EP1655485A1 - Crankshaft locking arrangement - Google Patents

Abstract

The engine has a locking device (2) that is brought into engagement with a crankshaft during the leakage of the engine. The device has contact and holding units (3, 4), in which the contact unit is attached to the holding unit in a movable manner, such that the contact unit is connected with an opposite contact unit during last revolution of the crankshaft, and the crankshaft in its rest position is adjusted to a preset position.

Description

The invention relates to an internal combustion engine, which comprises a blocking device for a crankshaft, wherein the blocking device is brought into engagement with the crankshaft when the internal combustion engine is coasting.

To improve fuel economy in internal combustion engine vehicles, it is often shut down instead of idling when no drive power is needed. The internal combustion engine must then be restarted when its power is needed again. For starting, conventional internal combustion engines have special devices, such as a starter motor or a generator that can be used as a motor, a so-called starter generator. These are vefiältanmäßig large and expensive equipment, as for the starting of the engine high electrical power is required.

Moreover, it is known to start an internal combustion engine by triggering combustion. This is possible in particular with internal combustion engines with spark ignition and direct injection. The injected directly into a combustion chamber fuel is thereby ignited by a spark, and the subsequent combustion of the air-fuel mixture moves a piston and starts the engine, without the crankshaft would have to be moved by an additional starter device. However, such direct starting of the engine requires certain boundary conditions in order to be able to be carried out successfully. In particular, it is necessary or advantageous if the crankshaft is in or near a certain position at the start of cranking. Thus, at least one piston of a cylinder of the internal combustion engine should be in a position in which injecting fuel and then igniting the resulting air-fuel mixture actually leads to movement of the piston located in the cylinder. In a four-stroke internal combustion engine, the piston would therefore have to be in the expansion or power stroke, with at least one associated outlet gas exchange valve not yet allowed to be opened. This can for example be in a position of about 90 ° crank angle to top dead center (TDC). This is conventional Internal combustion engines usually not guaranteed because the crankshaft stops after stopping and running of the engine in random positions.

From EP 1 367 256 A1 a method for preparing the starting of an internal combustion engine, preferably an internal combustion engine with direct injection, known, the crankshaft is braked when the engine is running and / or actively rotated to assume a predetermined position in the parked state of the internal combustion engine , The braking and / or active rotation takes place by using a compressor of an air conditioner, by using a pump of a power steering, by using a camshaft adjusting device and / or by changing the volume work of the internal combustion engine. The shutdown of the internal combustion engine in a desired crankshaft angle range can be achieved for example by an additional electrical, hydraulic or mechanical deceleration device, such as an eddy current brake, which acts in a controlled manner on the crankshaft during the stopping of the internal combustion engine.

DE 198 35 045 A1 relates to a method for starting an engine comprising an engine block, a crankshaft rotatably mounted in the engine block, at least one piston rotatably connected to the crankshaft and movable in at least one cylinder in the engine block. The engine has at least one combustion chamber formed by a piston and the engine block.

In DE 198 35 045 A1 a method for direct start is described by way of example. It is a suitable combustion chamber, formed from cylinder and piston identified, which is located in the power stroke and contains enough air volume. Subsequently, a predetermined amount of fuel is injected and ignited.

From DE 198 35 045 A1 it is thus known to bring the internal combustion engine into a suitable position for direct starting, wherein the crankshaft is stopped in a desired position in addition to the active rotation by means of an electric motor when stopping by a suitable braking system. However, that goes DE 198 35 045 assumed that still a, albeit smaller dimensioned, starter is required for starting the internal combustion engine.

DE 100 30 001 A1 discloses a device or a method for the controlled shutdown of an internal combustion engine. In this case, at least one adjusting device can be activated, which is activated after the end of regular operation of the internal combustion engine and the crankshaft of the internal combustion engine and / or the camshaft of the internal combustion engine moves in a predeterminable angular position.

From DE 199 60 984 A1 discloses a method for the outlet control of an internal combustion engine is known, wherein the piston is brought into at least one cylinder of the machine in a targeted position corresponding to a lying clearly after the upper dead center angular position of the crankshaft. In this case, the gas outlet valves are closed by one or more cylinders of the internal combustion engine after switching off the ignition for one or more periods of time. The beginning and the end of each valve closing portion are controlled so that the crankshaft stops in a desired outlet position.

