• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a length-adjustable connecting rod (1) for a reciprocating engine, in particular for an internal combustion engine, with at least a first rod part (6) with a small connecting rod eye (2) and a second rod part (9) with a large connecting rod eye (4), both Rod parts (6, 9) telescopically zoom in and / or into each other, wherein the second rod part (9) a guide cylinder (8) and the first rod part (6) in the guide cylinder (8) longitudinally displaceable piston element (7) form, wherein on the large connecting rod eye (4) facing side of the piston element (7) between the second rod part (9) and the piston member (7) a first high-pressure chamber (10) is clamped, in which at least one first oil passage (20) opens, in which in particular a first check valve (21) opening in the direction of the first high-pressure chamber (10) is arranged, wherein at least one first return passage (22) protrudes from the first high-pressure chamber (10) ht, the outflow cross section by a control valve (13) in a first position closed and releasable in a second position, the control valve (13) preferably in a receiving bore (14) of the second rod portion (9) of the connecting rod (1) axially displaceable Control piston (15), which in particular by a return spring (16) in the first position and by an actuating force against the force of the return spring (16) is displaceable in the second position. In order to be able to change the compression ratio as simply as possible, it is provided that the piston element (7) is designed as a double-acting piston.
    公开号:AT514071A4
    申请号:T50674/2013
    申请日:2013-10-18
    公开日:2014-10-15
    发明作者:Helmut Dipl Ing Melde-Tuczai;Stefan Lichtenegger;Bernhard Dipl Ing Hödl
    申请人:Avl List Gmbh;
    IPC主号:
    专利说明:

    1 56688
    The invention relates to a length-adjustable connecting rod for a reciprocating engine, in particular for an internal combustion engine, with at least a first rod part with a small connecting rod and a second rod part with a large connecting rod, which two rod parts telescopically zoom in and / or into each other, wherein the second rod part a guide cylinder and the first rod part form a longitudinally displaceable in the guide cylinder piston member, wherein on the large connecting rod eye facing side of the piston member between the second rod member and the piston member, a first high-pressure chamber is clamped, opens into the at least one first oil passage, in which in particular one in the direction the first high-pressure chamber opening first check valve is arranged, wherein from the first high-pressure chamber at least a first return passage emanates, the outflow cross section by a control valve in a first position closed and in a second position is releasable, wherein preferably the control valve has a in a receiving bore of the second rod portion of the connecting rod axially displaceable actuating piston which is displaceable in particular by a return spring in the first position and by an actuating force against the force of the return spring in the second position ,
    By changing the compression of an internal combustion engine can be driven full load with a lower compression ratio, and part load and starting 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.
    The publication US 2,217,721 A discloses an internal combustion engine with a length-adjustable connecting rod with a first and a second rod part, which rod parts are telescopically zu - and slidable. Between the two rod parts a high-pressure chamber is spanned, into which an oil channel opens. For refilling and emptying the high-pressure chamber with oil and thus for length adjustment of the connecting rod, a control valve is provided with an axially displaceable closure member, which is displaceable by a return spring in a first closed position and by oil pressure against the force of the return spring in a second open position.
    Other connecting rods, each with a hydraulic telescopic mechanism for adjusting the connecting rod length are from the documents FR 2 857 408 Al, WO 02/10568 Al, DE 198 35 146 Al, US 4,195,601 A, US 4,124,002 A and US 2,134,995 A known.
    WO 2013/092 364 A1 describes a length-adjustable connecting rod for an internal combustion engine with a first and a second rod part. The two rod parts are telescopically zoomed in and / or into each other, wherein the second rod part forms a guide cylinder and the first rod part forms a longitudinally displaceable in the guide cylinder piston member. Between the first and second rod part, a first high-pressure chamber is spanned, into which at least one first oil channel opens. The flow to the oil passage can be controlled in a control piston which can be displaced axially in a receiving bore. The actuating piston is moved by a return spring in a first position and by oil pressure against the force of the return spring in a second position.
