WO2018033276A1 - Connection rod for an internal combustion engine with a variable compression - Google Patents

Abstract

The invention relates to a connection rod (1) for an internal combustion engine with a variable compression, comprising a connection rod body (2) with at least one connection rod eye (3), a connection rod cover (6), and an eccentric adjusting device (4) for adjusting an effective connection rod length (5). The eccentric adjusting device (4) is arranged in the connection rod body (2) and has an eccentric (10) which interacts with at least one lever (7, 8). The eccentric (10) can be pivoted about the eccentric rotational axis, and the at least one lever (7, 8) is connected to a guide pin (21) arranged in the connection rod eye (3). The eccentric adjusting device (4) comprises a pivot motor (11) which has a rotor (13) mounted in a stator (12). The connection rod eye (3) of the connection rod body (2) is groove-shaped with a pin-guiding section (36) between the two end sections (38, 39), and the guide pin (21) is movably guided in the pin-guiding section.

Description

 Connecting rod for a variable compression internal combustion engine

Technical area

The invention relates to a connecting rod for an internal combustion engine with variable compression, in particular of a motor vehicle, with an eccentric adjusting device for adjusting an effective connecting rod length, and an internal combustion engine with variable compression with a connecting rod.

State of the art

In internal combustion engines, a high compression ratio has a positive effect on the efficiency of the internal combustion engine. Under compression ratio is generally understood the ratio of the entire cylinder space before compression to the remaining cylinder space after compression. However, in internal combustion engines with spark ignition, in particular gasoline engines, which have a fixed compression ratio, the compression ratio may only be selected so high that a so-called "knocking" of the internal combustion engine is avoided during full load operation low cylinder filling, the compression ratio with higher values are selected without a "knocking" would occur. The important part load range of an internal combustion engine can be improved if the compression ratio is variably adjustable. To adjust the compression ratio For example, systems with variable connecting rod length known which actuate by means of hydraulically or mechanically actuated changeover valves an eccentric adjusting device of a connecting rod.

A generic connecting rod is known for example from WO 2013/092364, which discloses a length-adjustable connecting rod for a reciprocating engine, in particular an internal combustion engine, with at least a first and a second rod part, which two rod parts telescopically zoom in and / or into each other. The second rod part forms a guide cylinder and the first rod part a longitudinally displaceable in the guide cylinder piston member. Between the first and the second rod part a high-pressure chamber is spanned, in which at least one first oil passage opens, in which at least one valve designed as a control valve is arranged, the actuator by a return spring in a first position and by oil pressure against the force of the return spring in a second position is displaced.

In contrast, WO 2010/108582 A1 discloses a connecting rod, in which an actuating device is arranged in the upper connecting rod eye. The actuator may also be placed on a central rod of the connecting rod and form the first connecting rod as the first connecting rod. The lower connecting rod eye is formed with the center rod of the connecting rod as a second connecting rod element. The connecting rod eye is the part of the connecting rod in which the piston pin is mounted. The actuating device comprises an eccentric, which carries the piston pin and is pivotally mounted in the upper connecting rod eye. The actuating device also comprises an actuating element, which can cause a pivoting of the eccentric about the central axis of the upper connecting rod eye. The piston pin is arranged eccentrically on the eccentric, and a pivoting of the eccentric about the central axis of the upper connecting rod causes a displacement of the piston pin along a circular path about this axis. The actuating element is designed as a swivel motor. Disclosure of the invention

An object of the invention is to provide a low-cost, improved connecting rod for a variable compression internal combustion engine with a robust and reliable adjustment mechanism having low space requirements.

Another object is to provide an internal combustion engine with such a connecting rod.

The above objects are achieved according to one aspect of the invention with the features of the independent claims.

Favorable embodiments and advantages of the invention will become apparent from the other claims, the description and the drawings.

