Length adjustable connecting rod

专利摘要:
The invention relates to a length-adjustable connecting rod (1) for a reciprocating engine, in particular internal combustion engine, with at least a first and a second rod part (2, 4), which two rod parts (2, 4) telescopically and / or slidable, wherein the second rod part (4) a guide cylinder (4a) and the first rod part (2) in the guide cylinder (4a) longitudinally displaceable piston element (3), wherein between the first and the second rod part (2, 4) a high-pressure chamber (4b) is clamped into which at least one oil channel (10) opens. In order to enable an adjustment of the compression ratio in the simplest and most reliable manner, it is provided that the two rod parts (2, 4) can be fixed relative to each other by a locking device (32) in at least one position preferably corresponding to a minimum length of the connecting rod (1) ,
公开号:AT513054A1
申请号:T50220/2013
申请日:2013-04-02
公开日:2014-01-15
发明作者:
申请人:Avl List Gmbh；
IPC主号:

专利说明:

The invention relates to a length-adjustable connecting rod for a reciprocating engine, in particular internal combustion engine, with at least a first and a second rod part, which two rod parts telescopically zu- and / or slidable, wherein the second rod part a guide cylinder and the first rod part a longitudinally displaceable in the guide cylinder piston member forms, between the first and the second rod part a high-pressure chamber is spanned, opens into the at least one first Ölkanai.
DE 101 51 517 A1 describes a variable length piston and connecting rod assembly for generating a variable compression ratio in an internal combustion engine having a first part and a second part coupled to a length change mechanism received between the parts. The length change mechanism has a frusto-conical spring washer and an elastomeric mass which bears against a concave surface of the spring washer.
Further connecting rods, each with a hydraulic telescopic mechanism for adjusting the connecting rod length, are known from the documents FR 2 857 408 A1, EP 1 243 773 A1, WO 02/10568 A1, DE 198 35 146 A1, US Pat. No. 4,370,901 A, US Pat. No. 4,195,601 A, US 4,124,002 A and US 2,134,995 A.
By changing the compression, full load can be driven with lower compression ratio, and part load and start with increased ratio. In the partial load range, the consumption is improved, the compression pressure is increased with the increased compression ratio at the start, and the peak pressure is reduced with a reduced ratio at high power and knocking is prevented.
It is known to use an eccentric piston pin or an eccentric crankpin crankshaft to adjust the compression ratio.
Furthermore, it is known to lift the entire cylinder block to change the compression ratio or to lower the entire crankshaft bearing with an eccentric bearing in the same crankcase.
All these proposals require a high level of design and control engineering effort.
Bi BEB1 2
The object of the invention is to avoid these disadvantages and to provide a simple and reliable solution for the change in the compression ratio.
According to the invention this is achieved in that the two rod parts in at least one preferably a minimum length of the connecting rod corresponding position by a locking device are fixed relative to each other.
The variable compression is achieved by making the rod length smaller at low load and smaller at higher load. This results in higher or lower compression ratios depending on the load. The effect is that at low load the higher compression ratio increases efficiency and at higher load the peak pressure does not get too high. The adjustment is made via the oil pressure of the internal combustion engine.
In this case, in the high-load phase, the Koibenelement be raised from its lower position, which can lead to suppression and thus cavitation phenomena in the high-pressure chamber.
In order to avoid cavitation phenomena, the two rod parts are fixed in the position corresponding to the minimum length of the connecting rod by the locking device relative to each other. It is particularly advantageous if the locking device has a movable stop element, which is arranged transversely to the connecting rod axis in a transverse bore of the piston element, preferably against the force of a return spring slidably. The stop element may have at least one wedge surface inclined with respect to a normal plane to the connecting rod axis, which cooperates with a counter surface of the piston element which is preferably formed parallel to the wedge surface, the wedge surface preferably facing the high-pressure chamber.
For actuation of the stop element, it is advantageous if the stop element has a displaceably mounted in a cylinder stop piston or is connected thereto, wherein between stop piston and stop cylinder via at least one filling bore can be acted upon with oil pressure chamber. 3
In a preferred embodiment of the invention, it is provided that the wedge surface is designed to be split and has two parallel part wedge surfaces adjacent to one another in the direction of the axis of the transverse bore, wherein a shoulder is formed between the two part wedge surfaces. The piston member is supported in the unlocked position with its counter surface on the wedge surface parallel to the first part wedge surface second part, whereby the surface pressure can be kept relatively small by inertial force.
In order to save space and make the connecting rod as compact as possible, it is particularly advantageous if the axial extent of the wedge surface or at least a part wedge surface and / or the mating surface - preferably by at least 1/4, more preferably at least 1/3 - is lower, as the thickness of the piston element, both measured in the direction of the axis of the transverse bore. This makes it possible to keep the dimensions of the return spring and the piston travel of the stop piston very small, whereby a required safety distance to the surrounding cylindrical surface can be maintained.
Furthermore, the pressure chamber can be connected to at least one drain hole.
In a variant of the invention, the axis of the transverse bore is normal to a Pleuelschwingebene formed normal to the Pleuelaugenachsen-preferably normal to the longitudinal axis of the connecting rod. This allows a large clearance to the surrounding cylinder in the rocker plane.
Is normal to the swing plane - so in the direction of the Pleuelaugenachsen little space, for example due to the rotating crank webs of the crankshaft available, it may be advantageous to arrange the axis of the transverse bore in the swing plane of the connecting rod - preferably normal to the longitudinal axis of the connecting rod.