    The AT 512 334 Al discloses a similar length-adjustable connecting rod with telescopically displaceable rod parts, wherein the rod parts are mechanically lockable in at least one shift position by a locking device. The locking device in this case has a slider which is displaceable in a receiving bore of a rod member transversely to the longitudinal axis of the connecting rod between a locking position and a release position. The slider in this case has a wedge-shaped region which cooperates with a corresponding wedge-shaped region of the other rod part. The displacement of the slide takes place hydraulically by pressurizing an end face of the slide against the force of a return spring.
    The disadvantage is that the locking device requires a relatively large amount of space.
    Furthermore, it is disadvantageous that relatively many complex components to be machined 3/25 3 are used. The determination of the optimum wedge angle for the respective application requires additional development work.
    All the known proposals thus require a high level of design and / or control engineering effort.
    The object of the invention is to avoid these disadvantages and to provide a simple solution for the change of the compression ratio.
    According to the invention this is achieved in that the piston element is designed as a double-acting piston, preferably as a stepped piston.
    A double-acting piston in the present use is a piston which can be acted upon or hydraulically actuated on opposite sides and thus can exert force in two directions.
    A stepped piston is a piston with different sized effective surfaces, wherein, for example, one of the active surfaces is designed as an annular surface and the other effective surface is formed as a circular surface.
    Both in one of the first position of the control valve associated extended, as well as in a second position of the control valve associated with the inserted position of the first rod member can be hydraulically locked relative to the second rod part.
    It is preferably provided that a second high-pressure chamber is opened on the side of the piston element facing the small rod end between a holding part fixedly connected to the second rod part and into which at least one second oil passage opens, in which preferably a opening in the direction of the first high-pressure chamber second check valve is arranged. In order to allow a pressure relief, at least a second return passage can start from the second high-pressure chamber, the outlet cross-section of which can be closed by the control valve in the second position and can be released in the first position. The first and second high-pressure chambers hold the piston in the direction of the large or in the direction of the small connecting rod. 4/25 4
    It is particularly advantageous if a return flow throttle opening in the direction of the control valve is arranged in a feed line preferably leading from the large connecting rod eye to the control valve.
    The Rückströmdrossel may consist of a valve opening in the direction of the control valve and a throttle bore arranged parallel thereto, wherein the Rückströmdrossel may have, for example, provided with a throttle bore spring-loaded valve plate, which is pressed counter to the opening direction by a valve spring on a valve seat. A Rückströmdrossel this type is disclosed for example in DE 196 12 721 Al.
    By the Rückströmdrossel can be done on the one hand, a rapid filling of the high-pressure chambers on the one hand, opening check valve Rückströmdrossel. On the other hand, resulting from the adjustment of the connecting rod returning pressure waves are damped and kept the backflow in the direction of the large connecting rod small.
    The pressure oil supply of the high-pressure chambers via the supply line from the large connecting rod or the large connecting rod bearing of the connecting rod.
    The axis of the receiving bore of the control piston of the control valve is preferably arranged normal to Pleuellängsachse in the longitudinal center plane of the connecting rod. In order to enable a simple production of the second oil passage and the second return passage, it is advantageous if the second oil passage and / or the second return passage outside a longitudinal axis of the connecting rod Pleuellängsachse enclosing - and thus laterally adjacent to the receiving bore - are arranged. The connection between the lateral second oil and return channels and the receiving bore via short cross-holes. The first oil passage and the first return passage may be arranged in the longitudinal center plane.
    The second oil and return channels can be drilled from the large connecting rod eye of the connecting rod. The preparation of the first oil and return channels can be made from the side of the guide cylinder.
    A reliable and simple solution for the change in the compression ratio can be realized when the feed cross-section to 5/25 5 first oil passage closed by the control valve in the second position and releasable in the first position, preferably wherein the feed cross-section to the second oil passage through the control valve lockable in the first position and releasable in the second position.
    In a particularly simple and extremely compact design variant of the invention, it is provided that only the first and second return passages can be controlled by the control valve. As a result, the adjusting piston can be kept very short.
    The actuation of the control piston is preferably carried out hydraulically by oil pressure against the force of a return spring.