DE 31 17 144 A1, DE 199 47 784 A1, DE 199 55 857 A1, DE 100 20 104 A1, DE 101 11 928 A1 and DE 100 20 325 A1 each relate to a method for starting an internal combustion engine, wherein a separate Starter is omitted.

An unreleased disclosure going back to the Applicant relates to a blocking device for the crankshaft of an internal combustion engine. The blocking device is designed such that a rotational movement of the crankshaft is blocked in one and / or two directions. The blocking device can be realized for example by means of bolts and / or ratchet wheels or locking wheels, which engage in an associated gear of the crankshaft. Alternatively, such a blocking device may be provided by means of a friction device, which cooperates with the crankshaft. This embodiment has proven itself in practice, however, to start the engine continues to provide one, albeit a smaller, starter device.

Therefore, the invention has the object to provide an internal combustion engine of the type mentioned with an improved blocking device for a crankshaft available, which achieves a controlled shutdown of the engine with simple means.

This is achieved according to the invention in that the blocking device has an engagement element and a rigid holding elements, wherein the engagement element is movably associated with the holding element, so that the engagement element with a counter-engagement element associated with the crankshaft at a last crankshaft revolution is connectable such that the crankshaft in its rest position is adjustable in a predetermined position.

With the blocking device according to the invention it is achieved that at least one piston of the internal combustion engine are in a certain, favorable configuration, this specific configuration corresponding to one or a certain angular range or position of the crankshaft. Thus, an improved blocking device is provided with which it is possible to effect a starterless direct starting of the internal combustion engine, for example by fuel ignitions.

In order to achieve a form-locking engagement of the engagement element with the counter-engagement element, it is favorable in the context of the invention, when the engagement element is configured with a toothed engagement side, which is brought into engagement with the counter-engagement element in a radial direction relative to the crankshaft, wherein the counter-engagement element designed as a toothed engagement side complementary sprocket. The engagement element can be configured preferably quadrangular in cross section. The sprocket is arranged in a preferred embodiment directly on the crankshaft, but may also be arranged on a shaft connected to the crankshaft. This can also be, for example, an existing starter tooth ring. The engagement member blocks the crankshaft during its last revolution in the predetermined position corresponding to the desired crank angle range, the engagement element positioning the crankshaft in a fixed position relative to a crankshaft Crankcase abruptly blocked when the engagement element is engaged in the counter-engagement element. It is well within the meaning of the invention that the engagement element is hydraulically, mechanically, pneumatically and / or electrically actuated.

It is expedient for the purposes of the invention, when the engagement means in a circumferential direction with respect to an outer circumference of the crankshaft and the counter-engagement element is movably connected to the holding element, wherein the holding element has a corresponding guide means for the engagement element. This guide device may for example be a slotted guide, which is introduced into the holding element. Thus, the engagement element can be taken with the crankshaft in the circumferential direction until the engagement element reaches a stop end of the holding element. Therefore, it makes sense in the context of the invention, when the holding element has at least one stop end in the circumferential direction. Preferably, the stop end is arranged such that the crankshaft is adjustable in its rest position in the predetermined position, wherein the predetermined position is just the required crank angle range, which is necessary to ensure a starterless, direct starting of the internal combustion engine, wherein the at least one Piston is in a favorable position.

In order to achieve a smooth braking of the crankshaft during its last revolution, it is favorable if the engagement element is fastened to at least one force storage element, which is otherwise connected to the holding element. In a preferred embodiment, the energy storage element is designed as a spring, wherein the force storage element is first tensioned in the circumferential direction after engagement or after the engagement of the engagement element in the counter-engagement element until the engagement element strikes against the stop end, then according to a balance of the spring force in the predetermined position to be retrieved. Here, the energy storage element takes the engaged engagement means and thus the crankshaft. Of course, it is possible, seen in cross-section on both sides of the engagement element to provide one or more force storage elements, so that the engagement element is embedded in two or more springs. Due to the flexible storage of the blocking device, in particular the flexible extension of the springs, a very gentle engagement process is provided. After the engagement of the engagement element in the counter-engagement element, the springs are tensioned during the crankshaft revolution, wherein the crankshaft is then stored in the predetermined position, which is caused by the force equilibrium of the power storage elements.

