AT517217A4 - LENGTH-ADJUSTABLE CONNECTING ROD - Google Patents

Abstract

A length-adjustable connecting rod (1) has a first rod part (4) and a second rod part (5) which are telescopically displaceable on. One of the two rod parts (5) forms a guide cylinder (8) and the other rod part (4) in the guide cylinder (8) longitudinally displaceable piston member (6) which is adjacent to a first and a second high-pressure chamber (9, 10), wherein the first high-pressure chamber (9) a first oil passage (11) and in the second high-pressure chamber (10) opens a second oil passage (12), and the oil passages (11, 12) by a control device (16) are controlled, a first and a second valve (17, 22) each having a in a valve chamber (18; 23) arranged valve body (20; 25) which is pressed by a restoring force against a valve seat (21; 26). The first valve space (18) of the first valve (17) is in fluid communication with the first oil passage (11) and the second valve space (23) of the second valve (22) with the second oil passage (12). The valve bodies (20; 25) are operatively connected to one another via a connecting device (27), wherein in a first position the first valve body (20) and in a second position the second valve body (25) are separated from the first or the first valve body by the connecting device (27) the second valve seat (21; 26) can be lifted off and the corresponding first or second valve chamber (18; 23) can be fluidly connected to the oil supply channel (13) and rests in the other position on the first and second valve seat (21; the flow connection to the oil supply channel (13) locks.

Description

The invention relates to a length-adjustable connecting rod for a reciprocating engine, with at least a first rod part and a second rod part, which two rod parts telescopically zoom in and / or into each other, wherein one of the two rod parts form a guide cylinder and the other rod part a longitudinally displaceable in the guide cylinder piston member wherein between a first end face of the piston member and the guide cylinder, a first high-pressure chamber and between a second end face of the piston member and the guide cylinder, a second high-pressure chamber is clamped, wherein in the first high-pressure chamber, a first oil passage and the second high-pressure chamber opens a second oil passage, and the Oil passages are fluidly connected by a control device with at least one oil supply channel.

The AT 511.803 Bl describes a length-displaceable connecting rod for an internal combustion engine with two telescopically movable rod parts, between the first and the second rod part a high-pressure chamber is spanned, in which an oil passage opens, the flow is controlled by a control valve designed as a control device.

Furthermore, from AT 514 071 Bl a telescopically adjustable connecting rod is known, wherein a rod part form a guide cylinder and another rod part of the connecting rod in the guide cylinder longitudinally displaceable piston member, wherein between the piston member and the guide cylinder on one side of the piston, a first high-pressure chamber and on the other Side of the piston, a second high-pressure chamber are spanned, which open into which oil passages whose flows are controlled by a spool.

Control spools are usually sealed by means of sealing rings (O-rings) relative to the surrounding cylinder, but with an axial deflection of the spool radial openings of the guide cylinder to be controlled oil passages are run over by the sealing rings and lead to increased wear and short life thereof.

The object of the invention is to avoid the disadvantages mentioned and to increase the service life with a length-adjustable connecting rod.

According to the invention this is achieved in that the control device comprises a first valve and a second valve, each having a valve body arranged in a valve body, which is pressed by a restoring force against a valve seat, wherein a first valve chamber of the first valve chamber with the first oil passage and a second Valve chamber of the second valve chamber is fluidly connected to the second oil passage, and the valve body via a displaceable at least between a first position and a second position, at least one connecting element having connecting means are operatively connected to each other, and wherein in the first position of the first valve body and in the second position the second valve body by the connecting device against the restoring force of an associated first and second valve seat can be lifted and the corresponding first and second valve chamber with the oil supply passage is flow connected, and each rests in the other position on the first and second valve seat and blocks the flow connection to the oil supply channel.

The control device thus has instead of a spool on simple lift valves whose spring-loaded, for example, spherical valve body are each pressed against a valve seat. Lifting the valve body from the valve seat opens the flow of the corresponding oil channel.

It is preferably provided that the connecting element is fixedly connected to a control piston which is displaceable in a control cylinder and which adjoins a control space into which a control line-preferably connected to the oil supply duct-opens. By pressurizing the control chamber of the control piston is deflected against a restoring force formed by a return spring.

The connecting element can be designed as a preferably perpendicular to the longitudinal axis of the connecting rod, axially displaceable in a guide of the connecting rod connecting rod. The connecting element has the task of opening the first valve or the second valve alternatively.

The valve body and the connecting device are separate component, wherein the connecting device in the first position from the second valve body and in the second position is spaced from the first valve body. This ensures that with a large stroke only one valve is opened and the other valve is closed. With a smaller stroke, in principle, both valves can be opened.

In a simple and space-saving embodiment variant of the invention it is provided that the first stroke axis of the first valve body is formed coaxially with the longitudinal axis of the displacement rod, wherein the first valve is arranged in the region of a first end of the connecting rod. Furthermore, it can be provided in an easy to manufacture and space-saving design that the second lifting axis of the second valve body is formed coaxially with the longitudinal axis of the connecting rod, wherein the second valve is disposed in the region of a second end of the connecting rod, and preferably wherein the valve seats of the first and the second valve facing away from each other. The lifting axes of the valve body and the longitudinal axis of the connecting rod are thus arranged normal to the longitudinal axis of the connecting rod. For internal combustion engines with high speeds, for example, over 4000 U / min, it is advantageous if the first stroke axis of the first valve body is inclined at a first angle of about 90 ° +/- 60 ° to the longitudinal axis of the connecting rod. Thereby, a lifting of the first valve body from the first valve seat at high speeds due to the inertial forces can be avoided. In this case, at least one preferably rod-shaped first transmission element can be arranged to be axially displaceable between the first valve body and the connecting rod, preferably the first displacement axis of the transmission element being arranged coaxially to the first stroke axis of the first valve body.

Internal combustion engines with still higher speed - for example up to 8800 rpm - can be operated, even if the second stroke axis of the second valve body is inclined at a second angle of about 90 ° +/- 60 ° to the longitudinal axis of the connecting rod. This prevents - as with the first valve body - a lifting of the second valve body from the second valve seat at very high speeds in consequence of the inertial forces. In this case, at least one preferably rod-shaped second transmission element can be arranged to be axially displaceable in an analogous manner between the second valve body and the connecting rod, wherein preferably the second displacement axis of the second transmission element is arranged coaxially to the second stroke axis of the second valve body.