It is proposed a connecting rod for an internal combustion engine with variable compression, comprising a Pleuelkörper with at least one connecting rod, a connecting rod cover, and an eccentric adjusting device for adjusting an effective connecting rod length, wherein the eccentric adjusting device is arranged in the Pleuelkörper and one with at least one lever having cooperating eccentric. An adjustment of the eccentric adjusting device is adjustable by means of a switching valve. The eccentric is pivotable about its axis of rotation and the at least one lever is connected to a guide pin arranged in the connecting rod. The eccentric adjusting device comprises a pivoting motor, which has a rotor mounted in a stator, between at least one rotor blade of the rotor and at least one stator stator of the stator at least a first support chamber and at least one second support chamber are formed, wherein a volume of the first support chamber and a Volume of the second support chamber by an adjustment of rotor against stator complementary to each other are variable. The connecting rod eye of the connecting rod body is groove-shaped with a bolt guide portion between two End portions formed and the guide pin is provided guided therein movable.

The connecting rod function is based on the principle known in the art and is operated by mass forces and gas forces, check valves and a mechanical or hydraulic switching valve in two positions for high compression (Ehigh) and low compression (£ | _0W ). According to the invention, the eccentric / lever connection of a conventional connecting rod of a variable compression internal combustion engine with its cylindrical support chambers, pistons, and support rods is replaced by a swivel motor system in the connecting rod body.

The check valves are integrated as well as the switching valve in a connecting rod cover. A large connecting rod bearing has a groove in the lower part for the hydraulic fluid supply, in particular with engine oil, the adjustment system. The small connecting rod eye of the connecting rod body is not cylindrical, but instead has a groove shape. In this groove-shaped connecting rod eye of the guide pin is movably guided. In the position for low compression (£ | _0W ) there is a defined stop between guide pin and connecting rod body. Even in the position for high compression (Ehigh) a defined stop on the contact between guide pin and connecting rod body is ensured.

The stator of the swing motor, for example, with two stator blades forms in combination with the rotor with two rotor blades four support chambers, which are separated from each other by the rotor blades and the stator vanes. The swivel motor can be designed in three parts with an additional stator cover, which is separately welded to the connecting rod body or otherwise joined.

The rotor is rotatably mounted in the stator. The chambers are sealed by sealing strips against each other and with piston rings to the outside. The introduction of the torque to the swing motor via a bolt which is placed in an eccentric bore of the rotor. Two levers connect the bolt with the guide pin, which in turn is arranged in the groove-shaped connecting rod eye. The guide pin receives a piston pin in a bore. By introducing a moment on the rotor, for example via external inertial forces, the effective connecting rod length can be varied.

Advantages of the connecting rod according to the invention include the fact that the connecting rod can also be operated with a hydraulic changeover valve. Further, the connecting rod, which is the interface to the pistons of an internal combustion engine, compared to a connecting rod according to the prior art only slightly modified. The Pleuelkörper is easy and inexpensive to edit, since a complex processing of cylindrical support chambers in the connecting rod body deleted. The connecting rod assembly is very compact in space and has a low total weight. The connecting rod assembly consists of very few individual components and assembly steps and is therefore well suited for mass production.

Due to the feasibility of larger swivel angle of the rotor, a lower eccentricity in the rotor can be selected for the same adjustment length of the connecting rod, so as to keep the maximum hydraulic pressures in the support chambers of the slewing motor low.

The use of the defined stops prevents unintentional striking of the rotor blades on the stator and thus represents a protective mechanism for the swivel motor system. The use of the defined stops also makes it possible to relieve the adjustment mechanism at maximum loads, in the position for low compression (£ | _0W ) with maximum gas force and in the high compression position (£ _high ) with high mass force, and thus prevents the occurrence of high pressure surges in the support chambers, since the forces can be absorbed by the connecting rod body.

The high number of degrees of freedom, such as swivel angle, eccentricity, rotor diameter, number of vanes for adapting the system to the internal combustion engine provides a valuable advantage of the connecting rod according to the invention represents.

Due to the additional mass on the eccentric (lever, pin bearing) can advantageously be adjusted faster via the mass force. These inertial forces counteract the ignition of the gas force, especially at top dead center, and reduce the force to be effectively supported on the eccentric. This allows more efficient switching of £ | _0W to Ehigh done. The load on the connecting rod is lower overall.

The use of non-cranked lever eccentric adjustment device facilitates the processing and is also feasible in cheaper serial production.

