways and highways. In inner-city traffic, stop-and-go traffic is no longer the exception, but the rule, as a result of the existing and non-coordinated traffic lights. Other applications provide limited level crossings and the like.

The problem with the concepts, which turn off the engine in case of lack of demand to improve fuel economy, is the need to restart the engine. The restart is problematic because when the internal combustion engine stops uncontrolled, the crankshaft and the camshaft come to a standstill in any and also unknown position. Consequently, the position of the pistons in the individual cylinders of the internal combustion engine is also not known and left to chance. However, this information is essential for an uncomplicated and as fast as possible and thus fuel-saving restart.

In an internal combustion engine, which is equipped with an electronically controlled ignition and / or electronically controlled injection, deliver at the Crankshaft arranged markers Signals about the crank angle position on connected to the engine control sensors for controlling the ignition and the injection timing. But to generate these signals, it is first necessary to put the crankshaft in rotation. Immediately at the beginning of the restart and the start in general, there is uncertainty about the correct injection and ignition timing, so that a run-in phase for the synchronization of the crank angle position on the one hand and the engine operating parameters on the other hand is required. In addition, devices for starting or restarting the internal combustion engine must be provided, for example, a conventional starter or a similar device which is adapted to forcibly set the crankshaft in rotation, such as an electric motor.

To simplify the restart, various concepts are proposed in the prior art.

The German Offenlegungsschrift DE 42 30 616 For example, suggests to store the angular position of the crankshaft, which is registered at shutdown and to use for the restart, so that the appropriate ignition timing and injection timing are immediately available. However, this approach has not proven in practice, since the stored information about the position of the crankshaft are too inaccurate.

Other approaches prefer methods for controlled shutdown and starting of the internal combustion engine. Controlled parking consists in deliberately approaching certain crank angle positions - so-called preferred positions - when the internal combustion engine is switched off. The end position of the crankshaft is no longer left to chance and more or less accurately registered, but it will be specifically brought about for the restart advantageous crank angle positions.

In internal combustion engines with direct injection, it is possible with appropriate crank angle even without starter to start directly from standstill or restart. This fuel is directly in the combustion chambers of the stationary Internal combustion engine is injected and ignited by means of a spark plug, so that the explosion of the air-fuel mixture brings the pistons in motion, whereby the crankshaft is rotated.

However, this type of starting or restarting requires compliance with certain boundary conditions. In particular, as already mentioned, the crankshaft must be in a specific position or in a specific crank angle range. In this respect, especially for internal combustion engines with direct injection method for controlled parking targets.

A method for the controlled shutdown of an internal combustion engine, for example, in the WO 01/48373 disclosed. The WO 01/48373 teaches the application of a method in which after switching off, ie after completion of the regular operation of the internal combustion engine, an adjusting device is activated and controlled, with which the crankshaft and / or the camshaft is moved to a predeterminable advantageous angular position. Both active and passive adjustment devices can be used.

As an active adjusting device can serve an electric motor which transmits a torque to the crankshaft and this rotates after switching off the internal combustion engine in the desired position, which is then maintained until the restart of the internal combustion engine. In the WO 01/48373 also active adjusting devices are described which have means for activating the injection and ignition of the internal combustion engine after completion of their regular operation. These means are used to selectively initiate combustion processes in the cylinders, with which a certain torque is transmitted to the crankshaft, so that a predetermined advantageous crank angle position can be approached.

Passive adjustment but can according to the WO 01/48373 also be used, these passive adjusting devices after completion of the regular operation of the internal combustion engine exploit the still existing in the wake of the crankshaft rotary motion and influence in the way that the Crankshaft comes to a standstill in the predetermined advantageous crankshaft position. As a passive adjustment means are proposed, for example, include a gas exchange valve control, which transmits a suitable braking brake torque to the engine or crankshaft, so that the delay of the shaft and thus its end position is controllable.