In order to enable in a simple manner a deflection of the actuating force of the connecting rod to the first valve or second valve, it is advantageous if at least one preferably spherical deflecting element is arranged between the first transmission element and the connecting rod and / or between the second transmission element and the connecting rod , wherein particularly preferably the deflecting element is arranged in a receiving bore of the connecting rod and the first and second transmission element and at an angle greater than 0 ° to this inclined deflection bore. The connecting rod thus acts indirectly via at least one deflection element and at least one transmission element on the valve body of the corresponding first or second valve. The use of deflecting elements has the advantage that the connecting rod can be built with a very small thickness, since the thickness has no influence on the stroke of the valve body.

As an alternative to a deflecting element arranged between the connecting rod and the transmission element, it can be provided that the connecting rod acts directly on the first or second transmission element, wherein at least one end of the connecting rod and / or of the transmission element acting with the respective other part is conically or spherically shaped. In this case, the thickness of the connecting rod has influence on the maximum possible stroke of the valve body to be controlled. The thickness of the connecting rod should be at least twice the stroke of the valve body. In this case, can be dispensed with a separate deflection.

In a further embodiment of the invention it can be provided that the control cylinder has at its outer periphery a preferably formed by a circumferential annular groove annulus, which is fluidly connected to the control chamber or a high-pressure chamber. As a result, an unintentional displacement of the control piston and thus of the displacement device in certain operating areas, for example, by pressure surges when opening one of the two valves can be avoided because the control piston is clamped or blocked by the filling of the annular space.

In a connecting rod, whose control device has at least one displaceably mounted in the direction of a displacement axis part, wherein the displacement axis in a rocking plane of the connecting rod - preferably normal to the longitudinal axis of the connecting rod - is arranged, it can further be provided in the invention that at least one hin- and hergehender part of the control device has at least one buoyant body or at least partially formed as a buoyant body.

The buoyant body floating in the actuating medium has a lower density than the actuating oil, for example engine oil. It can be designed as a hollow body or as a closed-cell foam body, for example made of polystyrene.

By firmly connected to the reciprocating part or formed integrally with this buoyancy body, the accelerated mass is reduced, the Archimedian principle that the static buoyancy of a body in a medium is the same as the weight of the body displaced medium to Application comes.

Preferably, at least one reciprocating part of the control device is formed by a control piston displaceably mounted in a cylinder, whose first end face adjoin a control chamber which can be acted upon with oil and whose second end side adjoin a spring space having a return spring. In a preferred embodiment of the invention, it is provided that at least one buoyant body is arranged in the region of the first end face and / or in the region of the second end face of the control piston.

A substantial reduction in the accelerated mass can be achieved, in particular, when a buoyant body is arranged both in the region of the first end face and in the region of the second end face adjoining the spring chamber. For this purpose, it is necessary that the spring chamber is flooded with the oil. This can be achieved with very little effort if the control piston between the control chamber and the spring chamber has a defined leakage, wherein preferably the spring chamber is fluidly connected to a storage space, which may be arranged for example in the same rod part of the connecting rod as the control device.

If the storage space is connected via a throttle with the crankcase, an unobstructed oil return into the crankcase chamber can be achieved.

Thus, the spring chamber of the control piston is thus always filled with the oil, as always sufficient oil from the storage space and / or can be sucked through the leaks by the reciprocating movements of the control piston. The throttle allows damping of the movement of the control piston, whereby it is less sensitive to any returning pressure waves.

In a particularly preferred embodiment of the invention it is provided that the connecting device has at least one buoyant body or is at least partially designed as a buoyant body. In this case, the connecting rod may for example be hollow and thus form a buoyant body itself. Alternatively or additionally, it can be provided that at least one valve body has at least one buoyancy body or is at least partially designed as a buoyancy body.

All of the measures mentioned contribute to the fact that the density of the entire system and the masses to which lateral accelerations act as a result of the crankshaft revolution are substantially reduced. In this way, engine speeds can be realized well above 7000 U / min, without the function of the length adjustability of the connecting rod is limited.

When cold starting, there is a desire for a high compression. However, when the engine is cold, there is a high oil pressure in the lubricating oil circuit, which would shorten the connecting rod, which hinders the desire for high compression. In order to avoid this problem it can be provided within the scope of the invention that the connecting device and / or the control piston has at least one thermocouple. It is particularly advantageous if the connecting element of the connecting device is designed as a preferably normal to the longitudinal axis of the connecting rod, axially displaceable connecting rod which - is preferably divided axially in the region of the control piston - the thermocouple between a first connecting rod part and a second connecting rod part, is particularly preferably arranged between the first connecting rod part and the control piston.

The thermocouple has a shorter installation length when cold than when hot. Such thermocouples with a temperature-sensitive expansion element with, for example, oil, wax, hard paraffin or metal as the expansion material are used for example in thermostatic valves of internal combustion engines.

In the cold state, the thermocouple compensates for the high control pressure in the cold lubricating oil circuit, which is why a shortening of the connecting rod and thus lowering the compression at cold start is avoided. Due to the contracted expansion of the thermocouple, the length of the connecting element is shortened, which is why an opening of the first valve is omitted and the pressure in the first high-pressure chamber is maintained. Upon reaching the operating temperature of the expansion material expands in the thermocouple, whereby the connecting element reaches the necessary for the actuation of the first valve normal length. The desired compression values can now be set according to the control of the engine map. For example, high compression is set for the low load range and low compression for the high load range.

The internal combustion engine is usually operated immediately before parking in the partial load and with high compression. When the engine is stopped, the high compression required for the cold start has been set.

To avoid that after prolonged rest period, the oil is pressed out of the first high-pressure chamber by the piston weight, between the first and second rod part acting in the direction of connecting rod extension spring element may be arranged, wherein preferably the spring element is designed as a plate spring. By the spring element, the second rod part of the connecting rod is held in its upper position.