In a further embodiment of the invention is advantageously provided that the retaining element is associated with a positioning ring which is movable via a positioning device in the circumferential direction, wherein the positioning ring has a stop end. Here, the positioning ring can be connected via the positioning device with the holding element, so that the positioning ring is displaceable in the circumferential direction. If the engagement element then engages in the counter-engagement element and abuts against the abutment end, the crankshaft is adjusted to the predetermined position by the action of the abutment end of the positioning ring via the circumferential displacement of the positioning ring. In this embodiment, the engagement member rotates with the crankshaft revolution until the engagement member abuts the abutment end, the crankshaft can of course stop automatically before the engagement member reaches the abutment end. An advantage of this design is that the abutment end can be arranged in an optimal position to ensure a smooth leakage of the internal combustion engine. After the crankshaft no longer rotates, the engagement member can be adjusted via the action of the positioning ring or the positioning device such that the crankshaft is mounted in the predetermined position. Of course, the positioning device can be operated electrically, hydraulically, mechanically or pneumatically. Of course, it can also be provided in this embodiment that the engagement element is provided with at least one energy storage, which is connected at the other end to the holding element.

In a further advantageous embodiment of the invention, it is expedient if the retaining element is associated with a positioning ring, in which the engagement element is integrated, wherein the positioning ring is movable via a positioning device in the circumferential direction. In this embodiment of the invention that is Engagement element disposed relative to the crankcase in a fixed position and engages in this fixed position in the counter-engagement element. Thus, the crankshaft is abruptly stopped again when the engagement element engages the counter-engagement element. By the positioning device, it is possible that an optimal locking or engagement position can be selected to ensure a smooth leakage of the internal combustion engine. After the crankshaft is stopped, it is moved by the engaging engagement member via the counter-engagement member in the predetermined position, so that a starterless, direct starting of the engine is possible.

Of course, it is within the meaning of the invention, when the engagement element or in the positioning integrated engagement element is controlled by a central engine control unit, which also controls the leakage of the engine to reach the appropriate predetermined position of the crankshaft to a direct, starterless Starting the internal combustion engine to achieve so that the at least one piston is in a favorable position for this purpose.

Fig. 1

Einen Querschnitt durch eine Kurbelwelle mit zugeordneter Blockiereinrichtung,

Fig. 2

einen Querschnitt durch die Kurbelwelle in Figur 1 mit einer Umfangsbewegung eines Eingriffselementes,

Fig. 3

einen Querschnitt durch eine Kurbelwelle mit der Blockiereinrichtung, der Kraftspeicherelemente zugeordnet sind,

Fig.4

einen Querschnitt durch eine Kurbelwelle mit einer Positioniervorrichtung, und

Fig. 5

einen Querschnitt durch eine Kurbelwelle mit einem in einem Positionierring integrierten Eingriffselement.

Further advantageous embodiments of the invention are disclosed in the subclaims and the following description of the figures, in which different embodiments of the invention are shown. Show it:

Fig. 1

A cross section through a crankshaft with associated blocking device,

Fig. 2

a cross section through the crankshaft in Figure 1 with a circumferential movement of an engagement element,

Fig. 3

a cross section through a crankshaft with the blocking device, which are associated with power storage elements,

Figure 4

a cross section through a crankshaft with a positioning device, and

Fig. 5

a cross section through a crankshaft with an integrated in a positioning engagement element.

In the different figures, the same parts are always provided with the same reference numerals, so that these are usually described only once. Figures 1 to 5 are not to scale, with distortions to a partially non-round in cross-section, and not lead to a round appearance, with a round in cross-section appearance of the following description is based.

FIG. 1 shows a crankshaft 1 of an internal combustion engine, not shown. The internal combustion engine has a blocking device 2 for the crankshaft 1. The blocking device 2 is brought into engagement with the crankshaft 1 when the engine runs out. The blocking device 2 has an engagement element 3 and a rigid holding element 4. The engagement element 3 is assigned to the holding element 4 such that the engagement element 3 can be connected to a counterengagement element 6 associated with the crankshaft 1 during a last crankshaft revolution in such a way that the crankshaft 1 can be adjusted in a predetermined position in its rest position. The predetermined position is defined in the context of the invention as a crank angle range in which a direct, starterless starting of the internal combustion engine is possible, wherein at least one piston is in a favorable position for this purpose.