Advantageously, the transverse bore in the small connecting rod having upper third of the connecting rod is arranged. This causes particularly small deflections of the stop element.
In order to allow a simple control of the change in the compression ratio, at least one valve, preferably a control valve, is arranged in the first oil passage, which preferably has a first position and a second position
Position, wherein in the first position, the first oil passage closed, and in the second position, the first oil passage is opened.
In a simple embodiment of the invention, it is provided that the valve is designed as a ball valve with a valve ball and a piston pin axially displaceable in a receiving bore, which together with valve ball by a return spring in a first position and by oil pressure against the force of the return spring in a second position is displaceable.
Alternatively, it can also be provided that the valve is designed as a control valve with an axially displaceable in a receiving bore actuator piston, which is displaceable by a return spring in a first position and by oil pressure against the force of the return spring in a second position, preferably in the first position, the first oil passage is closed and opened in the second position.
A simple control results when the first oil channel is formed as an inflow and outflow channel, preferably in the high-pressure chamber a second oil channel formed as a feed channel opens, in which a non-return valve opening in the direction of the high-pressure chamber is arranged.
In the receiving bore opens a preferably connected to the connecting rod bearing oil supply channel, wherein particularly preferably in the oil supply channel, a throttle point is arranged. As a result, a negative pressure wave resulting from the suction by the inertial force of the first rod part can be weakened with respect to the oil in the connecting rod bearing. In this case, the second Ölzuführkanal from the receiving bore of the control valve or the Ölversorgungskana] go out.
In a manufacturing technology simple embodiment of the invention it is provided that the receiving bore is formed by a bore transverse to the longitudinal axis of the connecting rod. A particularly compact design can be achieved if the valve is arranged in the region of a large pie lug of the connecting rod.
A simple control of the stop element is achieved when the filling bore is controllable by the control piston of the control valve, wherein the 5 filling bore is opened in the second position of the actuating piston and closed in the first position of the actuating piston.
It when the drain hole is controlled by the actuating piston of the control valve, wherein the drain hole is opened in the first position of the actuating piston and closed in the second position of the actuating piston is particularly advantageous.
The invention will be explained in more detail below with reference to FIGS. Show it
Fig. 1 is a connecting rod according to the invention in a first
Embodiment variant in a section along the line I -1 in Fig. 2 in a first switching position,
2 shows this connecting rod in a section along the line II - II in Fig. L,
3 this connecting rod in the locked position in a section along the line III - III in Fig. 1,
4, the connecting rod in a section analogous to FIG. 1 during a second switching position,
5 shows a partial section of the longitudinal section of the connecting rod analogous to FIG. 2 in a second switching position in the unlocked position, FIG.
Fig. 6 is a connecting rod according to the invention in a second
Embodiment in a section along the line VI - VI in Fig. 7 in a first switching position in the locked position,
7 shows this connecting rod in a section along the line VII - VII in Fig. 6,
8, this connecting rod in a section along the line VIII - VIII in Fig. 6,
9, this connecting rod in a section along the line IX - IX in Fig. 6, 6th
10 is a connecting rod according to the invention in a third
Embodiment variant in a section analogous to FIG. 6 in a first switching position in the locked position and
Fig. 11, this connecting rod in a second switching position in the unlocked position.
Functionally identical parts are provided in the embodiments with the same reference numerals.
In the figures, a two-part connecting rod 1 of an internal combustion engine is shown in each case. In the upper first rod part 2, a cylindrical piston element 3 is pressed. The lower part of this piston element 3 is seated with play in a guide cylinder 4a of the lower second rod part 4 of the connecting rod 1, wherein between the piston member 3 and the second rod part 4 in at least one position of the two rod parts 2, 4, a high-pressure chamber 4b is clamped. An adjacent to the high-pressure chamber 4b pressure-side lower end face 5 of the piston member 3 can be acted upon with engine oil. The oil supply and the drain via a bore, which acts as a first oil passage 10. The oil supply, lock and drain of the oil is controlled by a control valve 6 via the oil pressure at the oil pump not shown by means of a pressure control valve, also not shown. An unillustrated actuator biases a spring in the control valve of the oil pump more or less. The longitudinal axis of the connecting rod 1 is denoted by la.
In principle, the control valve 6 can be designed as desired. Below, two embodiments are described in detail. The control valve 6 can - as shown in FIGS. 1 to 9 - be formed with an axially displaceable in a receiving bore 7 actuating piston 6a. But it is also possible, alternatively, the control valve 6 as a ball valve 60 with a valve ball 61 and a receiving bore 62 axially displaceable cylinder pin 63 form, as shown in FIGS. 10 and 11 and will be described in detail below.
Fig. 1 and 2 shows the connecting rod 1 in a first embodiment in a low compression ratio associated with the first position and Fig. 4 and 5 in a high compression ratio associated second position. 7
The adjusting piston 6 a in the control valve 6 according to the first embodiment is designed with a cylinder jacket 11 having an inner bore 27 and arranged together with a return spring 9 in the receiving bore 7. The receiving bore 7 has a first 8 and a second stop 24. The first stop 8 is formed by a locking screw 45 and at least one projection 46 on the end face of the actuating piston 6a.