    Alternatively or additionally, it may be provided that the actuation of the control piston takes place electromagnetically, wherein preferably the control piston consists of ferromagnetic material or has a permanent magnet element which cooperates with an induction coil arranged in the crankcase. The control piston can be locked in at least one position by at least one preferably formed by a spring-loaded pressure member locking element, wherein preferably the locking element has a spring-loaded pressure body, which acts transversely to the direction of movement of the control piston on this.
    The invention will be explained in more detail below with reference to FIG.
    Show it
    1 shows a connecting rod according to the invention in a section along the line I - I in Figure 2 in a first embodiment in a first switching position of the switching valve.
    2 this connecting rod in a side view,
    3 shows the connecting rod in a section analogous to FIG. 1 in a second switching position of the switching valve, FIG.
    Fig. 4, the connecting rod in a section along the line IV - IV in Fig. 1, 6/25 6th
    5 shows the connecting rod in a section along the line V - V in Fig. 1,
    6 shows a circuit arrangement for the first switching position of the control valve shown in FIG. 1 in a schematic representation, FIG.
    7 shows a switching arrangement for the second switching position of the control valve shown in FIG. 3 in a schematic representation,
    8 shows the detail VIII of FIG. 1,
    9 shows the detail IX of FIG. 3,
    10 is a connecting rod according to the invention in a section analogous to Figure 1 in a second embodiment in a first switching position of the switching valve with rotated in the cutting plane second oil and return channels.
    11, this connecting rod in a second switching position of the switching valve,
    12 shows a circuit arrangement for the first switching position of the control valve shown in FIG. 10 in a schematic representation, FIG.
    Fig. 13 shows a circuit arrangement for the second switching position of the control valve shown in Fig. 11 in a schematic representation and
    14 shows a connecting rod according to the invention in a third embodiment variant.
    Functionally identical parts are provided in the embodiment variants with the same reference numerals.
    In the figures, in each case a two-part connecting rod 1, with a small connecting rod 2 for an apparent in Fig. 8 piston pin bearing 3 and a large connecting rod 4 for a crank pin bearing 5 (see Fig. 10 and Fig. 11) of an internal combustion engine. The rotational symmetry axes of the small or large connecting rod 2, 4 are denoted by 2a and 4a respectively. The longitudinal axis of the connecting rod 1 is denoted by la, a longitudinal center plane of the connecting rod 1 normal to the rotational axes of symmetry 2a and 4a of the small and large connecting rods 2, 4 and including the longitudinal axis la of the connecting rod 1 (FIG. 2). 7/25 7
    The connecting rod 1 has an upper first rod part 6 with the small connecting rod eye 2 and a lower second rod part 9 with the large connecting rod eye 4. The first rod part 6 is opposite to the second rod part 9 between an extended position A (FIGS. 1, 6, 8, 10 and 12) and an inserted position B (FIGS. 11 and 13) can be adjusted in the direction of the longitudinal axis la of the connecting rod 1 by an adjustment range AL shown in FIGS. 1, 8 and 10. In the upper first rod part 6, a substantially cylindrical piston element 7 is fastened with a fastening screw 17 formed in the exemplary embodiments by a hexagon socket screw. In the first embodiment variant shown in FIGS. 1 and 3, the screw head of the fastening screw 17 protrudes from the piston part 7; in the second variant embodiment shown in FIGS. 10 and 11, the screw head is sunk into the piston part 7.
    The piston element 7 is axially displaceably guided in a guide cylinder 8 of the lower second rod part 9 of the connecting rod 1, wherein between a large connecting rod 4 facing first end face 7a of the piston member 7 and the second rod member 9 in at least one position of the two rod parts 6, 9 a first high pressure chamber 10 is clamped. As can be seen from FIGS. 1 and 3, in the first exemplary embodiment the screw head of the fastening screw 17 protrudes from the first end face 7a of the piston element 7 into the first high-pressure space 10, but this has no influence on the function since only the projection the effective area in the axial direction is relevant. The oriented against the first high-pressure chamber 10 effective surface of the piston member 7 is partially formed by the first end face 7a and partially by the end face of the screw head of the fastening screw 17. The piston element 7 designed as a stepped piston has a second end face 7b facing the small connecting rod eye 2, which adjoins a second high-pressure space 11 whose cylindrical outer surface is formed by the guide cylinder 8 of the second rod part 9. Under a stepped piston is generally a piston - in the present case, a "double-acting piston". - understood with different sized effective surfaces, one of the active surfaces (here: the oriented against the second high-pressure chamber 11 effective area) is designed as an annular surface and the other effective surface area as a circular area. Due to the different effective surfaces, the pressure conditions described here can be realized. 8/25 8
    The annular first and second end faces 7a, 7b form pressure application surfaces for an actuating medium, for example engine oil, which is conducted into the high-pressure chambers 10, 11 and is under pressure.