A continuous lubrication of the bearing point of the guide pin in the groove-shaped connecting rod eye can be easily realized by the resulting cavity via two holes in the connecting rod. It can be used advantageous oil of the existing piston lubrication.

In a further advantageous embodiment, the swivel motor system can be replaced by an eccentric and the eccentric torque can be intercepted via a further pair of levers in a linear movement. The linear movement allows the use of a double acting support piston or two separate support pistons. The necessary piston guide can be accommodated in the connecting rod body. The advantage over a double-acting piston is the additional use of an eccentric, which conducts most of the load in the Pleuelkörper and only supports the adjusting torque of the eccentric on an oil column. This results in much lower pressures in the support chambers.

According to an advantageous embodiment of the bolt guide portion may be formed at least partially with straight bolt guide surfaces. In this way, the guide pin in the connecting rod along the bolt guide portion perform a linear movement, which is a favorable Changing the connecting rod length for a change in the compression of the internal combustion engine can be achieved.

According to an advantageous embodiment of the eccentric can be arranged in the rotor of the rotary motor and actuated by the rotor. This makes it possible to achieve a very compact design of the connecting rod. Also, the power transmission is given directly from the swing motor to the eccentric. The eccentric adjustment device can be operated very efficiently and compactly.

According to an advantageous embodiment, at least one hydraulic fluid line for supplying hydraulic fluid into the first support chamber of the swing motor and at least one hydraulic fluid line for supplying hydraulic fluid into the second support chamber of the swing motor may be provided in the connecting rod body. The hydraulic fluid can be advantageously fed directly to the support chambers of the swing motor. The connecting rod body is simple and inexpensive to machine to produce the hydraulic fluid lines. The connecting rod assembly can be done in simple and few assembly steps.

According to an advantageous embodiment, at least one stop for limiting an axial movement of the guide pin may be provided in the connecting rod body, wherein in particular the respective end portion of the connecting rod end forms the stop. Advantageously, an upper stop and a lower stop can be provided in the connecting rod eye. As a result, the forces acting on the connecting rod gas forces and mass forces are not derived through the rotor blades of the swing motor, but can be passed through the stops directly into the connecting rod body, which can reduce the possible material load and the consequent wear. The eccentric adjusting device can be relieved in this way and effectively protected against premature failure.

According to an advantageous embodiment, the first and / or the second support chamber by at least one on a running surface of the rotor and / or a Tread of the stator arranged sealing strip against each other to be sealed. By such, in particular axial sealing strips, the individual support chambers can be effectively sealed against each other. Thereby, the operation of the swing motor can be ensured low.

According to an advantageous embodiment, the first and / or the second support chamber may be sealed against an environment by at least one sealing element arranged at least partially on an outer circumference of the rotor and / or an inner circumference of the stator. By such, in particular all-round sealing elements, the individual support chambers can be effectively sealed against leakage to the outside. Thereby, the operation of the swing motor can be ensured low.

According to an advantageous embodiment, the stator can have on at least some regions at least two radial circumferential grooves on an outer circumference for supplying the first and the second support chamber with hydraulic fluid. By the circumferential grooves, the hydraulic fluid can be conveniently passed into the support chambers without additional hydraulic fluid lines must be present. Thus, the swing motor can be operated safely and the risk of inadequate supply of hydraulic fluid can be prevented.

According to an advantageous embodiment, the at least one rotor blade can be fastened to the rotor. The rotor can comprise several individual parts. For example, in a built rotor, the rotor blades may be screwed or pressed.

 As a result of such a modular construction of the rotor with attachable rotor blades, the pivoting motor can be manufactured and assembled at a favorable price overall. It is also possible to use identical parts for different types of swivel motors with a different number of rotor blades, as a result of which the cost of the swivel motor can be advantageously influenced.

According to an advantageous embodiment, the swivel motor can be at least two Have rotor blades and two stator blades, which are each spaced apart by an equal angular distance with respect to a rotational axis of the pivot motor. The swivel angle can be chosen so low through a different design of the swing motor via a different number of support chambers. In addition, for example, advantages for the support surface can be achieved. Also, a smaller eccentricity can be selected in the rotor so by the feasibility of larger swivel angle, for example, for the same adjustment length of the connecting rod, which can favorably influence the maximum hydraulic pressures in the support chambers.

