WO2011107130A1 - Method for operating a reciprocating piston engine - Google Patents

Abstract

The invention relates to a method for operating a reciprocating piston engine, wherein at least one lever element (16), which is supported on a crank pin (14) of a crankshaft (12) and which is connected to a corresponding connecting rod (18), is adjusted relative to the crank pin (14) between at least two pivot positions by means of a corresponding adjusting device (24) in order to set the compression ratio of the reciprocating piston engine, wherein the lever element (16) is adjusted between the at least two pivot positions by an at least substantially translational motion of the adjusting device (24), and to a method for operating a reciprocating piston engine, wherein at least one lever element (16), which is supported on a crank pin (14) of a crankshaft (12) and which is connected to a corresponding connecting rod (18), is adjusted relative to the crank pin (14) between at least two pivot positions by means of a corresponding adjusting device (24) in order to set the compression ratio of the reciprocating piston engine, in particular according to one of the preceding claims, wherein a plurality of lever elements (16), which are supported on a respective crank pin (14) and which are connected to a corresponding connecting rod (18), are adjusted independently of each other relative to the respective crank pin (14) between at least two pivot positions by means of an associated adjusting device (24) in order to set the compression ratio of the reciprocating piston engine.

Description

 Method for operating a reciprocating piston engine

The invention relates to a method for operating a reciprocating engine specified in the preamble of claim 1. Art and a method for operating a reciprocating engine specified in the preamble of claim 15 Art.

WO 2007/092168 A2 discloses an internal combustion engine with an adjustable compression ratio. To set the compression ratio is a

Crankshaft of the internal combustion engine mounted on an eccentric carrier, whereby the position of the axis of rotation of the crankshaft in a crankcase of the

Internal combustion engine can be adjusted. The eccentric carrier is actuated via a fork of a hydraulic actuator. This internal combustion engine has further potential for representing efficient operation.

From WO 02/12694 A1 a reciprocating internal combustion engine with a displaceably arranged in a cylinder piston is known, which is pivotally coupled to a connecting rod and whose movement is transferable to a crank of a crankshaft of the reciprocating internal combustion engine. Between the connecting rod and the crank is a

Transmitter provided whose movement is manipulated by a control lever, with the aim of ensuring a controllable movement of the piston, in particular to allow a variation of the compression ratio. These too

Reciprocating internal combustion engine has potential for representing even more efficient operation.

US 2007/0150164 A1 discloses an internal combustion engine with a variable compression ratio and a method for operating such

An internal combustion engine, which is adapted to be operated with one of a plurality of compression ratios selectable compression ratio. This combustion engine also has further potential for making its operation more efficient.

Furthermore, from DE 698 04 297 T2 a reciprocating internal combustion engine is known, which also has a device for adjusting the compression ratio during operation. This internal combustion engine has as a connection between the piston and the crankshaft on a rack which rolls with its teeth on a gear or toothed segment, which in turn with its teeth on a

Rolling control rack and is rotatably mounted on a mounted on the crankshaft connecting rod. The control rack is slidably mounted in the housing of the internal combustion engine in its longitudinal direction, so that by moving the

Control rack in the longitudinal direction, the compression ratio can be changed. The displacement of the control rack can be obtained, for example, hydraulically. The high gas and mass forces of the reciprocating internal combustion engine require a very robust toothing and can expect a strong noise and lack of durability.

DE 601 29 392 T2 also discloses a reciprocating engine with variable

Compression, in which a lever element between the connecting rod and crankshaft is arranged. However, this lever element is adjusted via a control element mounted on an eccentric shaft. The eccentric shaft in turn is by a

housing-fixed actuator twisted.

It is therefore an object of the present invention to provide a method for operating a reciprocating engine, which efficient operation of the

Reciprocating engine allows.

This object is achieved by a method for operating a reciprocating piston engine having the features of patent claim 1 and by a method for operating a reciprocating piston engine having the features of patent claim 15. Advantageous embodiments with expedient and non-trivial developments of the invention are specified in the dependent claims.