    The first end face 7a of the piston element 7, which adjoins the first high-pressure chamber 10, is acted upon by the engine oil via the first oil passage 20, in which a first check valve 21 which opens in the direction of the first high-pressure chamber 10 is arranged. From the first high-pressure chamber 10, a first return channel 22 goes out, via which the first high-pressure chamber 10 is pressure-relieved.
    In the adjacent to the second end face 7b of the piston member 7 second high-pressure chamber 11 opens a second oil passage 30, in which a in the direction of the second high-pressure chamber 11 opening second check valve 31 is arranged. About this, the second high pressure chamber 11 can be acted upon by oil pressure. The pressure relief of the second high pressure chamber 11 via a second high-pressure chamber 11 outgoing second return channel 32nd
    The oil supply, lock and drain of the oil is from a control valve 13 which has a displaceable in a receiving bore 14 axially between a first position and a second position actuator piston 15, in a known manner via the oil pressure to the oil pump not shown by means of a likewise not shown actuator biasing a spring in the control valve of the oil pump more or less.
    By moving the adjusting piston 15, either the first or the second return channel 22, 32 can be opened or closed, wherein the respective other return channel 32, 22 is locked or opened.
    In the first embodiment variant shown in FIGS. 1 to 9, the actuating piston 15 controls only the first and second return passages 22 and 32 open or closed. The first and second oil passages 20, 30 are not controlled by the actuating piston 15.
    On the other hand, in the embodiment shown in FIGS. 10 to 12, the actuating piston 15 has a first piston part 15 a for actuating the first and second oil passages 20, 30 and a second piston part 15 b for actuating the first and second return passages 22. 32, wherein between the two piston parts 15a, 15b a preferably arranged in an annular groove 15c radial bore 15d is formed in the actuating piston 15, which opens into an axial bore 15e of the actuating piston 15. The axial bore 15e is designed to be open in the direction of the oil supply channel 28 emanating from the large connecting rod eye 4 or the crank pin bearing 5 and opening into the receiving bore 14.
    Fig. 1 shows a connecting rod 1 in a first embodiment in a high compression ratio associated withdrawn position A, which correlates with the first position of the control valve 13 shown schematically in Fig. 6 and Fig. 3 shows the connecting rod 1 in a low compression ratio associated inserted position B, which correlates with an apparent from Fig. 7 second position of the control valve 13.
    10 shows a high compression ratio connecting rod 1 in a second embodiment with rotated in the cutting plane second oil and return passages 30, 32, in a high compression ratio associated withdrawn position A, with the first position shown in Fig. 12 of the control valve 13 correlates. FIG. 11 also has second oil and return passages 30, 32 rotated in the cutting plane and shows the connecting rod of FIG. 10 in an inserted position B associated with a low compression ratio, which has a second position of the control valve 13 shown in FIG correlated.