According to an advantageous embodiment, a gap for lubrication may be provided between connecting rod and guide pin. In this way, the bearing point between connecting rod eye and guide pin can be conveniently supplied with hydraulic fluid, in particular with engine oil for effective lubrication, which can reduce the wear on guide pin and connecting rod advantageously.

According to an advantageous embodiment, at least one check valve can be provided in the hydraulic fluid line between the first support chamber and a supply connection and / or at least one check valve in the hydraulic fluid line between the second support chamber and the supply connection. The check valves may advantageously be arranged so that only hydraulic fluid can flow from the supply port into the respective support chamber, and not vice versa. Thus, the supply of the support chambers can be done very effectively with hydraulic fluid.

Advantageously, in this embodiment, the switching valve and the at least one check valves may be arranged in the connecting rod cover. In particular, in each case one check valve can be provided in each of the two hydraulic fluid lines between the two support chambers and the supply connection, which can be arranged with the changeover valve in the connecting rod cover. As a result, the connecting rod can be constructed very compact. Next, the function of Changeover valve and check valve in the connecting rod cap must be tested separately before installation and checked for possible leakage. As a result, quality assurance in production can be improved favorably.

According to an advantageous embodiment, a groove for supplying the changeover valve with hydraulic fluid from the supply connection may be provided on a circumference of a Hublagerauges arranged at least partially in the connecting rod cover at least in the region of the connecting rod cover. About the groove, the supply of the support chambers of the swing motor can be ensured with hydraulic fluid in a suitable manner. The stroke bearing eye must be weakened in this way as little as possible by a hydraulic fluid line mechanically in its structure, which has a favorable effect on the life.

According to an advantageous embodiment, the eccentric adjusting device can be driven by mass forces and gas forces of an internal combustion engine. A rotation of the adjustable eccentric adjusting device is initiated by the action of mass and gas load forces of the internal combustion engine, which act on the eccentric adjusting device at a power stroke of the internal combustion engine. During a power stroke, the directions of action of the forces acting on the eccentric adjusting device change continuously. The rotary movement or adjusting movement is assisted by one or more hydraulic fluid, in particular engine oil, imparted rotor blades arranged in the swivel motor, or the rotor blades prevent the eccentric adjusting device from returning due to varying directions of force acting on the eccentric adjusting device.

According to another aspect of the invention, a variable compression internal combustion engine with a connecting rod is proposed. The connecting rod may be formed as described above with a pivot motor for driving the eccentric adjusting device, in particular the guide pin via an eccentric with levers. This can advantageously achieve a more stable and cheaper operation of the internal combustion engine. In particular, you can Torque and power curve of the internal combustion engine and consumption and exhaust emissions of the engine are favorably influenced.

Brief description of the drawings

Further advantages emerge from the following description of the drawing. In the drawings, an embodiment of the invention is shown schematically. The drawings, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

They show by way of example:

Figure 1 shows a connecting rod according to the invention in an exploded view.

Fig. 2, the connecting rod of Fig. 1 in the position for high compression (£ _high ) in

 Side view with marked section plane A-A;

Fig. 3 the connecting rod of Figure 2 in plan view.

Fig. 4 shows the connecting rod of Fig. 2 in longitudinal section A-A in Fig. 2 with

 Section plane B-B with enlarged section Z;

FIG. 5 shows the connecting rod according to FIG. 2 in longitudinal section B-B in FIG. 4 with cut planes C-C and D-D with enlarged section Y; FIG.

Fig. 6 shows the connecting rod of Fig. 2 in longitudinal section C-C in Fig. 5 with enlarged

Section X; the connecting rod of Figure 2 in longitudinal section DD in Figure 5 with enlarged section W. the connecting rod of Figure 2 in a part of a further longitudinal section with enlarged section V. the connecting rod of Figure 2 in a part of a further longitudinal section with enlarged section Q;

FIG. 10 shows the swivel motor in the enlarged section Z in FIG. 4; FIG. Fig. 1 1, the pivot motor in the enlarged section X in Fig. 6;

FIG. 12 shows the swivel motor in the enlarged section W in FIG. 7; FIG.