An inventive method for operating a reciprocating engine, in which at least one bearing on a crank pin of a crankshaft and with a corresponding connecting rod connected lever element by means of a

corresponding adjusting device for adjusting the compression ratio of the reciprocating engine is set between at least two rotational positions relative to the crank pin, wherein the lever element is articulated on the one hand to the connecting rod and on the other hand with the adjusting device, characterized in that the

Lever element is adjusted by an at least substantially translational movement of the adjusting device between the at least two rotational positions and that the adjusting device at least indirectly to a crankcase of the

Reciprocating piston pivotally supported about a pivot axis. The adjustment of at least two mutually different compression ratios by adjusting the lever element between at least two rotational positions as a result of rotation of the lever member relative to the crank pin around it by means of the adjusting device allows the representation of a very efficient operation of

Reciprocating engine, since their compression ratio can be adapted to different operating points. This means a reduction in fuel consumption and thus the C0 ₂ emissions.

In addition, the inventive method allows a compression ratio of a corresponding to the crank pin and the lever member of the cylinder

Adjust reciprocating engine, regardless of the setting of a compression ratio of at least one other, at least one further crank pin and a corresponding lever member corresponding cylinder of the reciprocating engine. This makes it possible that two different compression ratios of these cylinders can be adjusted, which allows a particularly fuel-efficient and thus efficient operation of the machine. This is a so-called cylinder-selective adjustment of

Compression ratio of the reciprocating engine possible.

In addition, the inventive method has the advantage that a

Tolerance reduction of both components of the reciprocating engine and of

Cylinder fillings of the cylinders of the reciprocating engine and thus a dispersion of the respective, corresponding compression ratios is at least reduced, which also benefits the efficient operation and low fuel consumption. The adjustment by the translational movement has the advantage that the

Reciprocating machine thereby has a low number of parts and thus low costs and low weight and low space requirement, which also favors the efficient operation.

In an advantageous embodiment of the invention, the lever element in

Dependence on a combustion in a working space associated with the lever element, in particular a cylinder, which sets and records the signal characterizing the reciprocating piston engine. This adjustment of the lever element and thus the corresponding compression ratio ensures a selective, controlled and needs-based adjustment of the compression ratio on the adjustment of the lever element to the combustion in the working space, which continues to benefit the efficient operation of the reciprocating engine.

This signal characterizing the combustion in the working space becomes

For example, detected by at least one detection device of the reciprocating engine, which is, for example, a knock sensor, which is associated with the corresponding and corresponding to the lever element working space.

Alternatively or additionally, the signal characterizing the combustion is detected by means of at least one pressure sensor of the reciprocating piston engine associated with the lever element or the corresponding working space, whereby a

appropriate adaptation of the corresponding compression ratio to the combustion in the working space can be performed.

The inventive method thus provides additional degrees of freedom for adjusting the compression ratio of the reciprocating engine, in particular for

Workspace-selective adjustment, available, so as to set a particularly efficient and fuel-efficient and low-emission operation of the reciprocating engine.

Another possibility is, the lever element in response to a temperature and / or pressure of the lever element associated working space of the

Adjust reciprocating piston engine. In the working space does not have to necessarily a combustion happen, so the corresponding work space does not necessarily have to be operated fired. It is also possible that, for example due to a fuel cut no combustion takes place, but it is nevertheless extremely advantageous, even in such operating conditions, for example in a push operation to adjust the corresponding compression ratio to the temperature and / or pressure of or in the work space to the fuel consumption to lower the reciprocating engine and their emissions. In overrun mode, this means that by adjusting the

Compression ratio on the one hand, a compression work of the non-fired working space can be adjusted, so as to set, for example, an engine braking effect or corresponding losses of the reciprocating engine. Furthermore, it is possible to operate one of the workrooms unfired, while another working space is operated to maintain, for example, an operating temperature of the reciprocating engine associated exhaust aftertreatment device, in particular a catalyst, resulting in a maintenance of a purification of exhaust gas of the reciprocating engine and thus low exhaust gas values leads, in particular in an adjoining the thrust operation, fired operation of all work spaces.

The inventive method also allows a workspace-selective

Fuel cut in which a fuel supply is terminated in at least one working space of the reciprocating engine. This leads to a further reduction of the

Fuel consumption. At the same time, it is possible to introduce fuel into at least one further working space, for example to inject it, by a certain amount

Operating temperature of components, in particular of

 Exhaust after-treatment devices, maintain, or increase or adjust.