When adjusting the length of the connecting rod may possibly lead to pressure waves in the hydraulic system, which can lead on the one hand to an undesired adjustment of the control device and on the other hand to adverse influences or damage in the rest of the oil system of the vehicle. In order to avoid this, it is provided in a particularly preferred embodiment of the invention that at least one first throttle device and / or at least one second throttle device is arranged in the first oil passage. By the throttle devices, it is possible to avoid returning pressure waves or at least slow down to a harmless extent. In this case, in each case a throttle device may be provided in one of the two oil channels or in both oil channels. In order to allow rapid filling of the high-pressure chambers despite the throttling devices, it can be provided in a further embodiment that the first throttle device and / or the second throttle device can be bypassed by a first bypass channel or a second bypass channel, preferably in the first bypass channel and / or second bypass channel, a first bypass valve or second bypass valve is arranged.

The first or second bypass valve may be formed as opening in the direction of the respective high-pressure chamber check valve.

The invention will be explained in more detail below with reference to the non-limiting figures.

Show it

1 is a connecting rod according to the invention in a longitudinal section,

2a shows a schematic control device for a connecting rod according to the invention in a first switching position,

2b shows this schematic control device in a second switching position,

3 shows a control device for a connecting rod according to the invention in a first embodiment,

4 shows a control device for a connecting rod according to the invention in a second embodiment,

5 shows a control device for a connecting rod according to the invention in a third embodiment,

6 shows a control device for a connecting rod according to the invention in a fourth embodiment,

7 shows a control device for a connecting rod according to the invention in a fifth embodiment variant,

8 shows the control device from FIG. 7 in a disassembly position, FIG.

9 shows a control device for a connecting rod according to the invention in a sixth embodiment,

10 shows a control device for a connecting rod according to the invention in a seventh embodiment variant,

11 is a schematic representation of a control device for a connecting rod according to the invention in an eighth embodiment and

FIG. 12 shows a practical embodiment of the eighth embodiment variant shown schematically in FIG. 11, FIG.

13 is a schematic control device for a connecting rod according to the invention in a ninth switching position,

14 shows a practical embodiment of the ninth embodiment variant shown schematically in FIG. 13,

15 this connecting rod in a section according to the lines XV-XV in Fig. 14,

Fig. 16, this connecting rod in a section along the lines XVI-XVI in Fig. 14 and

17 and 18, the relative displacements of the rod parts and the pressures in the high-pressure chambers over the crank angle for different engine speeds. Functionally identical parts are provided in the embodiments with the same reference numerals.

Fig. 1 shows a two-part connecting rod 1 for a reciprocating engine, such as an internal combustion engine, with a small connecting rod 2 for a not further shown piston pin bearing and a large connecting rod 3 for a not further shown crank pin bearing an internal combustion engine. The rotational symmetry axes of the small or large connecting rod 2, 3 are denoted by 2a and 3a, respectively. The longitudinal axis of the connecting rod 1 is denoted by la, one on the rotational symmetry axes 2a and 3a of the small and large connecting rod 2, 3 normal and the longitudinal axis la of the connecting rod 1-containing longitudinal center plane - the swing plane - the connecting rod 1 is denoted by ε.

The connecting rod 1 has an upper first rod portion 4 with the small connecting rod 2 and a lower second rod portion 5 with the large connecting rod 3. The first rod part 4 is adjustable relative to the second rod part 5 between an extended position and an inserted position shown in Fig. 1 by an adjustment range Äl in the direction of the longitudinal axis la of the connecting rod 1. In the upper first rod part 4, a substantially cylindrical piston element 6 is fastened, for example, with a fastening screw 7 formed by a hexagon socket screw.

The piston element 6 is guided in an axially displaceable manner in a guide cylinder 8 of the lower second rod part 5 of the connecting rod 1, wherein between at least one position of the two rod parts 4, 5, a first end face 6a of the piston element 6 and the second rod part 5 facing the large connecting rod eye 3 first high-pressure chamber 9 is clamped. The piston element 6 designed as a stepped piston has a second end face 6b facing the small connecting rod eye 2, which adjoins a second high-pressure chamber 10 whose cylindrical lateral surface is formed by the guide cylinder 8 of the second rod part 5. Under a stepped piston is generally understood a piston - in the present case a "double-acting piston" - with different sized effective surfaces, one of the active surfaces (here: oriented against the second high pressure chamber 10 effective area) as an annular surface and the other effective surface formed as a circular area is. Due to the different effective surfaces, the pressure conditions described here can be realized.

The annular first and second end faces 6a, 6b form pressure application surfaces for an actuating medium, for example engine oil, which is led into the high-pressure chambers 9, 10 and is under pressure.

In the first high pressure chamber 9, a first oil passage 11 and in the second high pressure chamber 10, a second oil passage 12 opens.

The oil supply of the first and second oil passage 11, 12 via the oil supply passage 13, which starts from the connecting rod bearing 3b of the large connecting rod 3 and thus fluidly connected to the crank pin bearing, not shown, and connected to the oil supply channel 13 connecting channels 14, 15th

For controlling the pressures in the first and second high-pressure chambers 9, 10, a control device 16 in the connecting rod 1, in the lower second rod member 5, is provided, which in the flow path between the first connecting channel 14 and the first oil passage 10, a first valve 17 with a first valve chamber 18, in which a biased by a first valve spring 19 first valve body 20 is pressed against a first valve seat 21. In the first valve chamber 18, the first oil passage 11 opens. Furthermore, the control device 16 has a second valve 22 with a second valve chamber 23, in which a biased by a second valve spring 24 second valve body 25 is pressed against a second valve seat 26, wherein the second oil passage 12 opens into the second valve chamber 23. Furthermore, the control device 16 has a connecting device 27 between the first valve 17 and the second valve 22 with at least one connecting element 28, which is formed in the embodiments by a normal to the longitudinal axis la, in particular normal to the longitudinal center plane ε of the connecting rod 1 connecting rod 29. The connecting element 28 is fixedly connected to a control piston 31 displaceable in a control cylinder 30. The spring-loaded by a return spring 32 control piston 31 is adjacent to a control chamber 33 into which a connected to the oil supply channel 13 and the connecting channel 15 control line 34 opens. The valve body 20 or 25 and the connecting device 27 are separate components. As a result, in at least one first displacement position of the connecting element 28 shown in FIG. 2a, the connecting device 27 is spaced from the second valve body 25 and in a second displacement position shown in FIG. 2b from the first valve body 20.

The first and second valve bodies 20, 25 of the first and second valves 17, 22 are preferably formed by balls.