The adjusting piston 6a is pressed in its through a bore transverse to the longitudinal axis la of the connecting rod 1 formed receiving bore 7 by the force of the return spring 9 at low oil pressure level against the first stop 8, as shown in Fig. 4 can be seen. The phrase " drilling transverse to the longitudinal axis " here comprises both holes normal to the longitudinal axis la, as well as holes which are inclined at a certain angle to the longitudinal axis la. The engine oil is sucked by the inertial force via a check valve 16 arranged in a second oil passage 15 (for example a small ball 16a in the illustrated embodiment) under the end face 5 of the piston 3. The steep piston 6a locks with its cylinder jacket 11 the first oil passage 10 forming an inlet and outlet opening.
The sucked oil can not escape and is not compressible. As a result, the piston member 3 is lifted and the connecting rod 1 thus longer. In this way, a higher compression ratio can be set at normal and low oil pressure.
If now the control pressure of the oil pump is increased, the actuating piston 6a, as is shown in FIG. 1, is pressed in its receiving bore 7 by the engine oil against the second stop 24, which is formed by the spring guide 25. The return spring 9 is compressed. A connecting opening 10a of the first oil passage 10 for the engine oil from the connecting rod bearing 30 to the end face 5 is opened by the adjusting piston 6a. In this position, the gas pressure from the not further apparent combustion chamber pushes the piston element 3 all the way down, which sets a smaller compression ratio. The end face 5 of the piston element 3 presses the engine oil out of the high-pressure space 4b.
It is particularly advantageous that even in a lower idle range of the internal combustion engine, when the engine oil pressure is less than the control pressure, a higher compression ratio can be adjusted, which improves consumption in the low load range and facilitates a cold start. To the high 8
To maintain compression ratio for a long time, the leakage losses must be refilled by the play seat of the guide cylinder 4 a from the high-pressure chamber 4 b under the end face 5 of the piston member 3 in the same. This happens because the mass force sucks the engine oil from the inner bore 27 of the actuating piston 6a via the check valve 16 (refill valve) into the high-pressure chamber 4b under the end face 5. During the subsequent compression stroke, the high pressure builds up again and the small ball 16a in the check valve 16 prevents the escape of the oil from the high-pressure chamber 4b. This process is repeated every working cycle. If you want to lower the compression ratio again, the control pressure of the oil pump is increased and the actuator piston 6a pressed by the oil pressure against the second stop 24 and the connection opening 10a to the connecting rod 30 thus opened. The gas pressure pushes the piston member 3 down and the lower compression ratio is reset. The adjusting piston 6a is reciprocated in its receiving bore 7 by the oil pressure and the return spring 9 between the stops 8 at low oil pressure and 24 at high oil pressure.
The oil supply to the receiving bore 7 of the actuating piston 6a and its inner bore 27 via an oil supply channel 17. This opens into a groove 19, in the base bore 18 of the connecting rod bearing shell 20 of the connecting rod bearing 30. This groove 19 in the connecting rod 1 is provided with a groove in the not shown lower shell of the connecting rod bearing 30 fluidly connected.
In order to attenuate the vacuum wave, which arises during suction by the inertial force, with respect to the oil in the groove 19, a throttle 28 is installed in the supply bore 17.
In all embodiments, the two rod parts 2, 4 can be fixed by a locking device 32 according to the invention in one of the minimum length of the connecting rod 1 corresponding position. The locking device 32 has for this purpose a stop element 33 with stop piston 38, wherein the stop element 33 is displaceably arranged in a transverse bore 35 of the piston element 3 against the force of a stop return spring 36. The stop piston 38 is slidably mounted in a stop cylinder 40, wherein between stop piston 38 and stop cylinder over at least a 9 filling bore 43, 43 a, 43 b acted upon with oil pressure chamber 42 is formed.
With 40a is a stopper cylinder 40 closing closure screw referred to.
The movable stop element 33 is provided on its underside facing the high-pressure chamber 4b with a wedge surface 37 inclined to a normal plane τ on the longitudinal axis 1a of the connecting rod 1, which has an inclination which is somewhat greater than that of the self-locking. This wedge surface 37 actively pressed by the increased oil pressure at higher load over the stopper cylinder 40 slidably guided stop piston 38 against - in the embodiment according to the wedge surface 37 wedge-shaped, the pressure chamber 42 facing away - counter surface 39 of the piston element 3 and this thus against the by the Bottom 41 of the high-pressure chamber 4b end stop formed. In this end position, the pressure chamber 42 formed in the embodiment by a base of the stop cylinder 40 and one of these facing end of the stop piston 38 is connected by the stopper piston 38 via the filling holes 43, 43a, 43b with the oil-carrying groove 19, 22 in the connecting rod bearing 30. The Steltkofben 6ä the control valve 6 is pressed by the oil pressure against the second stop 24 of the spring guide 25 of the return spring 9. The actuating piston 6a releases the filling bore 43 and closes the drainage bore 44 from the pressure chamber 42. 40a denotes a closure screw.
In the case of light load, the oil pressure is lowered. In this case, the return spring 9 pushes the actuating piston 6a to the left against the first stop 8, which is formed by the locking screw 45 and at least one projection 46 on the end face of the actuating piston 6a. In this position, he blocks the filling hole 43 and releases the drain hole 44. The oil now passes from the pressure chamber 42 via the holes 44, 44a and 44b and the opening 47 in the spring guide 25 (or spring plate) in the - not dargestelite - unpressurized engine inside. In this case, the stop restoring spring 36 can expand again and pushes on the spring plate 36a, the movable stop member 33 in Fig. 2 to the left until the spring plate 36a is present on the piston member 3, as shown in Fig. 5 can be seen. In this position, the wedge surface 37 is pushed away from the piston member 3 and the piston member 3 is lifted by the oil, which is sucked by the inertial force until it on a cylindrical portion 48 of the movable 10th
Stop element 33 abuts. This results in a longer connecting rod 1 and a higher compression ratio is set.