The adjustment of the lever element and thus the compression ratio in

Depending on a state or of the combustion in the working space characterizing signal individually for the respective working space makes it possible to represent an optimal combustion or optimal state of the corresponding working space individually for this workspace, in which for each working space by the individual adjustment of the lever element

corresponding best point is reached. It is extremely advantageous if, for example, when a predetermined threshold value is exceeded by the temperature in or the working space, the compression ratio is reduced by adjusting the lever element. For example, if a working space cooled by a corresponding cooling device worse, so it has a higher temperature, the compression ratio for this work space can be reduced to bring this working space to a best point to represent a very efficient operation of the working space and thus the entire reciprocating engine.

It should be noted at this point that the temperature of the working space can also refer to a temperature of a component forming the working space. The temperature in or of the working space can also refer to the temperature prevailing in the working space and detected by means of a detection device.

If the lever element is set as a function of a power stroke of a piston of the reciprocating piston engine assigned to the lever element, this means

Creation of further degrees of freedom to improve the efficient operation of the reciprocating engine by these can best be adapted to the currently available operating point individual working space.

The individual setting for each working space of the reciprocating engine

Compression ratio makes it possible to adjust the respective lever element in a favorable operating point, operating range, operating cycle or the like independently and optionally with a time delay.

In a further advantageous embodiment of the invention, the lever element is set to adjust the compression ratio when one of the

Actuator on the lever member for adjusting the lever member to be applied actuating force causes the same movement of the lever member, as one of the connected to the lever member connecting rod to the lever element force applied. This force applied by the connecting rod to the lever element, for example due to combustion processes in the working space, in particular the cylinder,

Compression operations, expansion operations or suction on the

Lever element and further applied to the adjusting device, wherein this force is detected for example by means of a detection device. In this case, therefore, the force applied by the connecting rod to the lever element of the force of the adjusting device, which is used up on the lever element, supported or possibly amplified. This has the consequence that the adjusting device must apply only small actuating forces in order to adjust the lever element, since to be set by the adjusting device rotational position of the lever member and a

Rotary movement of the lever member to achieve this desired rotational position is supported by the force applied by the connecting rod to the lever member force.

For example, applied by the connecting rod to the lever member such a force that causes a rotation of the lever member in a rotational direction and should be set a rotational position of the lever member relative to the corresponding crank pin, which requires a rotational movement in just this direction, it is advantageous in that the desired setting is then carried out by the adjusting device, since then the adjusting force required for adjusting the lever element and applying the adjusting device to the lever element can be lower than if a force were applied from the connecting rod to the lever element, the a rotational movement of the lever member in a direction opposite to this direction of rotation causes or would cause. This applies analogously to the desired setting of the lever element in the corresponding opposite direction of rotation.

Thus, for example, the compression ratio is increased by adjusting the lever element by means of the adjusting device when a tensile force is applied by the connecting rod to the lever element. Furthermore, advantageously, the compression ratio is reduced by adjusting the lever element when moving from the connecting rod to the

Lever element is applied a compressive force.

For example, is the axis of rotation of the lever member, around which the

Lever element in the setting of a rotational position rotates, in the longitudinal extent of the lever member between the force applied by the connecting rod to the lever member and the force applied by the actuator to the lever element actuating force, it is advantageous if a pressure force is exerted on the lever element of the adjusting device when a tensile force is applied to the lever element from the connecting rod and vice versa. This is extremely advantageous if these balance of power present and cause the desired adjustment of the lever member to adjust the desired compression ratio. Nevertheless, it is possible by means of the adjusting device to apply a force to the lever element, which counteracts the force applied by the connecting rod to the lever element. This is the case, for example, if the desire exists, a certain rotational position of the

Lever element for setting a specific, desired

Make compression ratio, but of the connecting rod on the lever member such a force is applied, the rotational movement of the

Lever element in a direction of rotation would cause which of the desired

Direction of rotation to achieve the desired rotational position is opposite.

In a further advantageous embodiment of the invention, the lever element is adjusted in response to a load of the reciprocating engine, which creates a further degree of freedom to represent a very efficient operation and thus to reduce fuel consumption and thus the C0 ₂ emissions of the reciprocating engine.

A particularly precise, efficient and cost-effective adjustment of the lever element is realized in that the lever element is adjusted for example via a threaded spindle of the adjusting device and / or by a hydraulic actuation of the adjusting device.

The adjusting device has, for example, a cylinder with at least one working space in which a piston is axially displaceably received relative to the cylinder and connected to a rod, wherein the working space, for example, divided by the piston into two acted upon by a working medium and having a respective volume control spaces is.