The in the WO 01/48373 indicated adjusting devices are not suitable to control the end position of the crankshaft with the necessary accuracy. In addition, the active adjustment either make additional components - such as possibly not yet existing electric motors - required for applying a Verstelldrehmomentes, or they work as in the initiation of targeted combustion processes for starting the predetermined crank angle position by means of an additional fuel injection and ignition. Especially the latter method, which requires the use of fuel, is in sharp contrast to the fundamental goal of switching off the internal combustion engine, namely to save fuel by switching off the engine and thus to optimize the fuel consumption of a vehicle. But the use of an electric motor is not effective in this aspect, since the energy needs of the electric motor adversely affects the overall efficiency of the engine, which is also in contradiction to the actual objective to optimize the efficiency through fuel economy.

Compared to the active adjusting the passive adjusting devices have the advantage that their energy consumption is usually lower and acceptable also with regard to the underlying task value, since the passive adjustment devices do not initiate a rotational movement of the crankshaft, but in principle only one Delay existing rotational movement of the crankshaft in a suitable manner.

A method for the outlet control of an internal combustion engine, in which specifically the gas exchange valves of the internal combustion engine for controlling the Preferred items are used in the WO 01/44636 A2 described. By suitable control, ie by suitably opening and closing the gas exchange valves, influence is thereby exerted on the combustion chamber pressure and thus on the torque exerted by the gas forces on the piston and the connecting rod on the crankshaft. However, this method requires an internal combustion engine which has an at least partially variable valve control. In addition, a complex and therefore complex control is required.

The German Offenlegungsschrift DE 101 23 037 A1 mentions a dual mass flywheel in the context of a method for controlled shutdown of an internal combustion engine, according to DE 101 23 037 A1 the shutdown is preferably carried out in the way that the dual mass flywheel is excited as little as possible to vibrate, so in particular the resonance frequency of the dual mass flywheel is bypassed.

Against this background, it is the object of the present invention to provide an internal combustion engine according to the preamble of claim 1 d. H. provide the generic type, with the targeted - after stopping the engine - an advantageous for the restart of the engine, predefinable end position of the crankshaft can be approached and with a restart is possible, which is characterized in particular by low energy consumption, according to overcome the known disadvantages of the prior art.

Another object of the present invention is to provide a method for the controlled shutdown of such an internal combustion engine.

The first sub-task is solved by an internal combustion engine with a crankshaft and a flywheel, which is arranged on the crankshaft, and which is characterized in that the flywheel for controlled stopping and starting of the internal combustion engine has a variable flywheel mass.

With flywheel mass is basically referred to in the context of the present invention, the total mass of the flywheel. On the other hand, in embodiments which have a modular flywheel, with flywheel mass, the mass of at least one fixed d. H. permanently connected to the crankshaft flywheel component referred. Such embodiments will be described in more detail below.

The flywheel mass has a significant influence on the outflow of the crankshaft, i. on the rotational movement of the crankshaft after stopping the engine and thus to the end position of the crankshaft. After switching off the ignition and / or the fuel supply, the rotational movement of the crankshaft is significantly determined by the inertial forces that result from the delay of the individual engine parts, such as the pistons and the connecting rods, and in particular by the delay of the flywheel.

By varying the mass of the flywheel, the moment of inertia of the flywheel is varied and the inertial forces or the attacking moment of inertia acting on the flywheel as a result of the deceleration during the outflow process are influenced.

In the internal combustion engine according to the invention, the mass of the flywheel can be selectively increased and decreased. If this happens in the appropriate manner, the internal combustion engine can be turned off in a controlled manner d. H. The completed after switching off the ignition and / or the fuel supply from the crankshaft to its standstill rotational movement is delayed by means of the variation of the flywheel mass in such a way that the crankshaft is stopped in a predeterminable position. The operation of the device in detail will be described in more detail in connection with the method according to the invention.

The internal combustion engine according to the invention also allows a simple and fuel-efficient restart, since the crankshaft can be stopped selectively in a so-called preferred position, ie in a crank angle range for the start of the internal combustion engine is to be regarded as advantageous. Thus, a gasoline engine with direct injection can be started directly from standstill by injection of fuel into the cylinder and ignition of the injected fuel.

The flywheel mass can be minimized for the start or restart of the internal combustion engine, whereby the required starting energy is reduced to a minimum. After the successful starting process, the flywheel mass is then on the normal d. H. regular operation of the internal combustion engine necessary size increased or adjusted.