In the embodiment shown in Fig. 10 and Fig. 11, the wedge surface 37 is made split and has two successively arranged in the direction of the axis 35a of the transverse bore 35, formed parallel to the counter surface 39 TeilkeiEflächen 37a, 37b, wherein between the two part wedge surfaces a paragraph 37c is formed. The paragraph 37c forms a low-voltage transition between the two part wedge surfaces 37a, 37b. The piston element 3 is supported in FIG. 11 with its wedge surface 39 on a second part wedge surface 37b adjacent to the first part wedge surface 37a. As a result, excessive surface pressure due to the inertial force in the unlocked position shown in FIG. 11 can be avoided. If the stop element 33 holds the piston element 3 in the case of low compression, the stop element 33 pushes in the axial direction (or in the direction of the axis 35a of the transverse bore 35) until a frictional connection between the wedge surface 37a and the piston element 3 on the one hand and the piston element 3 and the bottom 41 of the high-pressure chamber 4b on the other hand is reached. in the fold of the high compression, the stop element 33 ~ of dei -------
Stop return spring 36 is pressed against the locking screw 40a of the bore 40, or the stop member 33 is moved so far until the spring plate 36a is present on the piston element 3. The piston element 3 is now pressed by the oil pressure against the wedge surface 37b.
When the load rises again, the pressure control valve of the oil circuit, not shown, is adjusted by a servo motor, not shown, and the oil pressure is increased. Thus, the adjusting piston 6a of the control valve 6 is again pressed to the right against the second stop 24. He is again the filling hole 43 free and the drain hole 44 is closed.
The pressure rises in the pressure chamber 42 and the movable stop member 33 is pushed to the right until the wedge surface 37 presses the piston member 3 again against the end stop formed by the bottom 41 of the high-pressure chamber 4b. In this position, the connecting rod 1 is shorter and a higher compression adapted lower compression ratio is set.
The position of the movable stop element 33 is as high as possible below the adjacent to the combustion chamber piston (not dargestelit) selected. 11
The orientation of the axis 35a of the transverse bore 35 may be perpendicular to the swing plane ε of the connecting rod 1, as shown in FIGS. 1 to 5. This results in a smaller deflection of the stop element 33 than at a lower position and a different orientation of the axis 35a. In the event that the lower edge of the piston skirt of a piston not shown is located above the movable stop member 33, the line 49 in Fig. 3, Fig. 6 and Fig. 7 represents the smallest possible cylinder bore. If the position of the movable 3 is the inner contour of the smallest possible piston. Under the swing plane ε here is the longitudinal axis la of the connecting rod 1-containing plane understood, which is normal to the axis 12a, 13a of the small or large Pleuelauges 12,13 runs. The small Pleuetauge 12 is used for connection to a - not shown - piston, the large connecting rod 13 for connection to a - not shown - crankshaft.
In some cases, for example in the case of short-stroke reciprocating engines with relatively large crank arm radii, it may be advantageous to arrange the axis 35a of the transverse bore 35 in the oscillating plane ε of the connecting rod 1, as shown in FIGS. 6 to 9. As a result, the connecting rods can be made quite slim in the direction of the Pleuelaugenachsen. In order to keep the width of the connecting rod 1 in the deflection direction of the stop element 33 as small as possible, it may be advantageous, the axial extent a of the wedge surface 37, 37a and the counter surface 39 is lower - for example, at least 1/4, or 1/3 smaller than the thickness b of the piston member 3, both measured in the direction of the axis of the transverse bore, as shown in Fig. 6 can be seen. The filling and discharge bores 43, 44 are arranged in this variant on both sides outside of the longitudinal axis la of the connecting rod l extending rocking plane ε of the connecting rod 1, as .in Fig. 8 and 9 is shown.
10 and Fig. 11 show a variant with a second embodiment of the control valve 6, which differs from the embodiment shown in FIGS. 6 to 9 in that the control valve 6 as a ball valve 60 with a valve ball 61 and a in a receiving bore 62 axially displaceable cylinder pin 63 is formed, which together with the valve ball 61 by a return spring 64 in a first position and by oil pressure against the force of the return spring 64 is displaceable in a second position. Between the 12th
High-pressure chamber 4b and the receiving bore 62 is the first oil passage 10, which is formed by an outgoing in the bottom of the high-pressure chamber 4b blind hole, in which a tap hole for receiving bore 62 is located. The tap hole opens into the receiving bore 62, in which the axially displaceable cylinder pin 63 is arranged, softer on its valve ball 61 facing the end of a pin 65 which engages the valve ball 61. The receiving bore 62 (or also the high-pressure chamber 4b via the first oil passage 10) is connected to the supply of engine oil via a connecting opening 10a and bore (s) 67 with the connecting rod bearing 30.
At low oil pressure, the return spring 64 presses the valve ball 61 and the cylinder pin 63 with the pin 65 against the intersection of the first oil passage 10 with the receiving bore 62 for the cylinder pin 63 and seals the high-pressure chamber 4b below the piston element 3 (first position of the control valve 6) , By the inertial force, the piston member 3 is raised and the valve ball 61 is lifted from the valve seat, whereby oil enters the high-pressure chamber 4b. A run in the first oil passage 10 stop 66 prevents the Vefltilkuget 61 leaves the oil passage 10 (second position of the control valve 6). When the oil pressure exceeds its shift value, the cylinder bolt 63 is pushed to the right in Figs. 10 and 11, and the valve ball 61 releases the drain port 10a from the high pressure space 4b. The high-pressure oil (which has about 20 times the combustion chamber pressure) passes through the holes 67 in the filling bore 43 and from there into the pressure chamber 42 of the stop element 33, which is pushed by this pressure to the right and the piston rod 3 of the rod part 2 holds force-fit.
When the oil pressure is lowered, the return spring 64 expands and the valve ball 61 returns to the position where it seals the high pressure space 4b. During every second downward stroke, the rod part 2 together with the piston rod 3 is pulled upwards and the valve ball 61 is lifted, as a result of which the high-pressure space 4b is filled with oil and a higher compression sets in.