The invention also includes a method for operating a reciprocating piston engine, in which at least one lever element mounted on a crankpin of a crankshaft and connected to a corresponding connecting rod by means of a

corresponding adjusting device for adjusting the compression ratio of the reciprocating engine is set between at least two rotational positions relative to the crank pin, wherein the lever element is articulated on the one hand to the connecting rod and on the other hand with the adjusting device. According to the invention it is provided that a plurality of mounted on a respective crank pin and each with a Corresponding connecting rod connected lever elements by means of an associated adjusting device independently of each other for setting the

Compression ratio of the reciprocating engine between at least two

Rotary positions is adjusted relative to the respective crank pin and that the actuator is at least indirectly pivotally supported on a crankcase of the reciprocating engine about a pivot axis. Advantageous embodiments of the second aspect of the invention are to be regarded as advantageous embodiments of the first aspect of the invention and vice versa. Thus, the method of the second aspect of the invention also enables the representation of a very efficient and thus

low-fuel consumption and C0 ₂ -emissionsarmen operation of the reciprocating engine, since an adjustment of the compression ratio of the reciprocating engine individually for each, each associated with a crankpins work spaces, in particular cylinder, the reciprocating engine is possible. This goes hand in hand with the advantages already described. This as well as the executed support of the adjusting device to be applied to the respective lever element by the force applied by the connecting rod on this lever element force or vice versa leads to lower actuating forces than a common, simultaneous adjustment of the lever elements, resulting in the adjusting devices lower both in terms of their dimensions also their services and thus their energy needs are interpretable. This reduces that

Total energy consumption of the reciprocating engine, which further reduces fuel consumption and thus the C0 ₂ emissions.

In summary, it can be said that the methods of both aspects of the invention allow a component tolerance reduction as well as the representation of an optimal overrun operation of the reciprocating engine. Furthermore, to reduce the

Fuel consumption, a combustion control individually for each workspace and a so-called individual shutdown of the workrooms possible. This shutdown means stopping the fuel supply in at least one working space, it being possible to terminate the fuel supply in at least one working space, while further introduced in at least one other working space of the reciprocating engine fuel, in particular injected.

Further advantages, features and details of the invention will become apparent from the following description of a preferred embodiment and from the drawings. The features mentioned above in the description and Feature combinations as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures are not only in the respectively indicated combination but also in others

Combinations or alone, without departing from the scope of the invention.

The drawings show in:

1 is a perspective and partially sectioned view of a crank mechanism of a reciprocating engine with a crankshaft with four crank pins, on each of which a connected with a corresponding connecting rod lever member is mounted, each of the lever elements is assigned a hydraulically actuated and a translational movement executable actuator, by means of which the respective lever element for adjusting the compression ratio of the reciprocating engine is set between at least two rotational positions relative to the respective crank pin;

Fig. 2 is a perspective and partially sectioned view of a with a

 Connecting rod and an associated actuating device connected lever element of FIG. 1;

Fig. 3 is another perspective view of the conrod and the

 Actuator connected lever element of FIG. 2;

Fig. 4 is a partially sectioned plan view of the conrod and the

 Actuator connected lever element according to Figures 2 and 3.

Fig. 5 is a sectional view of an adjusting device according to the preceding

 Characters; and

6 shows five longitudinal sectional views of the adjusting device according to FIG. 5 in FIG

 different positions for presentation

different rotational positions of the lever member and thus to Representation of different compression ratios of

 Reciprocating engine.

1 shows a crank mechanism 10 of a reciprocating piston engine with a crankshaft 12. The crankshaft 12 has four crank pins 14, on each of which a lever element 6 is mounted, so that the lever elements 16 can rotate relative to the respective crank pins 14. The lever elements 16 are each pivotally connected to a connecting rod 18 and designed as a transverse lever, which extend transversely to the axis of rotation of the crankshaft 12. The connecting rods 18 in turn each have a connecting rod 22, via which the respective connecting rod 22 with a piston of the reciprocating piston displaceably arranged in a cylinder of the reciprocating engine is connectable. As is known, the pistons of the reciprocating engine due to gas expansions by combustion of a fuel-air mixture in the respective cylinder through translational movements, which transmitted via the connecting rods 18 and the lever members 16 on the crank pin 14 and on to the crankshaft 12 and in a rotational movement of the crankshaft 12 are converted, so that the crankshaft 12 according to a direction arrow 20 rotates about its axis of rotation.