By the valve body 20, 25 of the first and second valves 17, 22, the flow connections between the first supply channel 14 and the first oil passage 11 and between the second supply passage 15 and the second oil passage 12 are opened or closed. The existing example of plastic control piston 31 is actuated by the oil pressure of the internal combustion engine.

If the oil pressure - for example, at light load - under a defined set pressure (of, for example, 1.8 bar) is maintained, the control piston 31 remains in its illustrated in Fig. 2b second position, because the spring force of the return spring 32 is greater than the force In this case, keeps the connecting rod 29, which is fixed to the control piston 31 - for example, by a press fit - the valve body 25 for the connection to the second high-pressure chamber 10 via the the second oil passage 12 is opened while the first valve body 20 of the first valve 17 remains closed for connection to the first high-pressure chamber 9 by the first valve spring 19. During the lifting movement acts in the region of the top dead center of the piston, not shown, a mass force on the connecting rod 1, which the first rod part together with piston 6 - in Fig. 1, 2a and 2b considered - and thus pulls the small eye up. In this case, oil is sucked in via the actually closed first valve 21, in that the first valve body 20 is raised counter to the restoring force of the first valve spring 19 by the suction effect produced in the first high-pressure chamber 9; the lower first high pressure chamber 9 fills with oil via the first oil passage 11, while oil is pressed out of the upper second high pressure chamber 10 into the second oil passage 12. The connecting rod 1 is thereby longer. The oil flow in the oil passages 11, 12 is shown by arrows in Fig. 2b.

When the oil pressure at a higher engine load increases to a higher level, the return spring 32 of the control piston 31 is compressed, wherein the control piston 31 moves to a left stop of the control cylinder 30.

In this position, the connecting rod 29 presses the first valve body 20 of the first valve 17, which connects the lower first high-pressure chamber 9 with the oil supply channel 13. This allows the oil from the first high-pressure chamber 9 to flow back into the oil supply channel 13 and thus further into the oil supply system. Since the connecting rod 29 is lifted from the second valve body 25 and thus the second valve body is pressed by the restoring force of the second valve spring 24 to the second valve seat 26, the second valve 22 is closed; at each ignition, the piston 6 is depressed and sucked oil into the second high-pressure chamber 10 by the suction in the second high-pressure chamber 10 via the actually closed second valve 22 by the opposite of the force of the second valve spring 24 contrasting second valve body 25 to the second high-pressure chamber 10 with oil is filled. The flow of the oil is indicated by arrows in Fig. 2a. In this position, the connecting rod 1 is shorter.

When the oil pressure in the oil system is lowered again, the return spring 32 of the control piston 31 expands (FIG. 2b) and the control piston 31 moves to the right as viewed in FIG. 2b, the second valve 22 for the second high-pressure chamber 10 being opened and the first valve 17 is closed for the first high-pressure chamber 9. The first high pressure chamber 9 pumps again in the manner described by acting on the second rod member and the piston member 6 at the top dead center of the piston mass forces and the connecting rod 1 is longer again.

In the following, various embodiments of the control device 16 will be explained with reference to FIGS. 3 to 9.

FIG. 3 shows a first embodiment corresponding to the schematic representations from FIGS. 2 a and 2 b, in which the first lifting axis 20 a of the first valve body 20 of the first valve 17 and the second lifting axis 25 a of the second valve body 25 of the second valve 22 are coaxial to the longitudinal axis 29 a of FIG Connecting rod 29 is arranged.

The control device 16 has a housing 35 inserted and fixed in the second connecting rod part 5. The housing 35 has a guide part 35a for the connecting rod 29 in the region of the first valve 17 and a guide part 35b for the connecting rod 29 in the region of the second valve 22, wherein in the embodiment shown in Fig. 3, the first valve 17 in the guide part 35a and the second valve 22 is arranged in a guide part 35b. The guide part 35b is formed in the embodiments shown in FIGS. 3, 4, 5, 6, 10, 12 and 14 by the valve housing 55 of the second valve 22, which valve housing 55 laterally inserted and fixed in a receiving bore 56 of the second rod part 5 becomes. The displacement rod 29 is slidably mounted in the two guide part 35a, 35b. The control piston 30 accommodating the control piston 30 is formed by the guide part 35a. In the area of the first oil channel 11, the guide part 35a for supplying the first high-pressure chamber 9 with oil has an annular space 46 connected in flow-connected fashion to the first valve chamber 18. Similarly, in the guide part 35b in the region of the second oil passage 12, a circumferential annular space 47 is incorporated, which is flow-connected via a radial bore with the second valve chamber 23.

In the example shown in FIG. 3, the first connection channel 14 and the control line 34 are arranged in the guide part 35a, and the second connection channel 15 is arranged in the guide part 35b.

An annular gap 36 formed between the guide part 35a and the first rod part 4 serves to connect the oil supply channel 13 arranged in the first rod part 4 with the first connection channel 14 and the control line 34 leading to the control chamber 33. Optionally, a throttle 49 may be arranged between the second connecting channel 15 and the control chamber 33. Furthermore, a throttle 50 may be arranged in the outgoing from the connecting rod 3b oil supply channel 13.

The consisting of the two guide members 35a, 35b housing 35 with the integrated connection channels 14, 15 and the integrated control line 34 has the advantage that in the first rod part 4 designed for a control slide known connecting rod 1 no or only a few adaptations must be performed, so that the production costs can be kept very small.

Reference numeral 44 denotes a vent line for venting or venting the control chamber 33 and for removing leakage oil. The vent line 44 may have a restrictor 44a (FIG. 13). High pressure areas of the housing 35 are sealed via O-ring seals 45. With sealing plug 48 manufacturing technology necessary holes are closed.

FIG. 4 shows an alternative second embodiment of the control device 16, which essentially differs by a clamping function for the control piston 31 of FIG. 3.