The inventively proposed variation of the flywheel mass or the variable flywheel mass can basically be regarded as a passive adjustment in which by suitable variation of the flywheel mass due to the changed moment of inertia of the flywheel not constant torque is exerted on the crankshaft to the crankshaft - preferably in the desired Preferred position - comes to a standstill.

As will be seen below, embodiments of the internal combustion engine are possible in which the inventively proposed variation of the flywheel mass can also serve as an active adjustment, wherein the crankshaft is brought in a multi-stage process in a desired preferred position.

Furthermore, the kinetic energy stored in a flywheel component decoupled from the crankshaft may, under certain circumstances, be used for a restart, which will be explained in more detail in the context of the preferred embodiments.

With the flywheel a basically already existing component of the internal combustion engine is used to accomplish a controlled shutdown. The provision of additional adjustment is not required. Especially no active adjustment device, such as an electric motor, as the WO 01/48373 proposes to be provided to turn the crankshaft in the desired position after switching off the internal combustion engine. There are only means for varying the flywheel mass required.

With the internal combustion engine according to the invention, the first object of the invention is thus achieved, namely to provide an internal combustion engine, with the targeted - after stopping the engine - an advantageous for the restart of the engine, predefinable end position of the crankshaft can be approached and with a reboot is possible, which is characterized in particular by a low energy consumption, wherein the known prior art disadvantages are overcome.

Further advantageous embodiments of the internal combustion engine are discussed in connection with the subclaims.

Embodiments of the internal combustion engine in which the flywheel is a continuous d are advantageous. H. has continuously variable flywheel mass. A continuously variable flywheel mass ensures the highest degree of flexibility when parking the internal combustion engine and starting up the so-called preferred positions. In particular, a continuously variable flywheel mass increases the accuracy with which the preferred positions can be approached.

A continuously variable flywheel mass, for example, be realized in that a hollow flywheel body is provided, which can be filled with liquid, such as water. By introducing additional liquid into the hollow body, the flywheel mass is increased, whereas by discharging liquid contained in the hollow body, the mass of the flywheel is reduced.

Embodiments of the internal combustion engine in which the flywheel is modularly constructed from at least two flywheel segments are advantageous connectable to each other and are detachable, so that the flywheel mass is at least two stages changeable, wherein at least one flywheel segment is non-detachably connected as a base segment with the crankshaft. In this case, the at least two flywheel segments can be positively or positively connected to each other.

The mass of the base segment is to a certain extent the smallest flywheel mass to be realized, the maximum flywheel mass being realized by connecting all flywheel segments.

Embodiments of the internal combustion engine in which the at least two flywheel segments are designed in the form of flywheel disks which are connectable to one another and detachable from one another by axial displacement in the direction of the longitudinal axis of the crankshaft are advantageous.

The two last-mentioned embodiments divide the flywheel and thus the flywheel mass into at least two or a multiplicity of individual partial masses, which can be connected to one another or separated from one another. Thus, these embodiments not only allow a change in the moment of inertia of the flywheel for controlled deceleration of the crankshaft to its standstill, as is done in principle with passive adjusting devices.

As already mentioned above, the inventively proposed variation of the flywheel mass with a suitable embodiment of the internal combustion engine or the flywheel can also serve as an active adjusting device. The division of the flywheel mass into a plurality of individual masses which can be detached from one another is an example of such an embodiment, wherein the crankshaft is brought into a desired preferred position in a multi-stage process.

In this case, the rotating crankshaft is delayed in a first step by suitable replacement of individual flywheel segments of the base segment and the Brought to a standstill. In the context of the first step, the variable flywheel mass thus acts as a passive adjusting device, wherein the detachment of the flywheel segments before the standstill of the crankshaft, so that the detached flywheel segments, regardless of the rotational movement of the crankshaft and the delay of this rotational movement to move further, in particular can rotate , In a second step, the detached flywheel segments and the kinetic energy stored in them are used to move the crankshaft to a predeterminable advantageous angular position, for which purpose the flywheel segments detached from the base segment are partially or completely connected in a suitable manner to the base segment. In this case, the variable flywheel then serves as an active adjusting device, but in contrast to the known from the prior art active adjustment no external power supply needed. The energy required to adjust the crankshaft comes from the detached flywheel segments or flywheel disks.