As can be seen from FIG. 1, the pistons and thus the connecting rods 22 always apply the same stroke, ie the same translatory upward and downward movement. To represent an adjustable compression ratio of the reciprocating engine, each actuating element 24 is associated with each lever element 16, which is connected in an articulated manner to the respective lever element 16. By means of the adjusting devices 24, the lever elements 16 between at least two rotational positions relative to the respective crank pin 14 rotatable about this. This causes an adjustment of a final volume, which is also referred to as compression volume, in the respective cylinder at top dead center of the respective piston, since the rotational position of the lever elements 16 relative to the respective crank pin 14 affects the translational position of the bottom and top dead center of the piston in the cylinder , An enlargement of the

Compression volume leads to a reduction of the compression ratio and / or vice versa. To adjust the lever member 16 and thus the

Compression ratio of the reciprocating engine, the adjusting devices 24 perform a translational movement, which causes a rotation of the respective lever member 16 relative to the respective crank pin 14 about this. For the sake of clarity, the function of the actuators 24 is based on a

Setting device 24 explained, which is shown in the following figures. FIGS. 2 to 5 show the adjusting device 24, which has a working space 26

Hydraulic cylinder 28 includes. In the hydraulic cylinder 28 and its working space 26, a displaceable piston 30 is arranged, which is fixedly connected to a push rod 32. The piston 30 divides the working space 28 into a first, in the Fig. 2 upper control chamber 34 and a lower, in Fig. 2, the second control chamber 36, wherein the control chambers 34 and 36 have a respective volume, which with a working medium in the form of Lubricating oil of the reciprocating engine can be acted upon. In Fig. 2, the piston 30 and thus the push rod 32 is in a first end position in which the volume of the control chamber 34 is minimal and the volume of the control chamber 36 is maximum. In this case, the volume of the control chamber 36 is filled with the lubricating oil, while the control chamber 34 at least almost no

Includes lubricating oil.

2, the lever element 16 assumes a first rotational position relative to the crank pin 14, in which a low compression ratio of, for example, ε = 7 is present. If the compression ratio is increased, the piston 30 and thus the

Adjusting device 24 moved out of the first end position shown in FIG. 2 and the piston 30 are moved in the direction of a surface 38. This means that the volume of the control chamber 36 has to be reduced and the volume of the control chamber 34 has to be increased. For this purpose, the lubricating oil has to be removed from the control chamber 36 and lubricating oil introduced into the control chamber 34.

In order to allocate appropriate and desired amounts of lubricating oil to the respective control chamber 34 and 36, channels 40, 42, 44 and 46 are provided through which the lubricating oil can flow. The channels 40, 42 and 44 are releasable and closable by corresponding control edges 48, 50 and 52 of a partially received in the push rod 32 control piston 54.

To increase the compression ratio now give the corresponding

Control edges 48, 50 and 52, the channels 40 and 42 free, whereupon the lubricating oil can flow into the control chamber 34 via the channel 40 from the control chamber 36 and via the channel 42. In addition, further lubricating oil via the channel 46 in the Flow control chamber 34, which lubricating oil via a shaft 62 can be fed. The channel 46 is connected to a lubricating oil supply of the reciprocating engine and ensures the supply of the adjusting device 24 with sufficient working fluid in the form of lubricating oil. Corresponding control valves in the form of check valves 56, 58 and 60 prevent an undesirable flow of lubricating oil.

The adjusting device 24 can in particular by using the check valves 56, 58 and 60 additional means for pressure enhancement of the lubricant, ie

Pumps, obsolete or allows at least a small dimensioning of such a device in terms of dimensions and performance, since the actuating device 24 virtually independently as a result of voltage applied to the push rod 32 alternating forces the lubricating oil in and out of the control chambers 34 and 36 promotes and that according to the Channels 40, 42 and 44 released or closed by the control edges 48, 50 and 52. The aforementioned alternating forces result from pressure and gas forces in the cylinder resulting from the abovementioned combustion, which occur via the piston, the connecting rod 18 and the lever element 16 the push rod 32 and thus transferred to the piston 30, thus the lubricating oil in or out of the corresponding

Control chambers 34 and / or 36 pumps.

This means an extremely low energy requirement for setting the

Compression ratio, which keeps the fuel consumption and thus the C0 ₂ emissions of the reciprocating engine in a small frame.