FIG. 13 shows the switching valve in the enlarged detail Y in FIG. 5; FIG.

Fig. 14, the switching valve and a check valve in the enlarged

 Section V in Fig. 8;

Fig. 15 the changeover valve and the other check valve in the enlarged section Q in Fig. 9;

Fig. 1 6 the connecting rod of Fig. 1 in the position for low compression (£ | _0W ) in

 Side view with marked section plane A-A;

Fig. 17 the connecting rod of Figure 16 in plan view.

FIG. 18 shows the connecting rod according to FIG. 16 in a longitudinal section AA in FIG. 16 with a section plane BB drawn in with an enlarged section Z; FIG. the connecting rod of Figure 1 6 in longitudinal section BB in Figure 18 with drawn cutting planes CC and DD with enlarged section Y; the connecting rod of Figure 1 6 in longitudinal section CC in Figure 19 with an enlarged section X; the connecting rod of Figure 1 6 in longitudinal section DD in Figure 19 with an enlarged section W. the connecting rod of Figure 16 in a part of a further longitudinal section with enlarged section V. the connecting rod of Figure 16 in a part of a further longitudinal section with enlarged section Q; the swing motor in the enlarged section Z in Fig. 18; the swing motor in the enlarged section X in Fig. 20;

FIG. 26 shows the swivel motor in the enlarged section W in FIG. 21; FIG.

FIG. 27 shows the switching valve in the enlarged section Y in FIG. 19; FIG.

Fig. 28, the switching valve and a check valve in the enlarged

 Section V in Fig. 22; and

FIG. 29 shows the switching valve and the other non-return valve in the enlarged section Q in FIG. 23. Embodiments of the invention

In the figures, the same or similar components are numbered with the same reference numerals. The figures are merely examples and are not intended to be limiting.

Figure 1 shows the connecting rod 1 according to the invention in an exploded view, while in the figures 2 to 9 different longitudinal sections of the connecting rod 1 in the position for high compression (£ _high ) are shown. FIGS. 10 to 12 show corresponding longitudinal sections of the swivel motor 11 in an enlarged section, while FIGS. 13 to 15 show corresponding longitudinal sections of the reversing valve 9 and the check valves 18 in an enlarged section.

In Figures 1 6 to 23, the corresponding longitudinal sections of the connecting rod 1 in the position for low compression (£ | _0W ) are shown. Figures 24 to 26 show corresponding longitudinal sections of the pivot motor 1 1 in an enlarged section, while in Figures 27 to 29 corresponding longitudinal sections of the switching valve 9 and the check valves 18 are shown in enlarged section.

The connecting rod 1 for an internal combustion engine with variable compression comprises a Pleuelkörper 2 with a connecting rod 3 and a connecting rod cover 6. An eccentric adjusting device 4 for adjusting an effective connecting rod 5 is disposed in the Pleuelkörper 2 and has one with at least one, preferably two levers. 7 , 8 cooperating eccentric 10 on. An adjustment of the eccentric adjusting device 4 is adjustable by means of a switching valve 9, wherein the eccentric 10 is pivotable about its axis of rotation and the at least one lever 7, 8 is connected to a guide pin 21 arranged in the connecting rod 3.

The eccentric adjusting device 4 has a swivel motor 1 1, which has a rotor 13 mounted in a stator 12, wherein between at least one rotor blade 14 of the rotor 13 and at least one stator blade 15 of the stator 12th at least one first support chamber 1 6 and at least one second support chamber 17 are formed. A volume of the first support chamber 1 6 and a volume of the second support chamber 17 are mutually variable by an adjustment of the rotor 13 against the stator 14.

The connecting rod 3 of the connecting rod 2 is not cylindrical, but groove-shaped with a bolt guide portion 36 between two end portions 38, 39 is formed. The guide pin 21 is movably guided therein. The bolt guide portion 36 is formed with straight bolt guide surfaces. In this way, the guide pin 21 in the connecting rod 3 along the pin guide portion 36 perform a linear movement, whereby a change in the effective connecting rod length 5 can be achieved for a change in the compression of the internal combustion engine. The effective connecting rod length 5, as shown in Figure 3, the distance between the center of the connecting rod 3 and the center of the Hubageres 19. Between connecting rod 3 and guide pin 21 is a gap 34 for lubrication during movement of the guide pin 21 in the pin guide portion 36th intended. In this way, the guide pin 21 can be lubricated advantageous, which reduces the abrasion during movement and thus increases the life of the connecting rod 1.