Furthermore, the kinetic energy stored in a flywheel member detached from the crankshaft or base segment may be used for a restart.

If the internal combustion engine as a result of a momentary lack of power - off, for example, on a red light system - instead of idle continue to operate, the moment of inertia of the flywheel is controlled by detachment of individual flywheel segments controlled by the base segment in such a way after switching off the ignition and / or fuel the crankshaft comes to a standstill in a predeterminable position, preferably in a preferred position.

If the traffic light system then changes to green, a restart can be initiated by means of the previously detached flywheel segments or the kinetic energy stored in these segments by connecting the detached and further rotating segments to the base segment, thereby rotating the crankshaft.

• ■ das Schwungrad zum kontrollierten Abstellen der Brennkraftmaschine mit einer veränderbaren Schwungradmasse ausgebildet wird, und
• ■ beim Abstellen der Brennkraftmaschine nach Abschalten der Zündung und/oder der Kraftstoffzufuhr die Masse des Schwungrades verändert wird, so daß die Trägheit d.h. das Trägheitsmoment des Schwungrades variiert wird, wodurch auf die Auslaufbewegung der Kurbelwelle Einfluß genommen wird.

The second sub-task on which the invention is based, namely a method for the controlled shutdown of an internal combustion engine which has a crankshaft and a flywheel arranged on this crankshaft, is achieved by a method in which

• ■ the flywheel is designed for controlled shutdown of the internal combustion engine with a variable flywheel mass, and
• ■ When switching off the internal combustion engine after switching off the ignition and / or the fuel supply, the mass of the flywheel is changed, so that the inertia ie the moment of inertia of the flywheel is varied, whereby the outflow movement of the crankshaft influence is taken.

In normal driving, the flywheel preferably receives its maximum mass to minimize the speed fluctuations as much as possible.

The statements made in connection with the internal combustion engine according to the invention also apply to the method according to the invention, which is why reference is made at this point to the statements made with respect to the internal combustion engine.

The method according to the invention is based on the fact that the outflow process of the crank mechanism, which takes place after the combustion processes taking place in the combustion chambers of the internal combustion engine, is decisively determined by the inertia forces and moments of inertia which occur as a result of the deceleration of the individual engine parts. It is therefore proposed according to the invention to exert influence on the inertia or mass of an engine part in order to control or control the outflow of the crankshaft. As an engine part is used due to the relatively large mass arranged on the crankshaft flywheel.

• ■ die Masse des Schwungrades in der Art verändert wird, daß die nach Abschalten der Brennkraftmaschine bis zu ihrem Stillstand abgegebene kinetische Energie kontrolliert in der Weise abgebaut wird, daß die Kurbelwelle in einer vorbestimmbaren Position angehalten wird.

Advantageous embodiments of the method, in which

• ■ The mass of the flywheel is changed in such a way that the delivered after switching off the internal combustion engine to its standstill kinetic energy is reduced in a controlled manner in such a way that the crankshaft is stopped in a predeterminable position.

• ■ die Kurbelwelle in einer Vorzugsposition angehalten wird.

In particular, embodiments of the method are advantageous in which

• ■ the crankshaft is stopped in a preferred position.

This embodiment of the method is advantageous because starting a preferred position is favorable for a restart.

When the crankshaft is in a preferred position, there is clarity at the beginning of the re-start about the correct injection timing and ignition timing, so that a run-in phase for the synchronization of the engine operating parameters is not required. A fast and therefore fuel-efficient restart is possible.

Such a method allows, for example, in internal combustion engines with direct injection starting without starter d. H. to start directly from standstill, for which only fuel injected into the combustion chambers of the stationary internal combustion engine and must be ignited by means of a spark plug.

However, in order to precisely approach a certain preferred position of the crankshaft, but a lot of information is necessary. In this case, all data already measured and / or derived for the usual engine control can be used, in particular the engine speed, the crankshaft angle, the engine temperature or a temperature correlated therewith, such as the coolant temperature and / or the intake pressure in the intake manifold. Experience has shown that the variables mentioned have the strongest influence on the outflow movement of the internal combustion engine or the crankshaft.