In order to prevent that when the second valve 22 for the second high-pressure chamber 10 is opened, the pressure wave pushes the control piston 31 to the left in FIG. 2b and thereby reopens the other first valve 17, which seals the lower first high-pressure chamber 9 the control cylinder 30 receiving housing 35 of the control device 16 designed so that in the region of the control piston 31, the pressure wave constricting the housing wall of the control cylinder 30 elastic. The guide part 35a of the housing 35 has to a constriction of the housing wall in the region of the control cylinder 30 forming annular groove 37a, the annular space 37 is connected to the second oil passage 12 via an intermediate channel 38. The wall thickness in this constricted area is chosen so that the deformation of the housing wall surrounding the control cylinder 30 due to the pressure applied in the annular space 37 of the annular groove 37a when a pressure wave occurs is sufficiently large to clamp the control piston 31. Whenever high pressure prevails in the second high-pressure chamber 10, the housing 35 is deformed so that the spool 31 is clamped and a displacement of this by occurring pressure waves is effectively prevented. When the control piston 31 is clamped by the deformation of the housing 35, thus, the first valve 17 can not be opened by the control piston 31.

The control movement can therefore always take place only in the depressurized phases.

Furthermore, in FIG. 4, the connecting channels 14, 15 are arranged partially in the first rod part 4 and partly in the housing 35.

FIG. 5 shows a third variant in which the first valve space and the control cylinder are formed directly by the first rod part 4.

FIG. 6 shows a fourth variant in which the first lifting axis 20a of the first valve body 20 is inclined at a first angle α of approximately 90 ° +/- 60 ° to the longitudinal axis 29a of the connecting rod 29. Specifically, in the exemplary embodiment, the first lifting axle 20a is arranged normally on the longitudinal axis 29a of the connecting rod 29, but the second lifting axle 25a of the second valve body 25 is arranged coaxially with the longitudinal axle 29a of the connecting rod 29. Between the first valve body 20 and the connecting rod 29 at least one axially displaceable, substantially rod-shaped first transmission element 39 is arranged, wherein preferably the longitudinal axis 39a of the transmission element 39 is arranged coaxially to the first lifting axis 20a of the first valve body 20.

For deflecting the movement of the connecting rod 29 on the first valve body 20 and the first transmission element 39, a spherical deflecting element 40 is arranged in a deflection bore 41 which connects the receiving bore 29b of the connecting rod 29 and the receiving bore 39b of the transmission element 39. The first deflection bore 41 is arranged inclined at an angle β> 0 °, for example 45 °, to the longitudinal axis 29a of the connecting rod 29 and to the first lifting axis 20a of the first valve body 20. The connecting rod 29 thus acts indirectly, ie via the deflecting element 39, on the transmission element 39. The connecting rod 29 and / or the deflecting element 40 may consist of a ceramic material, which ensures high strength and low thermal expansion.

Characterized in that the first lifting axle 20a is arranged parallel to the longitudinal axis la of the connecting rod, a lifting of the first valve body 20 by inertial forces as a result delaying and accelerating movements of the connecting rod in the region of the large connecting rod eye during the crank movement is prevented. The second valve 22 is less vulnerable to lift-off, since in the region of the maxima of the inertial forces higher closing forces than the sum of the oil pressure in the second high-pressure chamber 10 and the restoring force of the second valve spring 24 by acting on the second valve body. Thus, revolutions up to about 4000 U / min can be driven without mass force induced lifting of the valve body 20, 25.

Fig. 7 shows a fifth embodiment, in which also the second valve 22 is arranged inclined to the connecting rod 29. In detail, the second lifting axis 25a of the second valve body 25 is inclined at a first angle γ of approximately 90 ° +/- 60 ° to the longitudinal axis 29a of the connecting rod 29. In the exemplary embodiment illustrated in FIG. 7, both the first lifting axis 20a of the first valve body 20 and the second lifting axis 25a of the second valve body 25 are arranged in a normal manner on the longitudinal axis 29a of the connecting rod 29. Between the first valve body 20 and the connecting rod 29, an axially displaceable, substantially rod-shaped first transmission element 39 and between the second valve body 25 and the connecting rod 29, an axially displaceable, for example rod-shaped second transmission element 42 is arranged. The first displacement axis 39a of the first transmission element 39 is arranged coaxially to the first stroke axis 20a and the second displacement axis 42a of the second transmission element 42 is arranged coaxially with the second stroke axis 25a.

Notwithstanding Figure 6, the connecting rod 29 acts in the embodiment shown in Fig. 7 directly on the first and second transmission element 39, 42 a. The ends 29c and 29d of the connecting rod are conical or wedge-shaped, wherein the opening angle δ of the lateral surfaces 29e of the conical or wedge-shaped end 29c, 29d is for example 30 °. When moving the connecting rod is through the inclined lateral surfaces 29 e, the first and second transmission element 39, 42 and thus the corresponding first and second valve body 20, 25 against the restoring force of the first and second valve springs 19, 24 in the direction of the first and second Hubachse 20a, 25a deflected. A separate deflecting element and a deflection bore for receiving this is therefore not required here. In order to achieve the necessary stroke of the valve body 20, 25, the thickness of the connecting rod 29 should correspond to at least twice the stroke of the valve body 20, 25.

The guide part 35b serves to guide the connecting rod 29 and the second transmission element 42. Between the guide part 35b and the first rod part is formed, for example, an annular gap s (of 0.05 mm, for example), which on the one hand to supply the control chamber 33 and the two valves 17, 22 with oil, and on the other hand acts as a throttle, to prevent that occurring during opening of the second valve 22 pressure wave enters the system. The guide part 35b is fixed, for example by means of an inner locking ring 52 on the first rod part 4 and held in the correct position by means of a dowel pin 53 and secured against rotation.

The second valve body 25 of the second valve 22 is formed as an elongate rotary member and has on the side of the second valve seat 26 below a spherical portion 25 b, a pin-like extension 25 c, which contacts the second transmission element 42.

Reference numeral 51 denotes a stop member for the connecting rod 29, which has a ventilation opening 51a, to allow ventilation and leakage in the crankcase, not shown. The stop element 51 prevents the connecting rod 29 in the region of the second end 29d and the second transmission element 42 from coming out of engagement in the control or that the transmission element 42 falls into the receiving bore 29b of the displacement rod 29.

As shown in Fig. 8, a suitable tool 43 is frontally screwed into the housing 35 for disassembly of the control device 16 so that the connecting rod 29 is pushed against the restoring force of the return spring 32 in Fig. 8 to the left until the connecting rod 28 and a pin 43 a of the tool 43, the transmission elements 39, 42 entirely radially from the receiving bore 29 b of the connecting rod 29 pushes. The pin 43a holds the second transmission element 42 in the extended position and prevents the second valve spring 24 presses the second transmission element 42 in the guide member 35b, which would hinder its disassembly. After screwing in the tool 43, the housing 35 can thus be pulled out of the first rod part 4 with the tool 43.