As can be seen in particular in FIGS. 10 to 12 in the position for low compression (| _0W ) and in the position for high compression ( _{high high} ) in _FIGS. 24 to 26, the stator 12 of the swivel motor 1 1 forms formed with two stator blades 15, in combination with the rotor 13 with two rotor blades 14 four support chambers 1 6, 17, which are separated from each other by the rotor blades 14 and the stator 15. The swivel motor 1 1 can also be designed in three parts with an additional stator cover, which is welded separately to the connecting rod 2 or otherwise joined. The rotor blades 14 can also be fastened to the rotor 13 - for example screwed - be formed.

The stator 12 is inserted with the rotor 13 in the Pleuelkörper 2 and welded, for example, on the front side. In the illustrated The stator 12 has on its outer circumference 54 at least partially two radial circumferential grooves 22, 23, each having two inlet bores 24, 25 to the support chambers 1 6, 17 and the connection between the support chambers 16, 17 and supply and discharge lines 31, 32 to the hydraulic fluid supply in the connecting rod body 2 ensure.

The swing motor 1 1, as shown in the embodiment, at least two rotor blades 14 and two stator blades 15 which are each spaced apart by a same angular distance with respect to a rotation axis of the swing motor 1 1. In a further embodiment, however, the swivel motor 1 1 may also have three rotor blades 14 and three stator blades 15 or alternatively only one rotor and one stator blades 14, 15.

The rotor 13 is rotatably supported in the stator 12. The support chambers 1 6, 17 are sealed by sealing strips 26, 27 against each other and with sealing elements 28, 29 in the form of piston rings to the outside. The first and the second support chamber 1 6, 17 are so sealed by the arranged on a running surface 44 of the rotor 1 3 and a tread 46 of the stator 12 sealing strip 26, 27 against each other. The first and the second support chamber 1 6, 17 are further sealed by the partially disposed on an outer periphery 50 of the rotor 13 and an inner periphery 52 of the stator 12 sealing element 28, 29 against the environment.

The introduction of the torque on the pivot motor 1 1 via a pin 30 which is placed in an eccentric bore of the rotor 13. The eccentric 10 is arranged in the rotor 13 of the swing motor 1 1 and actuated by the rotor 13. As can be seen, for example, in FIGS. 3 and 9, two levers 7, 8 connect the bolt 30 to the guide pin 21, which in turn is arranged in the groove-shaped connecting rod eye 3. The guide pin 21 receives a piston pin in a bore. By introducing a moment on the rotor 13, for example via external inertial forces, the effective connecting rod length 5 can thus be varied. The bolt 30 is as in Figures 1 and in particular in the figures 10 to 12 can be seen, designed as a bolt with an internal bore to accommodate advantageous bending moments and to save weight. Alternatively, however, the bolt 30 may also be formed of solid material.

Due to the inventive use of a swing motor 1 1 for the eccentric adjusting device 4 otherwise conventional telescopic rods in the connecting rod omitted, which advantageously the weight of the connecting rod can be reduced, so that the mass distribution is displaced in the connecting rod towards Hublagerauge 19, whereby less oscillating masses in Crankshaft of the internal combustion engine are present. This in turn has a positive effect on the comfort of the internal combustion engine, since vibrations can be reduced or do not arise.

The connecting rod function is based on the principle of a variable compression connecting rod known in the art and is operated via mass forces and gas forces, check valves 18 and the mechanical or hydraulic changeover valve 9 in two high compression (Ehigh) and low compression (£ | _0W ) positions , The eccentric adjusting device 4 is driven by the mass forces and gas forces of the internal combustion engine. About the swing motor 1 1, the positions of the connecting rod for low compression (£ | _0W ) and high compression (£ high) can be locked and so set the effective connecting rod length 5 for this operation of the internal combustion engine.