The fact that the adjusting device 24 performs a translational movement, it has the further advantage that it has only a small space requirement while achieving a very precise adjustment of the compression ratio, whereby the reciprocating engine can be adapted very precisely to different operating points and thus a very efficient Operation possible.

As becomes clear in conjunction with FIG. 1, the crank mechanism 10 and thus the reciprocating engine further have the advantage that the lever elements 16 can be adjusted independently of one another by the adjusting devices 24, as a result of which

Compression ratio of each cylinder is selectively adjustable. Thus, the adjusting device 24 perform movements of the lever member 16 and movements of the reciprocating engine with and possibly compensate, it is pivotally held about the rotatably supported on a crankcase of the reciprocating engine shaft 62 and thus pivotally and indirectly supported on the crankcase. The shaft 62 is fixed inter alia by fasteners 80.

Fig. 3 illustrates the operation of the control piston 54 for adjusting the

Lever element 16 and thus to adjust the compression ratio. to

Actuation of the control piston 54, the adjusting device 24 comprises a pin 64 which penetrates the rotatably fixed to the crankcase shaft 62 and is connected to a substantially U-shaped actuating member 66. The shaft 62 penetrating through a corresponding bore 64 and the substantially U-shaped actuating element 66 are integrally formed with each other and by means of an actuator, not shown, magnetically translatable in the direction of movement of the push rod 32 movable. If the actuator 66 via the pin 64 in

Direction of the push rod 32 moves, so the actuator 66 pushes the

Control piston 54 against a spring force of a hand on the control piston 54 and on the other hand on the push rod 32 supported spring element 68 in the

corresponding direction, resulting in a relative movement of the control piston 54 to the push rod 32 results. As a result, the control edges 48, 50 and 52, the channels 40, 42 and 44 free, whereby the lubricating oil in the executed manner in the

Control chambers 34 and / or 36 can flow in or out.

From this flow of lubricating oil results in an increase in volume or a

Volume reduction of the control chambers 34 and 36, which in turn a

Relative movement of the piston 30 and thus the push rod 32 results to the control piston 54. This relative movement takes place until the channels 40, 42 and 44, the corresponding control edges 48, 50 and 52 of the control piston 54 run over and closed again, whereby the flow of the lubricating oil is stopped and the piston 30 and thus the push rod 32 and thus turn the Lever 16 occupy a predetermined position, whereby a desired compression ratio of the reciprocating engine is set.

A reverse actuation of the control piston 54 takes place, for example, in that the actuating element 66 and the pin 64 are switched powerless, whereby the Spring element 68 can push the control piston 54 in the direction of the actuating element 66, whereupon the actuating element 66 and the pin 64 move away from the push rod 32. In this case, the control edges 48, 50 and 52, the channels 40, 42 and 44 free and the push rod 32 moves in the same direction in the other direction.

It is clear that to adjust the lever member 16 and thus the

Compression ratio of the reciprocating engine only a specification of a desired position of the control piston 54 must be done via a specification of a desired position of the actuating element 66 and the pin 64 and the adjusting device 24 then adjusts automatically until the flow of the lubricating oil is interrupted. An additional operation of the control piston 54 to terminate the adjustment of the actuator 24 is not required. Furthermore, this means that any leaks due to wear, as it can occur over a very long lifetime, is quasi self-compensated by the adjusting device 24. It is merely an adaptation of the specification of the desired position of the control piston 54 and the actuating element 66 and the pin 64 needed. If appropriate, this adaptation can take place via a simple comparison of predetermined desired values with actual values detected by means of detection devices. This ensures a very precise adjustment of the compression ratio over a very long service life of the reciprocating engine and thus the representation of a very efficient and fuel-efficient operation derselbigen.

As can be seen from FIG. 3, the actuating element 66 and the control piston 54 are not firmly connected to each other but act via a

arcuate surface 70 of the actuating element 66 together. The center of the arcuate surface is at least substantially on the pivot axis of the adjusting device 24, which coincides with the central axis of symmetry of the shaft 62. The arcuate surface 70 ensures a constant stroke and thus a constant movement of the control piston 54 even during a movement or at a

Pivoting the adjusting device 24 about its pivot axis, wherein the

Control piston 54 carries out this pivoting movement while the actuator 66 as described rotatably. To improve the contact conditions between the control piston 54 and the arcuate surface 70, the control piston 54 has a rounded head which abuts the arcuate surface 70 and can slide along it with little friction. To illustrate the executed relative movement of the cylinder 28 and thus of the control piston 54 to the actuating element 66, the cylinder 28 has a slot in which the actuating element 66 is arranged.