In connection with the variation of the flywheel mass according to the invention, it is necessary to determine how much kinetic energy is present after switching off the internal combustion engine in the drive train in order to control the outflow movement of the engine Crankshaft can be influenced by changing the moment of inertia of the flywheel targeted.

A model for the discharge movement of the internal combustion engine is described for example in the European patent application with the application number 03101379.0. This model takes into account the actual kinetic energy of the drive train, the friction losses and / or the compression and expansion processes in the cylinders of the internal combustion engine. Such a model can be obtained on the basis of theoretical considerations and implemented in the form of mathematical equations. Preferably, however, the model is obtained entirely or at least partially empirically. D. H. by observing the engine behavior and processing the measured data obtained (eg as a look-up table).

• ■ das Schwungrad modular aus mindestens zwei Schwungradsegmenten, die miteinander verbindbar und voneinander lösbar sind, aufgebaut wird und von denen mindestens ein Schwungradsegment als Basissegment mit der Kurbelwelle unlösbar verbunden wird, und
• ■ die Trägheit d. h. das Trägheitsmoment des Schwungrades durch das Trennen der mindestens zwei Schwungradsegmente verkleinert bzw. durch das Verbinden der mindestens zwei Schwungradsegmente vergrößert wird, wodurch die Auslaufbewegung der Kurbelwelle verkürzt bzw. verlängert wird.

Advantageous embodiments of the method, in which

• ■ the flywheel is constructed modularly from at least two flywheel segments, which are connectable and detachable from each other, and of which at least one flywheel segment is non-detachably connected as a base segment to the crankshaft, and
• The inertia ie the moment of inertia of the flywheel is reduced by the separation of the at least two flywheel segments or increased by the connection of the at least two flywheel segments, whereby the outflow movement of the crankshaft is shortened or lengthened.

• ■ mindestens ein Schwungradsegment vor dem Stillstand der Kurbelwelle von dem Basissegment getrennt wird, und
• ■ falls sich die Kurbelwelle bei Stillstand nicht in einer Vorzugsposition befindet, die kinetische Energie des mindestens einen abgetrennten Schwungradsegmentes dazu genutzt wird, die Kurbelwelle in eine Vorzugsposition zu drehen, wozu das Basissegment durch erneutes Verbinden mit dem mindestens einen abgetrennten Schwungradsegment beschleunigt wird und die Kurbelwelle in Drehung versetzt wird.

In this case, embodiments of the method are advantageous in which

• ■ at least one flywheel segment is disconnected from the base segment before the crankshaft stops, and
• ■ If the crankshaft is not in a preferred position at standstill, the kinetic energy of the at least one separated flywheel segment is used to rotate the crankshaft in a preferred position, including the base segment by again Connecting with the at least one separated flywheel segment is accelerated and the crankshaft is rotated.

In this variant of the method, the position of the crankshaft is actively and passively influenced as part of a multi-stage process d. H. the flywheel segments previously detached from the base segment as part of the passive deceleration process are used after initial standstill of the crankshaft by reconnecting these segments to the base segment to re-rotate the crankshaft and move it to a preferred position. If necessary, this method can be repeated if there is no preferred position of the crankshaft after acceleration and retardation of the crankshaft.

• ■ mindestens ein Schwungradsegment vor dem Stillstand der Kurbelwelle von dem Basissegment getrennt wird, und
• ■ die kinetische Energie des mindestens einen abgetrennten Schwungradsegmentes dazu genutzt wird, die Brennkraftmaschine erneut zu starten, wozu das Basissegment durch erneutes Verbinden mit dem mindestens einen abgetrennten Schwungradsegment beschleunigt wird, um die Kurbelwelle in Drehung zu versetzen.

Also advantageous in this context are embodiments of the method in which

• ■ at least one flywheel segment is disconnected from the base segment before the crankshaft stops, and
• The kinetic energy of the at least one separated flywheel segment is used to restart the engine, for which purpose the base segment is accelerated by reconnecting to the at least one separated flywheel segment to rotate the crankshaft.