权利要求:
Claims (23)
[1]
13 PATENT CLAIMS 1. Length-adjustable connecting rod (1) for a reciprocating engine, in particular internal combustion engine, with at least a first and a second rod part (2, 4), which two rod parts (2, 4) telescopically zu-and / or slidable, wherein the second rod part (4) a guide cylinder (4a) and the first rod part (2) in the guide cylinder (4a) longitudinally displaceable piston element (3), wherein between the first and the second rod part (2, 4) a high-pressure chamber (4b) is clamped , in which at least one first oil passage (10) opens, characterized in that the two rod parts (2, 4) in at least one preferably a minimum length of the connecting rod (1) corresponding position by a locking device (32) are fixed relative to each other.
[2]
Second connecting rod (1) according to claim 1, characterized in that the locking device (32) comprises a movable stop element (33) which transversely to the longitudinal axis (la) of the connecting rod (1) in a transverse bore (35) of the piston element (3). is preferably arranged displaceably against the force of a return spring (36).
[3]
3. connecting rod (1) according to claim 2, characterized in that the stop element (33) has at least one with respect to a normal plane (τ) on the longitudinal axis (la) of the connecting rod (1) inclined wedge surface (37, 37a, 37b) which with a preferably parallel to the wedge surface (37, 37a, 37b) formed mating surface (39) of the piston element (3) cooperates, wherein preferably the wedge surface (37, 37a, 37b) facing the high-pressure chamber (4b).
[4]
4. Connecting rod (1) according to claim 3, characterized in that, the wedge surface (37) is designed divided and two parallel to the counter surface (39) formed in the direction of the axis (35 a) of the transverse bore (35) juxtaposed part wedge surfaces (37 a , 37b), wherein a shoulder (37c) is formed between the two part wedge surfaces. 14
[5]
5. connecting rod (1) according to claim 3 or 4, characterized in that the axial extent (a) of the wedge surface (37) or at least a part wedge surface (37 a, 37 b) and / or the mating surface (39) - preferably at least 1 / 4, more preferably at least 1/3 - smaller than the thickness (b) of the piston element (3), both measured in the direction of the axis (35a) of the transverse bore (35).
[6]
6. connecting rod (1) according to one of claims 2 to 5, characterized in that the stop element (33) in a stop cylinder (40) slidably mounted stop piston (38) or is connected thereto, wherein between stop piston (38) and Stop cylinder (40) via at least one filling bore (43, 43 a, 43 b) can be acted upon with oil pressure chamber (42).
[7]
7. Connecting rod (1) according to claim 6, characterized in that the pressure chamber (42) with at least one drainage bore (44, 44 a, 44 b) is flow connected.
[8]
8. connecting rod (1) according to one of claims 2 to 7, characterized in that the transverse bore (35) in a small connecting rod eye (12) having upper third of the connecting rod (1) is arranged.
[9]
9. connecting rod (1) according to one of claims 2 to 8, characterized in that the axis (35 a) of the transverse bore (35) normal to a swing plane (ε) of the connecting rod (1) - preferably normal to a longitudinal axis (la) of Connecting rod (1) - is arranged.
[10]
10. connecting rod (1) according to one of claims 2 to 8, characterized in that the axis (35 a) of the transverse bore (35) in a rocker plane (e) of the connecting rod (1) - preferably normal to a longitudinal axis (la) of the connecting rod (1) - is arranged.
[11]
11. connecting rod (1) according to one of claims 1 to 10, characterized in that in the first oil passage (10) at least one valve, preferably a control valve (6) is arranged. 15
[12]
12. connecting rod (1) according to claim 11, characterized in that the valve has a first position and a second position, wherein in the first position, the first oil passage (10) closed, and opened in the second position of the first oil passage (10) is.
[13]
13. connecting rod (1) according to claim 11 or 12, characterized in that the valve as a ball valve (60) with a valve ball (61) and in a receiving bore (62) axially displaceable cylinder pin (63) is formed, which together with valve ball ( 61) by a return spring (64) in a first position and by oil pressure against the force of the return spring (64) is displaceable in a second position.
[14]
14. connecting rod (1) according to claim 11 or 12, characterized in that the valve with a in a receiving bore (7) axially displaceable actuating piston (6a) is formed, which by a return spring (9) in a first position and by oil pressure opposite the force of the return spring (9) is displaceable in a second position.
[15]
15. connecting rod (1) according to one of claims 11 to 14, characterized in that the first oil passage (10) is designed as inflow and outflow channel.
[16]
16. connecting rod (1) according to one of claims 11 to 15, characterized in that in the high-pressure chamber (4b) designed as a feed channel second oil passage (15) opens, in which in the direction of the high-pressure chamber (4b) opening check valve (16) is arranged.
[17]
17. connecting rod (1) according to one of claims 11 to 16, characterized in that in the receiving bore (7, 62) preferably with the connecting rod bearing (30) flow-connected oil supply channel (17) opens, wherein particularly preferably in the oil supply channel (17) Throttling point (28) is arranged.
[18]
18 connecting rod (1) according to claim 16 or 17, characterized in that the second Ölzuführkanal (15) from the receiving bore (7) of the control valve (6) or from the oil supply channel (17) starts.