The engagement element 3 is configured with a toothed engagement side 7 and is brought into engagement with the counter-engagement element 6 in a radial direction 8 with respect to the crankshaft 1, wherein the counter-engagement element 6 is configured as a toothed ring that is complementary to the toothed engagement side 7. The engagement element 3 can be configured preferably quadrangular in cross-section.

The counter-engagement element 6 is arranged directly on the crankshaft 1, wherein, of course, it is also conceivable that the counter-engagement element 6 is arranged on a shaft connected to the crankshaft 1.

The holding element 4 is connected to a non-rotatable motor element, preferably to an engine block. Of course, the retaining element 4 can be screwed frictional-locking with the motor element or produced directly in the manufacture of the motor element in one piece with this. In a preferred embodiment, the holding element 4 is arranged in an interior of the internal combustion engine, in particular in an interior of the engine block. Of course, the retaining element 4 can also be arranged outside of the engine block.

The holding element 4 is designed in cross-section similar to an armature of an electric motor and has at least one arranged in the circumferential direction stop end 9, wherein seen in cross-section opposing armature webs 11 of the holding element 4 in each case a quarter of the circumference of the crankshaft 1 and the counter-engagement element. 6 include.

The engagement element 3 is movably connected to the holding element 4 in the radial direction 8. For this purpose, a suitable guide device is provided on the holding element 4.

In the embodiment shown in Fig. 1, the engagement member 3 is disposed in a preferred stop position 12 which is selected such that the crankshaft 1 is stopped in the predetermined position when the engagement member 3 engages the counter engagement member 4.

The engagement member 3 is controlled via a central engine control unit, which preferably also controls the leakage of the engine so that it is abruptly connected to the counter-engagement means 6 during the leakage of the internal combustion engine, in particular in a last crankshaft revolution, so that a positive locking connection is made in the crankshaft 1 is stopped in the predetermined position. The engagement element 3 is hydraulically, mechanically, pneumatically and / or electrically actuated.

In contrast to the embodiment shown in Figure 1, the holding element 4 in the embodiment shown in Figure 2 a Guiding device for the engaging member 3, so that this s not only in the radial direction 8 but also in a circumferential direction 13 is movable. As a result, a smooth braking of the crankshaft can be achieved until reaching the desired stop position.

Due to the selected cross section, the guide device in Figure 2 is not visible. The engagement element 3 is controlled via the central engine control unit such that it is brought into engagement with the counter-engagement element 6 at an engagement point 14. The engagement point 14 is shifted in the embodiment shown in Figure 2 according to the example shown in Figure 1 counterclockwise about 30 ° from the zenith of the crankshaft 1, so that the engagement means 3 in the engaged state to the stop end 9 in the circumferential direction 13 accordingly the crankshaft revolution is taken. The arrangement of the abutment end 9 corresponds to a preferred stop position 16 or the predetermined position in which the crankshaft 1 is arranged in the crankshaft angle range, in which a direct, starterless starting of the internal combustion engine is possible.

In the exemplary embodiment illustrated in FIG. 3, the engagement element 3 is connected to two force storage elements 17, which are each fastened to the holding element 4 at the other end. The force storage elements 17 are configured in the illustrated embodiment as springs. Thus, a flexible blocking device 1 is provided, in which in particular the engagement element 3 is flexibly supported by the force storage elements 17 in the circumferential direction 13. FIG. 3 shows the engagement element 3 in an engaged, deflected state. In this case, both force storage elements 17 are biased.

After the engagement or engagement of the engagement element 3 in the counter-engagement element 6, upon reaching a crank angle position 18, the engagement element 3 has been taken in the circumferential direction 13 of the crankshaft 1 and the counter-engagement element 6, whereby the energy storage elements 17 are tensioned. As a result, a gentle deceleration of the crankshaft 1 is achieved, wherein the prestressed force storage elements 17 cause a return movement of the engagement element 3, so that the crankshaft 1 is approximately in the preferred Stop position 18 and the predetermined position is stored by the balance of power of the force storage elements 17.