After the successful start of the internal combustion engine possibly detached or separated flywheel segments are connected to the base segment for the regular operation of the internal combustion engine.

Fig. 1

schematisch Kurbelwelle und Schwungrad einer ersten Ausführungsform einer Brennkraftmaschine in einer ersten Momentaufnahme, und

Fig. 2

schematisch Kurbelwelle und Schwungrad der in Figur 1 dargestellten Ausführungsform der Brennkraftmaschine in einer zweiten Momentaufnahme.

In the following the invention with reference to an embodiment according to the FIGS. 1 and 2 described in more detail. Hereby shows:

Fig. 1

schematically crankshaft and flywheel of a first embodiment of an internal combustion engine in a first snapshot, and

Fig. 2

schematically crankshaft and flywheel of in FIG. 1 illustrated embodiment of the internal combustion engine in a second snapshot.

FIG. 1 schematically shows a crankshaft 1 and a flywheel 4 of a first embodiment of an internal combustion engine.

The flywheel 4 is modularly constructed from two flywheel segments 2, 3, wherein the two flywheel segments 2, 3 are designed in the form of flywheel disks 2, 3, which are connectable to one another and detachable from one another. The first flywheel segment 2 is permanently connected to the crankshaft 1 and serves as a base segment 8. The illustrated embodiment allows a step-shaped variation of the flywheel mass between a minimum flywheel mass, which is determined by the mass of the base segment 8, and a maximum flywheel mass, resulting from the Sum of the two flywheel discs 2.3 results.

The first flywheel disc 2 inevitably takes on the rotational movement of the crankshaft 1 about the axis of rotation 7 d. H. in the deceleration and acceleration of the crankshaft 1, while the second flywheel mass 3 can be separated from the base segment 8 or connected to the base segment 8.

The inertia or the moment of inertia of the flywheel 4 is reduced by the separation of the second flywheel disk 3 or increased by connecting the second flywheel disk 3 with the base segment 8, whereby the outflow movement of the crankshaft 1 is shortened or extended.

The second flywheel disk 3 is thereby connected to the base segment 8 by axial displacement in the direction of the longitudinal axis 6 of the crankshaft 1 (see FIG FIG. 2 ) or detached from the base segment 8 (see FIG. 1 ). For this purpose, a thread 5a is provided on the outer circumferential surface of the crankshaft 1, which adjoins the base segment 8 in the direction of the longitudinal axis 6. The second Flywheel segment 3 has on the inside of a bore via a thread 5b corresponding to this thread 5a, wherein both threads 5a, 5b are not in engagement with each other when the second flywheel segment 3 is detached from the base segment 8 and spaced apart.

In the FIG. 1 shown snapshot shows a flywheel 4, in which the second flywheel disc 3 is separated from the base segment 8 and consequently there is no connection or coupling between the second flywheel disk 3 and the crankshaft 1. In this respect, the mass of the second flywheel disk 3 also has no influence on the outlet movement of the crankshaft 1. Only the inertial forces and moments acting on the base segment 8 influence the rotational movement of the crankshaft 1.

The stored in the detached second flywheel segment 3 kinetic energy can be used in many ways. A stalled crankshaft 1 can be rotated by connecting the two segments 2,3 again. In this way, the crankshaft 1 can be actively rotated or moved to a preferred position.

The kinetic energy of the detached segment 3 can also be used for a restart of the internal combustion engine, which also takes place by connecting the previously detached flywheel segment 3 with the base segment 8 fixedly arranged on the crankshaft 1.

FIG. 2 schematically shows the crankshaft 1 and the flywheel 4 in FIG. 1 illustrated embodiment of the internal combustion engine in a second snapshot. It should only the differences to the in FIG. 1 discussed snapshot are discussed, which is why otherwise reference is made to FIG. 1 , The same reference numerals have been used for the same components.

In contrast to FIG. 1 is at the in FIG. 2 shown snapshot the second flywheel segment 3 connected to the base segment 8.