16 sil
[19]
19. connecting rod (1) according to one of claims 12 to 18, characterized in that the receiving bore (7, 62) through a bore transverse to the longitudinal axis (la) of the connecting rod (1) is formed.
[20]
20. connecting rod (1) according to one of claims 11 to 19, characterized in that the control valve (6) in the region of a ball bearing (30) of the connecting rod (1) is arranged.
[21]
21, connecting rod (1) according to one of claims 13 to 20, characterized in that at least one filling bore (43) by the actuating piston (6a) of the control valve (6) is controllable, wherein the filling bore (43) in the second position of the actuating piston (6a) and closed in the first position of the actuating piston (6a) is closed.
[22]
22 connecting rod (1) according to one of claims 13 to 21, characterized in that at least one drain hole (44) by the actuating piston (6a) of the control valve (6) is controllable, wherein the drain hole (44) in the first position of the actuating piston (6a) and closed in the second position of the actuating piston (6) is closed.
[23]
23 connecting rod (1) according to one of claims 12 to 22, characterized in that in the first position of the cylinder pin (63) or the adjusting piston (6a), the oil pressure level lower than in the second position of the cylinder pin (63) or actuating piston ( 6a). 2013 04 02 Fu

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AT521675B1|2020-04-15|Hydraulic control valve for a length-adjustable connecting rod with two control pistons on the front