    At low load, the oil pressure of the oil pump is controlled speed and load dependent on low pressure, for example, to 1.8 bar. The adjusting piston 15 is thereby-as in the FIGS. 1 and 6-shown pressed in its transverse to the longitudinal axis la of the connecting rod 1 receiving bore 14 by the force of the return spring 16 at low oil pressure level against a first stop 18 because the spring force of the return spring 16 is greater than the piston force of the actuating piston 15 caused by the oil pressure. In this position, there is a flow connection between the oil supply from the crank pin bearing 5 and the first check valve 21, which leads into the first high-pressure space 10 lying below the first end face 7a of the piston element 7. As long as the piston of the internal combustion engine by its inertial force pulls the two connecting rod parts 6, 9 10/25 10 flows through the first check valve 21 oil in the first high-pressure chamber 10 until it is filled. The volume of the high pressure chamber 10 is limited by a screwed into the shaft portion 9 a of the second rod member 9, formed by a stop sleeve holding part 33 which defines the maximum possible stroke of the piston element 7. Depending on the length of the stop sleeve, the adjustment range AL of the connecting rod length of the length-adjustable connecting rod 1 can be set as desired.
    The engine oil is sucked by the inertial force via the arranged in a first oil passage 20 first check valve 21 below the first end face 7a of the piston member 7. The actuator piston 15 locks with his cylinder jacket 19 from the first high-pressure chamber 10 outgoing first return channel 22. The sucked oil can not escape and is not compressible. As a result, the piston member 7 is raised together with the first rod member 6 and the connecting rod 1 thus longer. In this way, a higher compression ratio can be set at low oil pressure.
    The piston member 7 displaced when pulling the connecting rod 1, the oil from the annular second high-pressure chamber 11 via the second return passage 32, the actuating piston 15 of the control valve 13 releases in this first position. The oil flows toward the crankcase of the internal combustion engine according to the arrow R shown in FIGS. 1, 6, 10 and 12.
    Now, if the control pressure of the oil pump at high load - also load and speed-dependent - to a higher level, for example, to 3.5 bar, regulated, the control piston 15, as shown in Fig. 3, and 11, in his Receiving bore 14 pressed by the engine oil against the second stop 23, since the piston pressure caused by the oil pressure of the actuating piston 15 is stronger than the spring force of the return spring 16. The return spring 16 is compressed. The second stop 23 may be formed, for example, by a guide for the return spring 16 and / or a securing ring 24 inserted in a groove of the receiving bore 14.
    In this position, a flow connection between the first high pressure chamber 10 and the second check valve 31, which is arranged in the second high-pressure chamber 11 leading second oil passage 32 results. The gas force pushes the first rod part 6 together with the piston element 7 in FIGS. Down 11/25 11 in the direction of the large connecting rod 4, because the outflow from the first high pressure chamber 10 was opened by the first return passage 22 from the actuating piston 15. The resulting from the gas force in this first high-pressure chamber 10 pressure, which can reach about 20 times the amount of gas pressure in the combustion chamber, now helps to fill the annular second high-pressure chamber 11. The outflow through the second return channel 32 from this second high pressure chamber 11 is blocked by the actuating piston 15 in this second position. In this second position, the gas pressure from the not further apparent combustion chamber pushes the piston element 7 completely downwards, which sets a smaller compression ratio. By the resulting pressure of the first rod portion 6 of the connecting rod 1 is pressed in the Fig. Down in the direction of the large connecting rod 4 against the crank-side end face 12 of the guide cylinder 8, which forms a stop for the piston member 7 in the retracted position of the first rod part 6 ,
    The piston member 7 can not lift off, because 31 passes through the responsible for the filling of the second high-pressure chamber 11 open second check valve 31 oil in the second high-pressure chamber 11 and the piston member 7 thereby continues to be pressed against the bottom of the bag hole. Due to the rising in the first high-pressure chamber 10 pressure, the first check valve 21 is held in its closed position.
    In the second embodiment variant, the first oil passage 20 is additionally blocked by the left-hand piston part 15a in FIG.
    Since the volume of the second high-pressure chamber 11 is smaller than the volume of the first high-pressure chamber 10, the oil which no longer finds room in the second high-pressure chamber 11, via the supply line 25 having a Rückströmdrossel 29, which has an opening into the large connecting rod oil supply channel 28 , can flow into the direction of the crank pin bearing 5. This is achieved in that, in the second position of the actuating piston 15, the first return channel 22 for the engine oil is released by the actuating piston 15, as can be seen from FIGS. 7 and 13.