In this case, the provided on the outer circumferential surface of the crankshaft 1 thread 5a in engagement with the corresponding thread 5b of the second flywheel segment 3. In this way, the second flywheel segment 3 is carried along by the rotating crankshaft 1, whereby the two flywheel segments 2,3 connected to each other are. The crankshaft 1 serves in this embodiment as a connecting element of the two segments 2,3.

reference numeral

1

crankshaft

2

first flywheel segment, first flywheel disk

3

second flywheel segment, second flywheel disk

4

flywheel

5a

Thread on the crankshaft

5b

Thread on the second flywheel segment

6

Longitudinal axis of the crankshaft, rotation axis

7

free shaft end

8th

base segment

Claims (10)

1. Internal combustion engine having a crankshaft (1) and a flywheel (4) which is arranged on the crankshaft (1), characterized in that the flywheel (4) has a variable flywheel mass for the controlled shutting down and starting of the internal combustion engine.
2. Internal combustion engine according to Claim 1, characterized in that the flywheel (4) has a flywheel mass which can be varied continuously, i.e. in an infinitely variable fashion.
3. Internal combustion engine according to Claim 1, characterized in that the flywheel (4) is constructed in a modular fashion from at least two flywheel segments (2, 3) which can be connected to one another and detached from one another so that the flywheel mass can be varied at least in two stages, in which case at least one flywheel segment (2) is nondetachably connected to the crankshaft (1) as a basic segment (8).
4. Internal combustion engine according to Claim 3, characterized in that the at least two flywheel segments (2, 3) are embodied in the form of flywheel disks (2, 3) which can be connected to one another and detached from one another by axial displacement in the direction of the longitudinal axis (6) of the crankshaft (1).
5. Method for the controlled shutting down of an internal combustion engine which has a crankshaft (1) and a flywheel (4) which is arranged on this crankshaft (1), characterized in that

   • the flywheel (4) is designed to shut down the internal combustion engine in a controlled fashion with a variable flywheel mass, and

   • when the internal combustion engine is shut down after the ignition and/or the fuel supply has been switched off, the mass of the flywheel (4) is changed so that the inertia, i.e. the moment of inertia, of the flywheel (4) is varied, as a result of which the coasting movement of the crankshaft (1) is influenced.
6. Method according to Claim 5, characterized in that

   • the mass of the flywheel (4) is changed in such a way that the kinetic energy which is emitted after the internal combustion engine has been switched off, until it comes to a standstill, is reduced in a controlled fashion such that the crankshaft (1) is stopped in a predeterminable position.
7. Method according to Claim 6, characterized in that

   • the predeterminable position is a preferred position and the crankshaft (1) is stopped in this preferred position.
8. Method according to one of Claims 5 to 7, characterized in that

   • the flywheel (4) is constructed in a modular fashion from at least two flywheel segments (2, 3) which can be connected to one another and detached from one another, and at least one flywheel segment (2) of which is nondetachably connected to the crankshaft (1) as a basic segment (8), and

   • the inertia, i.e. the moment of inertia, of the flywheel (4) is decreased by the separation of the at least two flywheel segments (2, 3) and respectively increased by the connection of the at least two flywheel segments (2, 3), as a result of which the coasting movement of the crankshaft (1) is shortened and respectively prolonged.
9. Method according to Claim 8, characterized in that

   • at least one flywheel segment (3) is separated from the basic segment (8) before the crankshaft (1) comes to a standstill, and

   • if the crankshaft (1) is not in a preferred position when it comes to a standstill, the kinetic energy of the at least one separated flywheel segment (3) is utilized to rotate the crankshaft (1) into a preferred position, for which purpose the basic segment (8) is accelerated by connecting it again to the at least one separated flywheel segment (3) and the crankshaft (1) is made to rotate.
10. Method according to Claim 8 or 9, characterized in that

    • at least one flywheel segment (3) is separated from the basic segment (8) before the crankshaft (1) comes to a standstill, and

    • the kinetic energy of the at least one separated flywheel segment (3) is utilized to start the internal combustion engine again, for which purpose the basic segment (8) is accelerated by connecting it again to the at least one separated flywheel segment (3) in order to make the crankshaft (1) rotate.

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