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AT519293B1|2019-02-15|Length adjustable connecting rod with a cylinder-piston unit with oil guide rod

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AT519307B1|2019-01-15|Length adjustable connecting rod with a cylinder-piston unit with conical gap seal

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AT521268B1|2019-12-15|Length-adjustable connecting rod with hydraulic control device

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AT519304B1|2019-04-15|Length adjustable connecting rod with a cylinder-piston unit with oil scraper

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AT519306B1|2019-01-15|Length adjustable connecting rod with a cylinder-piston unit with gap seal, oil reservoir, oil filter and oil scraper

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AT519300B1|2019-04-15|Length adjustable connecting rod with cylinder-piston unit with gap seal and elastic piston collar

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AT522793B1|2021-02-15|Compact hydraulic valve mechanism for a length-adjustable connecting rod

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AT521146B1|2019-11-15|Hydraulic control valve for a length-adjustable connecting rod with a hollow slide

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AT519799B1|2019-08-15|Length-adjustable connecting rod with a cylinder-piston unit with anti-rotation

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AT522570A4|2020-12-15|Hydraulic valve mechanism with throttle bore

同族专利:

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公开号 | 公开日

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KR20150024936A|2015-03-09|

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CN104620002B|2017-10-13|

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WO2014005984A1|2014-01-09|

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JP2015527518A|2015-09-17|

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WO2014005984A9|2014-03-13|

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US20150122077A1|2015-05-07|

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EP2870370B1|2017-02-08|

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KR102081212B1|2020-05-28|

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AT513054B1|2014-09-15|

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JP6204464B2|2017-09-27|

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CN104620002A|2015-05-13|

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EP2870370A1|2015-05-13|

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US9670952B2|2017-06-06|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

DE2753563A1|1977-12-01|1979-06-07|Daimler Benz Ag|Variable stroke reciprocating piston IC engine - has resilient connecting rod formed by spring=loaded hydraulic arm|

---

JPS61122417U|1985-01-17|1986-08-01|

---

EP0297903A2|1987-07-03|1989-01-04|Honda Giken Kogyo Kabushiki Kaisha|Compression ratio-changing device for internal combustion engines|

---

DE4226361A1|1992-08-10|1994-04-07|Alex Zimmer|Fuel-air mixt. compressing IC engine - has remaining space during compression varied w.r.t. mixt. feed quality in direction of best compression ratio|DE102015001066B3|2015-01-29|2015-10-22|Armin Brunner|Hydraulically adjustable connecting rod|

---

DE102016220149A1|2016-10-14|2018-04-19|Mahle International Gmbh|Connecting rod for a reciprocating engine with a length adjustment and reciprocating engine with variable compression|US1610137A|1926-01-28|1926-12-07|Charles E Kratsch|Connecting rod|

---

US2134995A|1935-11-13|1938-11-01|George A Anderson|Adjustable stroke and shock absorbing connecting rod|

---

US2252153A|1940-06-17|1941-08-12|Mary Adeline Reynolds|Internal combustion engine|

---

US4124002A|1976-07-23|1978-11-07|Crise George W|Pressure-responsive variable length connecting rod|

---

US4140091A|1977-03-09|1979-02-20|Showers Jr Lewis M|Uniform compression piston engine|

---

US4195601A|1978-10-30|1980-04-01|Crise George W|Controlled compression internal combustion engine having fluid pressure extensible connecting rod|

---

US4370901A|1981-01-05|1983-02-01|John Sawyer|Connecting rod with variable length|

---

US4809650A|1986-10-09|1989-03-07|Nissan Motor Co., Ltd.|Variable compression control arrangement for internal combustion engine|

---

DE19530191A1|1995-08-17|1997-02-20|Daimler Benz Ag|connecting rod|

---

DE19835146A1|1998-08-04|1999-06-10|Daimler Chrysler Ag|Automotive engine connecting rod|

---

AU7714601A|2000-08-02|2002-02-13|Jerry I Yadegar|Hydraulically adjustable connecting rod for internal combustion engine efficiency|

---

US6568357B1|2000-10-18|2003-05-27|Ford Global Technologies, Inc.|Variable compression ratio pistons and connecting rods|

---

DE10151516A1|2000-10-18|2002-05-29|Ford Global Tech Dearborn|Engine with variable compression ratio for motor vehicles comprises a connecting rod consisting of a first part and a second part positioned relative to each other to adjust|

---

US6386153B1|2000-10-18|2002-05-14|Ford Global Technologies, Inc.|Variable compression ratio connecting rod locking mechanism II|

---

EP1243773B1|2001-03-19|2004-10-20|Ford Global Technologies, Inc., A subsidiary of Ford Motor Company|Connecting rod with adjustable length|

---

FR2857408B1|2003-07-09|2007-09-28|Inst Francais Du Petrole|INTERNAL COMBUSTION ENGINE WITH SCAN OF THE RESIDUAL BURN GAS PRESENT IN A COMBUSTION CHAMBER AND METHOD FOR SUCH SCAN|

---

CN101109321A|2007-08-08|2008-01-23|陈晨|Self-adaption compression ratio variable engine|

---

CN102319785B|2011-08-02|2013-06-05|济南铸造锻压机械研究所有限公司|Single-action type variable length connecting rod and crank-connecting rod transmission mechanism|

---

CN110110932A|2019-05-09|2019-08-09|上汽安吉物流股份有限公司|Order forecast method and device, logistics system and computer-readable medium|AT514071B1|2013-10-18|2014-10-15|Avl List Gmbh|Length adjustable connecting rod|