In an exemplary embodiment illustrated in FIG. 4, the blocking device 2 is assigned a positioning ring 19, which can be moved in the circumferential direction 13 via a positioning device 21. Otherwise, the embodiment shown in Figure 4 corresponds to the embodiment of Figure 2, wherein one of the anchor webs 11 has been replaced by the positioning ring 19, wherein the positioning ring 19, a stop end 22 is associated. The positioning ring 19 is designed such that it comprises approximately one quarter of the circumference of the crankshaft 1 and the counter-engagement element 6. In the embodiment shown in Figure 4, the engagement member 3 rotates with the crankshaft 1 and the counter-engagement member 6 until the engagement member 3 abuts the abutment end 22, the crankshaft 1 and the counter-engagement member 6 of course automatically stopped shortly before the abutment end 22 can be. Advantageously, the positioning ring 19 can be adjusted so that it is arranged in an optimal position, so that the engine can smoothly leak. After the crankshaft 1 has been stopped, this can be adjusted by the action of the positioning ring 19 on the engaging member 3 in the predetermined position. For this purpose, the positioning ring 19 is simply rotated by means of the positioning device 21 in the circumferential direction 13 against the normal direction of rotation. The positioning device 21 is electrically, hydraulically, mechanically or pneumatically actuated, wherein the positioning ring 19 can of course also be configured with power storage elements according to the embodiment of Figure 3.

In contrast to the exemplary embodiment illustrated in FIG. 4, the engagement element 3 is integrated into the positioning ring 19 in the exemplary embodiment illustrated in FIG. Here, the engagement member 3 is arranged as in the embodiment shown in Figure 1 in a fixed position relative to the crankcase. Thus, the crankshaft 1 is abruptly stopped by engaging or engaging the engagement member 3 in the counter-engagement member 6, wherein the engagement or locking position can be selected such that a smooth leakage of the internal combustion engine is ensured. After the crankshaft 1 is stopped, it can be adjusted via the engagement member 3 and the acting positioning device 21 in the predetermined position.

Of course, instead of frictional connection and a frictional connection, not shown, of the engagement member may be provided with the Gegeneingriffseiement, which would then form accordingly. Of course, it is within the meaning of the invention that the engagement member 3 and the integrated in the positioning ring 19 engagement element 3 is ausgeüctct before starting the engine from the counter-engagement element 6, which in the figures 1 and 4 by way of example by means of the double arrow 8, the radial Direction 8 is shown. In all embodiments, an exemplary direction of rotation of the crankshaft 1 is indicated by the arrow 23.

Claims (7)

An internal combustion engine having a crankshaft blocking device (2), wherein the blocking device (2) is brought into engagement with the crankshaft (1) when the internal combustion engine is coasting,
characterized in that
the blocking device (2) has an engagement element (3) and a rigid holding element (4), wherein the engagement element (3) is movably associated with the holding element (4), so that the engagement element (3) with a counter-engagement element associated with the crankshaft (1) (6) is connectable at a last crankshaft revolution such that the crankshaft (1) is adjustable in its rest position in a predetermined position. Internal combustion engine according to claim 1,
characterized in that
the engagement element (3) is designed with a toothed engagement side (7) which is brought into engagement with the counter engagement element (6) in a radial direction (8) relative to the crankshaft (1), the counter engagement element (6) being intended to be toothed Engaging side (7) complementary sprocket is configured. Internal combustion engine according to claim 1 or 2,
characterized in that
the engagement means (3) is movably connected to the holding element (4) in a circumferential direction (13) relative to an outer circumference of the crankshaft (1), wherein the holding element (4) has a corresponding guide means for the engagement element (3). Internal combustion engine according to one of the preceding claims,
characterized in that
the holding element (4) in the circumferential direction (13) has at least one stop end (9). Internal combustion engine according to one of the preceding claims,
characterized in that
the engagement element (3) is attached to at least one force storage element (17) which is connected to the holding element (4) at the other end. Internal combustion engine according to one of the preceding claims,
characterized in that
the retaining element (4) is associated with a positioning ring (19) which is movable via a positioning device (21) in the circumferential direction (13), wherein the positioning ring (19) has a stop end (22). Internal combustion engine according to one of the preceding claims,
characterized in that
the retaining element (4) is associated with a positioning ring (19), in which the engagement element (3) is integrated, wherein the positioning ring (19) via a positioning device (21) is movable in the circumferential direction.

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