    It is particularly advantageous that even in a lower idling range of the internal combustion engine, when the engine oil pressure is less than the control pressure, a higher compression ratio can be set, which the consumption in 12/25
    Low load range improved and facilitates a cold start. In order to maintain the high compression ratio over a longer period, the leakage losses must be refilled by the play seat of the guide cylinder 8 from the first high-pressure chamber 10 under the first end face 7a of the piston member 7 in the same. This happens because the mass force of the piston (not shown) and of the first rod part 6 sucks the engine oil through the supply line 25 via the first check valve 21 (refill valve) into the first high-pressure chamber 10 under the first end face 7a. In the subsequent compression stroke, the high pressure builds up again and the small ball 21a in the first check valve 21 prevents the escape of the oil from the first high pressure chamber 10. This process is repeated at each cycle. If you want to lower the compression ratio again, the control pressure of the oil pump is increased and the actuator piston 15 is pressed by the oil pressure against the second stop 23 and the flow connection between the first return channel 22 via the supply line 25 and the oil supply channel 28 to the crank pin bearing 5 thus opened. The gas pressure pushes the piston member 7 down and the lower compression ratio is reset. The adjusting piston 15 is pushed back and forth in its receiving bore 14 only by the oil pressure and by the return spring 16 between the stops 18 at low oil pressure and 23 at high oil pressure.
    The piston element 7 has an anti-rotation lock 34, which in the first exemplary embodiment (see FIGS. 1 and 2) is formed by an axial groove 26 formed in its lateral surface, in which a cylindrical pin 27 engages. "Axial " means here substantially parallel to the longitudinal axis la of the connecting rod 1, whereas the cylindrical pin 27 radially, ie substantially normal to said longitudinal axis la, engages in the axial groove 26. In the second embodiment variant (see FIGS. 10 and 11), the anti-twist device 34 has an axial bore 26a in the first end face 7a of the piston element 7, into which a cylindrical pin 27 arranged correspondingly in the second rod part 9 engages, into the bore 26a engaging length is greater than the adjustment AL.
    The pin 27 prevents rotation of the piston member 7 and thus of the first rod member 6 relative to the second rod member 9. 13/25 13th
    The oil supply to the receiving bore 14 of the actuating piston 15 via the supply line 25 and the oil supply channel 28. This opens into the large connecting rod 4 and is thus fluidly connected to the crank pin bearing 5.
    The arranged in the oil supply channel 28 Rückströmdrossel 29 consists of a in the direction of the control valve 13 opening check valve 29a and a throttle bore arranged parallel thereto 29b, the Rückströmdrossel 29, for example - as known per se - may have a provided with a throttle bore spring-loaded valve disc, the opposite the opening direction is pressed by a valve spring on a valve seat (not shown). By the opening in the direction of the switching valve 13 check valve 29a of Rückströmdrossel rapid filling of the first high-pressure chamber 10 can be ensured. On the other hand, the pressure waves, which result from the adjustment of the two rod parts 6, 9 to each other, are damped relative to the area of the crank pin bearing 3, but the flow in the direction of the crank pin bearing 3 is kept small. The parallel-connected throttle bore 29b and the check valve 29a can be accommodated in a common cylindrical body, not shown.
    For assembly reasons, the first rod part 6 and piston element 7 are made of different parts and firmly connected to each other via the fastening screw 17.
    Conveniently, the thread for the fastening screw 17 is placed in a region of the first rod part 6, which has a sufficiently large cross-sectional area and thus lies outside the bending region of the rod part 6. The screw connection must be dimensioned sufficiently to be able to absorb the mass force.