---

KR101518945B1|2013-12-11|2015-05-12|현대자동차 주식회사|Varialble compression ratio engine that varies compression ratio|

---

JP6070683B2|2014-12-22|2017-02-01|トヨタ自動車株式会社|Variable length connecting rod and variable compression ratio internal combustion engine|

---

JP6277997B2|2015-05-15|2018-02-14|トヨタ自動車株式会社|Internal combustion engine|

---

WO2016203047A1|2015-06-18|2016-12-22|Avl List Gmbh|Longitudinally adjustable connecting rod|

---

AT15426U1|2015-08-10|2017-08-15|Avl List Gmbh|Reciprocating engine, in particular internal combustion engine|

---

EP3390794B1|2015-12-14|2019-06-26|AVL List GmbH|Length-adjustable connecting rod with electromagnetically-actuatable switching valve|

---

AT517619B1|2015-11-05|2017-03-15|Avl List Gmbh|LENGTH-ADJUSTABLE CONNECTING ROD|

---

JP6319279B2|2015-12-08|2018-05-09|トヨタ自動車株式会社|Variable length connecting rod and variable compression ratio internal combustion engine|

---

JP6299741B2|2015-12-28|2018-03-28|トヨタ自動車株式会社|Variable length connecting rod and variable compression ratio internal combustion engine|

---

DE102016117874A1|2016-03-14|2017-09-14|Hilite Germany Gmbh|Changeover valve for controlling a hydraulic fluid flow and connecting rod with a changeover valve|

---

JP6376170B2|2016-05-02|2018-08-22|トヨタ自動車株式会社|Variable compression ratio internal combustion engine|

---

JP6424863B2|2016-05-12|2018-11-21|トヨタ自動車株式会社|Variable compression ratio internal combustion engine|

---

AT519011B1|2016-05-31|2018-03-15|Avl List Gmbh|reciprocating engine|

---

CN106089977B|2016-06-08|2018-11-20|北汽福田汽车股份有限公司|Engine link mechanism, variable compression ratio of engines system, engine and vehicle|

---

DE102016008306A1|2016-07-06|2018-01-11|Avl List Gmbh|Connecting rod with adjustable connecting rod length|

---

CN106089978B|2016-07-27|2018-11-16|奇瑞汽车股份有限公司|A kind of length two-stage adjustable connecting-rod|

---

US20170009647A1|2016-09-22|2017-01-12|Caterpillar Inc.|Connecting rod|

---

US20200217246A1|2016-09-30|2020-07-09|Avl List Gmbh|Length-adjustable connecting rod having stop surfaces|

---

JP6424882B2|2016-11-29|2018-11-21|トヨタ自動車株式会社|Variable compression ratio internal combustion engine|

---

AT519360B1|2017-02-24|2018-06-15|Avl List Gmbh|Method for operating a reciprocating piston engine with at least one hydraulically length-adjustable connecting rod|

---

JP6597699B2|2017-04-11|2019-10-30|トヨタ自動車株式会社|Internal combustion engine|

---

JP2018178919A|2017-04-18|2018-11-15|トヨタ自動車株式会社|Vehicle controller|

---

DE102017110446A1|2017-05-15|2018-11-15|ECO Holding 1 GmbH|Connecting rod for a variable compression internal combustion engine|

---

EP3674529A4|2017-08-25|2021-07-21|IHI Corporation|Variable compression device, engine system, and piston-rod position adjustment method|

---

CN108533606B|2018-06-21|2019-12-20|浙江吉利控股集团有限公司|Engine connecting rod with variable length|

---

KR20200000906A|2018-06-26|2020-01-06|현대자동차주식회사|Variable compression ratio engine|

---

RU2754573C1|2020-12-29|2021-09-03|федеральное государственное бюджетное образовательное учреждение высшего образования "Московский государственный технический университет имени Н.Э. Баумана " |Connecting rod-piston group of internal combustion engine|

法律状态:

优先权:

---

申请号 | 申请日 | 专利标题

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ATA50262/2012A|AT512334A1|2011-12-23|2012-07-03|Length adjustable connecting rod|

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ATA50220/2013A|AT513054B1|2012-07-03|2013-04-02|Length adjustable connecting rod|ATA50220/2013A| AT513054B1|2012-07-03|2013-04-02|Length adjustable connecting rod|

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PCT/EP2013/063812| WO2014005984A1|2012-07-03|2013-07-01|Length-adjustable con rod|

---

US14/412,310| US9670952B2|2012-07-03|2013-07-01|Length-adjustable con rod|

---

JP2015519170A| JP6204464B2|2012-07-03|2013-07-01|Adjustable length connecting rod|

---

KR1020157002486A| KR102081212B1|2012-07-03|2013-07-01|Length-adjustable con rod|

---

CN201380035799.1A| CN104620002B|2012-07-03|2013-07-01|The connecting rod of adjustable in length|

---

EP13733290.4A| EP2870370B1|2012-07-03|2013-07-01|Connecting rod with adjustable length|