In the sixth embodiment variant shown in FIG. 9, as in FIGS. 7 and 8, the lifting axles 20a, 25a of the first and second valve bodies 20, 25 are arranged inclined to the longitudinal axis 29a of the connecting rod 29. However, this sixth embodiment differs from the fifth embodiment in that - as in Fig. 4 - a clamping function for the control piston 31 is provided. For this purpose, a guide part 35a of the housing 35 is also provided here in the region of the first valve 17, which forms the control cylinder 30 for receiving the control piston 31. In the region of the control cylinder 30, an annular space 37a forming an annular space 37 is formed on the outer circumference, this annular space 37 being flow-connected via one or more connecting channels 38 to the second oil passage 12 and further to the second high-pressure space 10. Whenever high pressure prevails in the second high-pressure chamber 10, the guide part 35a of the housing 35 is deformed in the region of the control cylinder 30 in such a way that the control slide 31 is clamped and displacement of this due to pressure waves occurring is effectively prevented. Reference numeral 54 designates a locking element for positionally fixing the guide part 35b.

The control device 16 has a number of in the direction of the displacement axis 16 a of the control device 16 reciprocating parts, such as control piston 31, connecting rod 29 and valve body 20, 25. The displacement axis 16a of the control device 16 is arranged in the rocker plane ε and approximately normal to the longitudinal axis la of the connecting rod 1. During the rotation of the crankshaft, acceleration forces act on reciprocating parts of the control device 16, in particular on the control piston 31 against the force of the return spring 32. From a certain speed on the control piston 31 acting mass inertia forces are so great that finally the force of the return spring 32 is exceeded and the control piston 31 would be moved by the acceleration forces against the restoring force alone, resulting in a malfunction of the controller 16 and thus the Speed range for the adjustment of the connecting rod 1 would restrict.

In order to avoid this, at least one reciprocating part of the control device 16 may have at least one buoyancy body 60 or at least partially be designed as a buoyancy body. The buoyant body 60 may be formed as a hollow body or as a closed-cell foam body. The control device 16 shown in FIG. 10 differs from the control device shown in FIG. 5 in that at least one reciprocating part of the control device 16 is provided with buoyancy bodies 60, 61.

As shown in FIG. 10, at least one buoyant body 60 can be arranged in the region of the first end face 31a. Furthermore, a buoyant body 61 can also be arranged in the region of the second end face 31b of the control piston 31. In order for the buoyant body 61 to float in the oil, defined leaks are provided between the control chamber 33 and the spring space 32a containing the return spring 32.

Furthermore, the connecting rod 29 and / or the valve body 20, 25 may be designed as a buoyant body, for example as a hollow body.

As is further apparent from FIG. 10, the spring chamber 32a is connected via the venting line 44 to a storage space 62, which is connected via a throttle 63 to the crankcase of the crankcase (not shown). This allows an oil return in the crankcase space. Thus, the spring chamber 32a of the control piston 31 is always filled with the oil, since by the reciprocating movements of the control piston 31 always enough oil from the storage space 32 and / or can be sucked through the leaks. The throttle 63 allows damping of the movement of the control piston 16, whereby an opening of the first valve 17 and thus of the first high-pressure chamber 9 can be avoided by a deflection of the control piston 16 and the displacement rod 29 to follow from the second high-pressure chamber 10 returning pressure waves.

Due to the small clearance between control piston 31 and control cylinder 30 occur small - intended - leaks between the control chamber 33 and the spring chamber 32 a, whereby the buoyancy bodies 60, 61 are always largely surrounded by oil and swim. As a result, the well-known Archimedean principle that the static buoyancy of a body in a medium is just as great as the weight of the body displaced by the medium, is used. The lateral acceleration force, which would cause a lifting of the control piston 31 and the return spring 32 is thus substantially reduced, so that malfunction of the control device 16 can be avoided.

All described embodiments allow by the use of the buoyancy bodies 60, 61, the density of the entire system and the masses on which lateral accelerations act as a result of the crankshaft revolution to reduce substantially. Thus, by using the buoyancy bodies 60, 61, even without the force deflection of the connecting device 27 provided in FIGS. 6 to 8, engine speeds of more than 7000 rpm can be achieved without the function of the length-adjustable connecting rod 1 having to be restricted.

When cold starting, there is a desire for a high compression. However, there is a high oil pressure in the lubricating oil circuit in the cold state of the internal combustion engine, whereby the connecting rod 1 would be shortened, which precludes the desire for a high compression. FIGS. 11 and 12 show a solution to avoid this problem in that the connecting device 27 and / or the control piston 31 has at least one thermocouple 65, which changes the effective length of the connecting device 27 as a function of the operating temperature.

The connecting element 28 of the connecting device 27 is designed as a normal to the longitudinal axis la of the connecting rod 1, axially displaceable two-piece connecting rod 29 which is axially divided in the region of the control piston 31, wherein the thermocouple 65 between a first connecting rod portion 29a and a second connecting rod part 29b, in particular between the first connecting rod part 29a and the control piston 31 is arranged.

The thermocouple 65 has a shorter installation length in the cold state than in the warm state. Such thermocouples have a temperature-sensitive expansion element with, for example, oil, wax, hard paraffin or metal as a wax.

When cold, the thermocouple 65 compensates for the high control pressure in the cold lubricating oil circuit, which is why a shortening of the connecting rod 1 and thus lowering the compression at cold start is avoided. Due to the contracted expansion material of the thermocouple 65, the length of the connecting element 28 is shortened, which is why an opening of the first valve 17 is omitted and the pressure in the first high-pressure chamber 9 is maintained. Upon reaching the operating temperature, the expansion expands in the thermocouple 65, whereby the connecting element 28 reaches the necessary for the actuation of the first valve 17 normal length. The desired compression values can now be set according to the control of the engine map. For example, high compression is set for the low load range and low compression for the high load range.

The internal combustion engine is usually operated immediately before parking in the partial load and with high compression. When the engine is stopped, the high compression required for the cold start has been set.