To illustrate a simple and inexpensive installation, the cylinder 28 comprises three parts 74, 76 and 78, the part 74 being connected to the part 76. The part 78 is also connected to the part 76 and is partially received in the part 76 and limited on the one hand the working space 26th

Fig. 6 shows the adjusting device 24 in five different from each other

Positions for the representation of five different rotational positions of the lever member 16 relative to the respective crank pin 14 and for representing five different compression ratios of the reciprocating engine. According to illustration A, the adjusting device 24 is in the upper end positions shown in FIGS. 1 to 5, in which the lowest compression ratio is present, which is, for example, ε = 7.

As shown in Figure B, there is a larger amount of lubricating oil in the control chamber 34 than in the illustration A, while there is a small amount of lubricating oil in the control chamber 36. Accordingly, the piston 30 and thus the push rod 32 has moved away from the shaft 62. By this movement, the compression volume in the corresponding cylinder of the reduced

Reciprocating piston engine because the push rod 32 presses the lever member 16 in a different rotational position relative to the crank pin 14, wherein this rotational movement is converted via the connecting rod 18 in a translational movement of the piston in the cylinder. According to illustration C, a compression ratio of ε = 9.5 is set. In comparison, the compression ratio is as shown in FIG

Adjustment of the adjusting device 24 again slightly less, while the

Compression ratio in the position shown in FIG. E of FIG

Adjustment device 24 ε = 14 amounts. It can be seen that now a particularly large amount of lubricating oil is received in the control chamber 34, while the control chamber 36 contains almost no more lubricating oil. For the sake of clarity, the other reference numerals have been omitted in FIG. 6, the analogous to the adjusting device 24 according to the preceding figures being analogous to the adjusting device 24 according to FIG.

Claims

claims

Anspruch [en] A method for operating a reciprocating engine, in which at least one lever element (16) mounted on a crank pin (14) of a crankshaft (12) and connected to a corresponding connecting rod (18) is adjusted by means of a corresponding adjusting device (24) for setting the

 Compression ratio of the reciprocating engine between at least two rotational positions is adjusted relative to the crank pin (14), wherein the

 Lever element (16) on the one hand with the connecting rod (18) and on the other hand with the adjusting device (24) is hingedly connected,

 characterized in that

 the lever element (16) is adjusted by an at least substantially translatory movement of the adjusting device (24) between the at least two rotational positions and that the adjusting device (24) is at least indirectly pivotably supported on a crankcase of the reciprocating engine about a pivot axis.

2. The method according to claim 1,

 characterized in that

 the lever element (16) as a function of a combustion in a lever element (16) associated working space, in particular cylinder, the

 Reciprocating engine characterizing signal is set.

3. The method according to claim 2,

 characterized in that

 the combustion characterizing signal by means of at least one

Detecting means of the reciprocating engine is detected.

4. The method according to any one of claims 2 or 3,

 characterized in that

 the combustion characterizing signal is detected by means of at least one of the working space associated knock sensor of the reciprocating engine.

5. The method according to any one of claims 2 to 4,

 characterized in that

 the combustion characterizing signal is detected by means of at least one of the working space associated pressure sensor of the reciprocating engine.

6. The method according to any one of the preceding claims,

 characterized in that

 the lever element (16) is set as a function of a temperature and / or a pressure of a working space, in particular a cylinder, associated with the lever element (16), of the reciprocating piston engine.

7. The method according to claim 6,

 characterized in that

 when a predetermined threshold value is exceeded by the temperature, the compression ratio is reduced by adjusting the lever element (16).

8. The method according to any one of the preceding claims,

 characterized in that

 the lever element (16) in response to a power stroke of the

 Lever element (16) associated piston of the reciprocating engine is adjusted.

9. The method according to any one of the preceding claims,

 characterized in that

the lever member (16) is adjusted to adjust the compression ratio when one of the actuator (24) to be applied to the lever member (16) for adjusting the lever member (16) actuating force causes the same movement of the lever member (16) as one of the the lever element (16) connected to the connecting rod (18) on the lever element (16) applied force.