For driving the swivel motor 1 1, at least one check valve 18 is provided in the hydraulic fluid line 31 between the first support chamber 16 and a supply port and at least one check valve 18 in the hydraulic fluid line 32 between the second support chamber 17 and the supply port. The check valves 18 are integrated into the connecting rod cover 6 as well as the switching valve 9, which is designed mechanically here, as can be seen in FIGS. 4 and 18.

The large connecting rod bearing as a crank bearing eye 19 preferably has a groove 20 in the lower part for the oil supply of the system, which has advantages in terms the bearing load. As can be seen in FIG. 1, the groove 20 for supplying the switching valve 9 with hydraulic fluid from the supply connection is provided on a circumference of the lifting bearing eye 19 arranged at least partially in the connecting rod cover 6, at least in the region of the connecting rod cover 6. A groove for supplying the Schenkmotors 1 1 with hydraulic fluid can be omitted so that the carrying capacity of the Hublagerauges 19 can be favorably influenced.

As can be seen in particular in Figures 4 and 18, is located in the position for low compression (£ | _0W) a defined stop 42 between guide pin 21 and connecting rod body 2 before. Even in the position for high compression (Ehigh) a defined stop 40 is ensured via the contact between guide pin 21 and connecting rod 2, in particular, the respective end portion 38, 39 of the connecting rod 3, the stop 40, 42 forms. The use of the defined stops 40, 42 prevents unintentional striking of the rotor blades 14 on the stator 12 and thereby represents a protective mechanism for the swing motor system 1 1. The use of the defined stops 40, 42 also allows relief of the adjustment mechanism 4 at maximum loads , in the position for low compression (£ | _0W ) with maximum gas force and in the position for high compression (Ehigh) with maximum mass force, and thus prevents the occurrence of high pressure surges in the support chambers 1 6, 17, as the forces Pleuelkörper 2 can be intercepted.

In the figures 13 to 15, and 27 to 29 are longitudinal sections of the switching valve 9 and the check valves 18 for the high compression positions (£ _high ), and low compression (£ | _0W ) shown in enlarged section.

The switching valve 9 shown in Figure 13, as a switching element on a pickup 60, which can lock by means of a connecting rod 6 arranged in the latching element 62 in two locking positions 64 to control the hydraulic flow for the two positions of the connecting rod 1. The locking element 62, shown in the Embodiment, a ball is biased by a spring element 66, for example a compression spring. The lateral movement of the tappet 60 is limited by a positioning element 68 guided in a recess 72. The tappet 60 has flow holes 70, which open the hydraulic fluid lines 31, 32 depending on the position of the tappet 60 a hydraulic fluid flow. In the high compression position (Emgh), as shown in Fig. 15, for example, the hydraulic fluid passage 32 is opened, while in the low compression position (£ | _0W ), as shown in Fig. 28, the hydraulic fluid passage 31 is opened. The other hydraulic fluid line 31, 32 is then closed in each case.

FIGS. 14 and 15, or 28 and 29, also show the corresponding non-return valves 18 in an enlarged section. In the hydraulic fluid line 31 between the first support chamber 1 6 of the swing motor 1 1 and the supply port, a check valve 18 and in the hydraulic fluid line 32 between the second support chamber 17 of the swing motor 1 1 and the supply port, a further check valve 18 is provided. The check valve 18 in each case comprises a valve body 80, in which the closing element 82, in the embodiment, a ball, is guided. The closing element 82 is prestressed with a spring element 84, for example a compression spring, and pressed into a valve seat (not illustrated). The closing element 82 closes a hydraulic fluid line 56, or 58, which is in hydraulic communication with the supply connection, or the groove 20 in the lifting eye 19. In this way, the connected support chambers 1 6, 17 of the swing motor 1 1 can be conveniently filled with hydraulic fluid, the check valves 18 each prevent the corresponding support chamber 16, 17 is at least partially emptied during filling by flowing back the hydraulic fluid.