    Alternatively to the operation by oil pressure against the restoring force of the return spring 16, the actuation of the actuating piston 15 can also be effected electromagnetically by an induction coil 41 arranged in the crankcase 40, as shown schematically in FIG. 14. In this case, the actuating piston 15 may consist of ferromagnetic material or have a permanent magnet element 42 and between two by means of locking elements 43, 44 lockable positions by electromagnetic forces back and forth to be moved. Alternatively, the magnetic actuating piston 15 - as in the first and second embodiments shown in FIGS. 1 to 13 - by a return spring 16 in a with the extended position A of the first rod member 6 corresponding first position and opposite the force of the return spring 16 - but now electromagnetically - are placed in a second position corresponding to the inserted position B of the first rod member 6 first position. The locking elements 43, 44 may be formed for example by spring-loaded pressure body, which act transversely to the direction of movement of the actuating piston 15 on this, wherein in the locked position, the pressure body in grooves or recesses of the actuating piston 15 engage. Reference numeral 45 in Fig. 14, the conrod of the connecting rod 1 is indicated. 15/25
    权利要求:
    Claims (14)
    [1]
    15 PATENT CLAIMS 1. Length adjustable connecting rod (1) for a reciprocating engine, in particular for an internal combustion engine, comprising at least a first rod part (6) with a small connecting rod eye (2) and a second rod part (9) with a large connecting rod eye (4), both Rod parts (6, 9) telescopically zoom in and / or into each other, wherein the second rod part (9) a guide cylinder (8) and the first rod part (6) in the guide cylinder (8) longitudinally displaceable piston element (7) form, wherein on the large connecting rod eye (4) facing side of the piston element (7) between the second rod part (9) and the piston member (7) a first high-pressure chamber (10) is clamped, in which at least one first oil passage (20) opens, in which in particular a first check valve (21) opening in the direction of the first high-pressure chamber (10) is arranged, wherein at least one first return passage (22) starts from the first high-pressure chamber (10), whose outflow cross-section can be closed by a control valve (13) in a first position and in a second position, wherein preferably the control valve (13) in a receiving bore (14) of the second rod part (4) of the connecting rod (1) axially displaceable actuating piston ( 15), which in particular by a return spring (16) in the first position and by an actuating force against the force of the return spring (16) is displaceable in the second position, characterized in that the piston element (7) acting as a double-sided piston, preferably as a stepped piston is formed.
    [2]
    Second connecting rod (1) according to claim 1, characterized in that the first position of the control valve (13) of an extended position (A) of the first rod part (6) and the second position of the control valve (13) of an inserted position (B) of the associated with the first rod part (6).
    [3]
    3. connecting rod (1) according to claim 2, characterized in that both in the extended position (A), as well as in the inserted position (B) of the first rod member (6) relative to the second rod member (9) is hydraulically locked. 16/25 16
    [4]
    4. connecting rod (1) according to one of claims 1 to 3, characterized in that on the said small connecting rod eye (2) facing side of the piston element (7) between a with the second rod part (9) fixedly connected holding part (33) and the Piston member (7) a second high-pressure chamber (11) is clamped, in which at least one second oil passage (30) opens, in which preferably in the direction of the first high-pressure chamber (10) opening second check valve (31) is arranged.
    [5]
    5. connecting rod (1) according to one of claims 1 to 4, characterized in that from the second high-pressure chamber (11) at least a second return channel (32) goes out, the outflow cross-section through the control valve (13) in the second position closed and in the first Position is releasable.
    [6]
    6. connecting rod (1) according to one of the preceding claims, characterized in that by the control valve (13) only the first and second return passages (22, 32) are controllable.
    [7]
    7. connecting rod (1) according to one of claims 1 to 6, characterized in that in a supply line (25) to the control valve (13) at least one Rückströmdrossel (29) is arranged.
    [8]
    8. connecting rod (1) according to one of claims 4 to 7, characterized in that the second oil passage (30) and / or the second return channel (32) outside of the longitudinal axis (la) of the connecting rod (1) enclosing longitudinal center plane (ε) the connecting rod (1) is arranged.
    [9]
    9. Connecting rod (1) according to any one of claims 1 to 8, characterized in that the holding part (33) is formed by an in the guide cylinder (8) projecting replaceable stop sleeve, wherein preferably the stop sleeve with the second rod part (9) is screwed ,
    [10]
    10. connecting rod (1) according to one of claims 1 to 9, characterized in that the feed cross-section to the first oil passage (20) by the control valve (13) in the second position is closed and releasable in the first position. 17/25 17
    [11]
    11. connecting rod (1) according to one of claims 4 to 10, characterized in that the feed cross-section to the second oil passage (30) by the control valve (13) in the first position is closed and releasable in the second position.