To avoid that after prolonged rest period, the oil is pressed out of the first high-pressure chamber 9 by the piston weight, can be arranged between the first and second rod part 4, 5 of the connecting rod 1 acting in the direction of connecting rod extension spring element 66, which, for example, designed as a plate spring can be. By the spring element 66, the second rod part 5 of the connecting rod 1 is held in its upper position.

FIG. 12 shows a practical embodiment of the arrangement shown schematically in FIG. 11 with a thermocouple 65 in the divided connecting rod 29 between the first connecting rod part 19a and the control piston 31 and one in the first high pressure chamber 9 between the first rod part 4 and In this case, the piston element 6 of the second rod part 5 in the left half of the image in its high compression ratio associated upper position and in the left half of its low compression ratio associated lower position is shown with compressed spring element 66.

13 schematically shows a control device 16, which differs from FIGS. 2 a and 2 b in that a first throttle device 71 is arranged in the first oil passage 11 between the first valve 17 and the first high-pressure chamber 9. Furthermore, a second throttle device 72 is disposed between the second valve 22 and the second high pressure chamber 10 in the second oil passage 11. By the throttling devices 71 and 72 pressure waves can be braked, which deflect the control device 16, in particular the valves 17, 22 could open. In particular, in a length adjustment of the connecting rod 1, a spreading of pressure waves from the high-pressure chambers 9, 10 are prevented in the rest of the oil system of the vehicle and resulting damage.

In order nevertheless to allow a rapid filling of the first high-pressure chamber 9, the first throttle device 71 can be bypassed via a first bypass channel 73, wherein in the first bypass channel 73, a first bypass valve 75 is arranged, which is formed for example by a 9 opening in the direction of the first high-pressure chamber check valve is. The first bypass channel 75 may originate from the oil supply channel 13 or from the first connection channel 14 and flows into the first oil channel 11 or into the first high-pressure chamber 9 downstream of the first throttle device 71. Similarly, the second throttle device 72 may be formed by a bypass passage 76, which emanates from the oil supply channel 13 or the second connection channel 15 and downstream of the second throttle device 72 opens into the second oil passage 12. Furthermore, in the second bypass channel 74, a first bypass

Valve 75 is arranged, which is formed for example by a in the direction of the second high-pressure chamber 10 opening check valve.

Variants are possible with only a first throttle device 71 or a second throttle device 72, or both a first 71 and a second throttle device 72, each without bypass channel 73, 74 or in combination with at least one bypass channel 73, 74. Figs. 14 and 15 show a constructive embodiment of the scheme shown in Fig. 13.

16 and 17 show relative displacements h of the two rod parts 4, 5 to each other, and the pressure curves p9 and pi0 in the first high pressure chamber 9 and second high pressure chamber 10, plotted against the crank angle KW for an extension and shortening of the connecting rod 1, FIG. 17 shows a full-load operation of the internal combustion engine at an engine speed of 2000 rpm and FIG. 18 shows a light-load operation of the internal combustion engine at an engine speed of approximately 4000 rpm. It can clearly be seen that in Fig. 17, the maximum length (h = 3 mm) of the connecting rod 1 after about four cycles and the minimum length (h = 0 mm) of the connecting rod are achieved after a duty cycle. In Fig. 18, the maximum length (h = 3 mm) of the connecting rod 1 is reached after about three working cycles and the minimum length (h = 0 mm) of the connecting rod after about five working cycles.

Claims (30)