Claims

claims

1 . Connecting rod (1) for a variable compression internal combustion engine, comprising

a connecting rod body (2) with at least one connecting rod eye (3),

 a connecting rod cover (6),

 - An eccentric adjusting device (4) for adjusting an effective connecting rod length (5),

 wherein the eccentric adjusting device (4) is arranged in the connecting rod body (2) and has an eccentric (10) cooperating with at least one lever (7, 8), wherein a displacement path of the eccentric adjusting device (4) by means of a switching valve (9) is adjustable,

 wherein the eccentric (10) is pivotable about its axis of rotation and the at least one lever (7, 8) is connected to a guide pin (21) arranged in the connecting rod eye (3),

 wherein the eccentric adjusting device (4) comprises a swivel motor (1 1) which has a rotor (13) mounted in a stator (12), wherein between at least one rotor blade (14) of the rotor (13) and at least one stator wing (15 ) of the stator (12) at least a first support chamber (16) and at least one second support chamber (17) are formed, wherein a volume of the first support chamber (1 6) and a volume of the second support chamber (17) by an adjustment of rotor (13 ) are mutually variable against stator (14),

 wherein the connecting rod eye (3) of the connecting rod body (2) is groove-shaped with a bolt guide portion (36) between two end portions (38, 39) and the guide pin (21) is movably guided therein.

2. Connecting rod according to claim 1, wherein the bolt guide portion (36) is formed at least partially with straight bolt guide surfaces.

3. Connecting rod according to claim 1 or 2, wherein the eccentric (10) in the rotor (13) of the swivel motor (1 1) is arranged and actuated by the rotor (13).

4. Connecting rod according to one of the preceding claims, wherein in the Pleuelkörper (2) at least one hydraulic fluid line (31) for supplying hydraulic fluid into the first support chamber (1 6) of the pivot motor (1 1) and at least one hydraulic fluid line (32) for supplying Hydraulic fluid in the second support chamber (17) of the pivot motor (1 1) are provided.

5. Connecting rod according to one of the preceding claims, wherein in the Pleuelkörper (2) at least one stop (40, 42) for limiting an axial movement of the guide pin (21) is provided, in particular the respective end portion (38, 39) of the connecting rod ( 3) forms the stop (40, 42).

6. Connecting rod according to one of the preceding claims, wherein the first and / or the second support chamber (1 6, 17) by at least one on a running surface (44) of the rotor (13) and / or a running surface (46) of the stator (12 ) arranged sealing strip (26, 27) are sealed from each other.

7. Connecting rod according to one of the preceding claims, wherein the first and / or the second support chamber (1 6, 17) by at least one at least partially on an outer circumference (50) of the rotor (13) and / or an inner circumference (52) of the stator (12) arranged sealing element (28, 29) are sealed against an environment.

8. Connecting rod according to one of the preceding claims, wherein the stator (12) on an outer circumference (54) at least partially at least two radial circumferential grooves (22, 23) for supplying the first and the second support chamber (1 6, 17) with hydraulic fluid.

9. Connecting rod according to one of the preceding claims, wherein the at least one rotor blade (14) to the rotor (13) is fastened.

10. connecting rod according to one of the preceding claims, wherein the pivot motor (1 1) at least two rotor blades (14) and two stator blades (15) which are each spaced by an equal angular distance with respect to a rotation axis of the pivot motor (1 1).

1 1. Connecting rod according to one of the preceding claims, wherein between the connecting rod eye (3) and guide pin (21), a gap (34) is provided for lubrication.

12. Connecting rod according to one of the preceding claims, wherein in the hydraulic fluid line (31) between the first support chamber (1 6) and a supply port at least one check valve (18) and / or in the hydraulic fluid line (32) between the second support chamber (17) and the supply connection at least one check valve (18) is provided.

13. Connecting rod according to claim 12, wherein the switching valve (9) and the at least one check valve (18) in the connecting rod cover (6) are arranged.

14. Connecting rod according to one of the preceding claims, wherein on a circumference of at least partially in the connecting rod cover (6) arranged Hublagerauges (19) at least in the region of the connecting rod cover (6) has a groove (20) for supplying the switching valve (9) with hydraulic fluid the supply connection is provided.

15. Connecting rod according to one of the preceding claims, wherein the eccentric adjusting device (4) via masses forces and gas forces of an internal combustion engine is driven.

16. Internal combustion engine with variable compression with a connecting rod (1) according to one of the preceding claims.