    [12]
    12. connecting rod (1) according to one of claims 1 to 11, characterized in that the actuation of the actuating piston (15) hydraulically by oil pressure or electromagnetically - preferably against the force of a return spring (16) - takes place.
    [13]
    13. connecting rod (1) according to claim 12, characterized in that the adjusting piston (15) consists of ferromagnetic material or a permanent magnet element (42) which cooperates with a crankcase arranged in the induction coil (41).
    [14]
    14. connecting rod (1) according to claim 12 or 13, characterized in that the adjusting piston (15) by at least one preferably formed by a spring-loaded pressure member locking member (43, 44) is lockable in at least one position, wherein preferably the locking element (43, 44) has a spring-loaded pressure body, which acts transversely to the direction of movement of the actuating piston (15) on this. 2013 10 18 feet 18/25
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    EP3371470B1|2019-02-27|Length-adjustable connecting rod
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    AT518848B1|2018-10-15|Connecting rod with adjustable connecting rod length with mechanical actuation
    AT517511A1|2017-02-15|LIFTING MACHINE, IN PARTICULAR FUEL POWER MACHINE
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    AT519156B1|2018-11-15|Length adjustable connecting rod for a reciprocating engine, reciprocating engine and vehicle
    WO2018007534A1|2018-01-11|Connecting rod having an adjustable connecting rod length with a mechanical actuating means
    AT517109B1|2016-11-15|LENGTH-ADJUSTABLE CONNECTING ROD
    AT519298B1|2019-07-15|Connecting rod with adjusting mechanism between connecting rod and piston rod
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    AT518208B1|2018-03-15|SWITCHING VALVE FOR CONTROLLING A FLUID CURRENT
    DE102015121918A1|2017-06-22|Changeover valve, connecting rod and internal combustion engine
    DE102015111273A1|2016-09-29|Hydraulic valve and connecting rod with a hydraulic valve
    DE102016120948A1|2018-05-03|Connecting rod with adjustment mechanism between connecting rod and connecting rod
    DE102016123635A1|2017-06-22|Connecting rod for a variable compression internal combustion engine
    DE102015121917A1|2017-06-22|Changeover valve, connecting rod and internal combustion engine
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    DE102019133520A1|2020-09-10|Switching valve for controlling a hydraulic fluid flow and connecting rod for an internal combustion engine with variable compression with a switching valve
    DE102009037434B3|2011-06-16|Length adjustable connecting rod for motor, has eccentric shaft that detachably connects connecting rod arm with another connecting rod arm such that two different lengths are adjusted
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    同族专利:
    公开号 | 公开日
    EP3058239B1|2019-05-01|
    US10294859B2|2019-05-21|
    JP2016535838A|2016-11-17|
    EP3058239A2|2016-08-24|
    US20160237889A1|2016-08-18|
    AT514071B1|2014-10-15|
    CN105814327A|2016-07-27|
    CN105814327B|2019-08-13|
    WO2015055582A2|2015-04-23|
    KR102245904B1|2021-04-29|
    KR20160073979A|2016-06-27|
    JP6467412B2|2019-02-13|
    WO2015055582A3|2015-06-11|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50674/2013A|AT514071B1|2013-10-18|2013-10-18|Length adjustable connecting rod|ATA50674/2013A| AT514071B1|2013-10-18|2013-10-18|Length adjustable connecting rod|
    US15/028,638| US10294859B2|2013-10-18|2014-10-13|Length-adjustable connecting rod|
    CN201480068098.2A| CN105814327B|2013-10-18|2014-10-13|Length-adjustable link|
    EP14789207.9A| EP3058239B1|2013-10-18|2014-10-13|Length-adjustable connecting rod|
    JP2016524470A| JP6467412B2|2013-10-18|2014-10-13|Adjustable connecting rod|
    PCT/EP2014/071890| WO2015055582A2|2013-10-18|2014-10-13|Length-adjustable connecting rod|
    KR1020167012109A| KR102245904B1|2013-10-18|2014-10-13|Length-adjustable connecting rod|
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