10. The method according to claim 9,

 characterized in that

 the compression ratio is increased by adjusting the lever member (16) when a tensile force is applied from the connecting rod (18) to the lever member (16).

11. The method according to any one of claims 9 or 10,

 characterized in that

 the compression ratio is reduced by adjusting the lever member (16) when a compressive force is applied from the connecting rod (18) to the lever member (16).

12. The method according to any one of the preceding claims,

 characterized in that

 the lever member (16) is adjusted in response to a load of the reciprocating engine.

13. The method according to any one of the preceding claims,

 characterized in that

 the lever element (16) is adjusted via a threaded spindle of the adjusting device (24) and / or by a hydraulic actuation of the adjusting device (24).

14. The method according to any one of the preceding claims,

 characterized in that

 the lever element (16) is adjusted via a piston (30) of the adjusting device (24) that is displaceably received axially relative to the cylinder (28) in a working chamber (26) of a cylinder (28) and connected to a rod (32).

15. A method for operating a reciprocating engine, wherein at least one of a crank pin (14) of a crankshaft (12) stored and with a

 corresponding connecting rod (18) connected lever element (16) by means of a corresponding adjusting device (24) for adjusting the

 Compression ratio of the reciprocating engine between at least two rotational positions is adjusted relative to the crank pin (14), wherein the

Lever element (16) on the one hand with the connecting rod (18) and on the other hand with the Actuator (24) is pivotally connected,

 characterized in that

 a plurality of at a respective crank pin (14) mounted and each with a corresponding connecting rod (18) connected lever elements (16) by means of an associated adjusting device (24) independently of each other for adjusting the compression ratio of the reciprocating engine between at least two rotational positions relative to the respective crank pin (14) is set and that the adjusting device (24) at least indirectly on a

 Crankcase of the reciprocating engine pivotally supported about a pivot axis.

16. The method according to claim 15,

 characterized in that

 the lever elements (16) in each case depending on a combustion in a lever element (16) associated working space, in particular cylinder, the reciprocating engine characterizing signal can be adjusted.

17. The method according to claim 16,

 characterized in that

 the combustion characterizing signal by means of at least one

 Detecting means of the reciprocating engine is detected.

18. The method according to any one of claims 16 or 17,

 characterized in that

 the combustion characterizing signal is detected by means of at least one of the working space associated knock sensor of the reciprocating engine.

19. The method according to any one of claims 16 to 18,

 characterized in that

 the combustion characterizing signal is detected by means of at least one of the working space associated pressure sensor of the reciprocating engine.

20. The method according to any one of claims 15 to 19,

 characterized in that

the lever elements (16) in each case depending on a temperature and / or a pressure of the lever element (16) associated working space, in particular cylinder, the reciprocating engine can be adjusted.

Method according to claim 20,

 characterized in that

 when a predetermined threshold value is exceeded by the temperature, the compression ratio is reduced by adjusting the lever element (16).

Method according to one of claims 15 to 21,

 characterized in that

 the lever elements (16) in each case depending on a power stroke of the lever element (16) associated piston of the reciprocating engine can be adjusted.

23. The method according to any one of claims 15 to 22,

 characterized in that

 the lever elements (16) for setting the compression ratio are each set when one of the adjusting device (24) to be applied to the respective lever element (16) for adjusting the lever element (16)

 Actuating force causes the same movement of the lever member (16) as a force applied to the lever member (16) by the connecting rod (18) connected to the lever member (16).

24. The method according to claim 23,

 characterized in that

 the compression ratio is increased by adjusting the lever member (16) when a tensile force is applied from the connecting rod (18) to the lever member (16).

Method according to one of claims 23 or 24,

 characterized in that

the compression ratio is reduced by adjusting the lever member (16) when a compressive force is applied from the connecting rod (18) to the lever member (16).

26. The method according to any one of claims 15 to 25,

 characterized in that

 the lever elements (16) each in response to a load of

 Reciprocating engine can be adjusted.

27. The method according to any one of claims 15 to 26,

 characterized in that

 the lever elements (16) in each case via a threaded spindle of the adjusting device (24) and / or by a hydraulic actuation of the adjusting device (24) can be adjusted.

28. The method according to any one of claims 15 to 27,

 characterized in that

 the lever elements (16) in each case via a in a working space (26) of a cylinder (28) axially relative to the cylinder (28) slidably received and connected to a rod (32) piston (30) of the adjusting device (24) can be adjusted.