1. Length-adjustable connecting rod (1) for a reciprocating engine, with at least one first rod part (4) and a second rod part (5), which two rod parts (4, 5) telescopically zoom in and / or into each other, wherein one of the two rod parts (5) form a guide cylinder (8) and the other rod part (4) in the guide cylinder (8) longitudinally displaceable piston member (6), wherein between a first end face (6a) of the piston member (6) and the guide cylinder (8) a first high-pressure chamber (9) and between a second end face (6b) of the piston element (6) and the guide cylinder (8) a second high-pressure chamber (10) is clamped, wherein in the first high-pressure chamber (9) a first oil passage (11) and in the second high-pressure chamber (10) opens a second oil passage (12), and the oil passages (11, 12) by a control device (16) with at least one oil supply passage (13) are flow connected, characterized in that the control Device (16) a first valve (17) and a second valve (22) each having a in a valve chamber (18; 23) is pressed by a restoring force against a valve seat (21; 26), wherein a first valve space (18) of the first valve (17) with the first oil passage (11) and a second valve space (23) of the second valve space (23) is fluidly connected to the second oil passage (12), and the valve bodies (20; 25) via a at least between a first position and a second position displaceable, at least one connecting element (28) having connecting means (27 In the first position, the first valve body (20) and in the second position, the second valve body (25) by the connecting means (27) respectively against the restoring force of an associated first and second valve seat (21; ) and the corresponding first or second valve chamber (18; 23) can be connected to the oil supply channel (13), and in each case in the other position on the first n and second valve seat (21; 26) rests and blocks the flow connection to the oil supply channel (13). Second connecting rod (1) according to claim 1, characterized in that the connecting element (18) with a in a control cylinder (30) displaceable control piston (31) is fixedly connected to a control chamber (33), in which a - preferably with the oil supply channel (13) flow-connected - opens control line (34). 3. connecting rod (1) according to claim 1 or 2, characterized in that the valve body (20, 25) and the connecting means (27) are separate components, wherein the connecting means (27) in the first position of the second valve body (25) and in the second position from the first valve body (20) is spaced. 4. connecting rod (1) according to one of claims 1 to 3, characterized in that the connecting element (28) as preferably normal to the longitudinal axis (la) of the connecting rod (1) arranged axially displaceable connecting rod (19) is formed. 5. connecting rod (1) according to claim 4, characterized in that the first lifting axis (20a) of the first valve body (20) is formed coaxially with the longitudinal axis (29a) of the connecting rod (29), wherein the first valve (17) in the area a first end (29c) of the connecting rod (29) is arranged. 6. connecting rod (1) according to claim 4 or 5, characterized in that the second lifting axis (25 a) of the second valve body (25) is formed coaxially with the longitudinal axis (29 a) of the connecting rod (19), wherein the second valve (22). in the region of a second end (29d) of the connecting rod (29) is arranged, and wherein preferably the first valve seats (21) of the first valve (17) and the second valve seat (26) of the second valve (22) facing away from each other. 7. connecting rod (1) according to one of claims 4 to 6, characterized in that the first lifting axis (20a) of the first valve body (20) at a first angle (a) of about 90 ° +/- 60 ° to the longitudinal axis (29a ) of the connecting rod (29) is arranged inclined. 8. connecting rod (1) according to claim 7, characterized in that between the first valve body (20) and the connecting rod (19) at least one preferably rod-shaped first transmission element (39) is arranged axially displaceable, wherein particularly preferably the first displacement axis (39 a) of the transmission element (39) is arranged coaxially with the first stroke axis (20a) of the first valve body (20). 9. connecting rod (1) according to any one of claims 7 or 8, characterized in that the second lifting axis (25 a) of the second valve body (25) at a second angle (γ) of about 90 ° +/- 60 ° to the longitudinal axis (29 a ) of the connecting rod (29) is arranged inclined. 10. connecting rod (1) according to claim 9, characterized in that between the second valve body (25) and the connecting rod (29) at least one preferably rod-shaped second transmission element (42) is arranged axially displaceable, wherein preferably the second displacement axis (42 a) of the second transmission element (42) is arranged coaxially with the second stroke axis (25a) of the second valve body (22). 11. connecting rod (1) according to one of claims 8 to 10, characterized in that between the first transmission element (39) and the connecting rod (29) and / or between the second transmission element (42) and the connecting rod (29) at least one preferably Spherical deflecting element (40) is arranged, particularly preferably the deflecting element (40) in one of the receiving bores (29b, 39b, 42b) of the connecting rod (29) and the first and second transmission element (39, 42) connecting and at an angle ( ß) greater than 0 ° to this inclined deflection bore (41) is arranged. 12. connecting rod (1) according to one of claims 8 to 11, characterized in that the connecting rod (29) in at least one position directly on the first and second transmission element (39, 42) acts. A connecting rod (1) according to any one of claims 4 to 12, characterized in that at least one end (29c, 29d) of the connecting rod (29) is conical or spherical in shape. 14. connecting rod (1) according to one of claims 8 to 13, characterized in that at least one end of the first and / or second transmission element (39, 42) is conical or spherical. 15. connecting rod (1) according to one of claims 1 to 14, characterized in that the control cylinder (30) at its outer periphery preferably by a circumferential annular groove (37 a) formed annular space (37) which communicates with the control chamber (33) or a high pressure chamber (10) is fluidly connected. 16. connecting rod (1) according to one of claims 1 to 15, wherein the control device (16) at least one displaceable in the direction of a displacement axis (16 a) mounted part, and wherein the displacement axis (16 a) in a rocker plane (ε) of the connecting rod ( 1) - preferably normal to the longitudinal axis (la) of the connecting rod (1) - is arranged, characterized in that at least one reciprocating part of the control device (16) at least one buoyant body (60, 61) or at least partially as a buoyant body ( 60, 61) is formed. 17. Connecting rod (1) according to claim 15, characterized in that the buoyant body (60, 61) has a lower density than the actuating medium, preferably engine oil. 18. connecting rod (1) according to claim 16 or 17, characterized in that at least one buoyant body (60, 61) is designed as a hollow body. 19. connecting rod (1) according to one of claims 16 to 18, characterized in that at least one buoyant body (60, 61) as a closed-cell foam body, preferably made of polystyrene, is formed. 20. Connecting rod (1) according to any one of claims 16 to 19, characterized in that the buoyancy body (60, 61) fixedly connected to the reciprocating part or is formed integrally therewith. 21, connecting rod (1) according to one of claims 16 to 20, wherein a reciprocating part of the control device (16) by a in a control cylinder (30) slidably mounted control piston (31) is formed, the first end face (31 a) a control chamber (33) which can be acted upon by the actuating medium and whose second end face (31b) adjoin a spring space (32a) having a return spring (32), characterized in that at least one buoyancy body (60, 61) in the region of the first end face (31a) and / or in the region of the second end face (31b) of the control piston (31) is arranged, wherein preferably the control piston (31) between the control chamber (33) and the spring chamber (32a) has defined leaks. 22 connecting rod (1) according to claim 21, characterized in that the spring chamber (32 a) with a storage space (62) is fluidly connected, wherein preferably the storage space (62) in the same rod part (4) of the connecting rod (1) as the control device ( 16) is arranged. 23 connecting rod (1) according to claim 22, characterized in that the storage space (62) via a throttle (63) is connected to a crank chamber. 24. Connecting rod (1) according to any one of claims 16 to 23, characterized in that the connecting device (27) has at least one buoyancy body or at least partially formed as a buoyant body. 25. Connecting rod (1) according to claim 24, characterized in that at least one valve body (20, 25) has at least one buoyancy body or is at least partially designed as a buoyant body. 26. Connecting rod (1) according to one of claims 1 to 25, characterized in that the connecting device (27) and / or the control piston (31) has at least one thermocouple (65). 27 connecting rod (1) according to claim 26, characterized in that the connecting element (28) of the connecting device (28) as a preferably normal to the longitudinal axis (la) of the connecting rod (1) arranged axially displaceable connecting rod (29) is formed, which - Preferably in the region of the control piston (31) - axially divided, wherein the thermocouple (65) between a first connecting rod part (29 a) and a second connecting rod part (29 b), particularly preferably between the first connecting rod part (19 a) and the control piston (31) is arranged. 28 connecting rod (1) according to one of claims 1 to 27, characterized in that between the first connecting rod part (19 a) and the second connecting rod part (19 b) acting in the direction of connecting rod extension spring element (66) is arranged, wherein preferably the spring element (66 ) is designed as a plate spring. 29 connecting rod (1) according to one of claims 1 to 28, characterized in that in the first oil passage (11) at least a first throttle device (71) and / or in the second oil passage (12) at least a second throttle device (72) is arranged, wherein preferably the first throttle device (71) and / or the second throttle device (72) by a first bypass passage (73) and a second bypass passage (74) is bypassed. 30. connecting rod (1) according to claim 29, characterized in that in the first bypass channel (73) and / or second bypass channel (74) preferably designed as a check valve first bypass valve (75) and second bypass valve (76) is arranged. 2015 06 18 Fu