WO2017102108A1 - Length-adjustable connecting rod with electromagnetically-actuatable switching valve - Google Patents

Abstract

The invention relates to a length-adjustable connecting rod for a reciprocating piston engine, particularly a reciprocating piston internal combustion engine, comprising a hydraulic arrangement with which a length of the connecting rod can be adjusted, and a switching valve for controlling the inflow and outflow of a hydraulic medium into or out of the hydraulic arrangement, wherein the switching valve can be actuated electromagnetically.

Description

 Length adjustable connecting rod with electromagnetic

 actuatable switching valve

Description

The invention relates to a length-adjustable connecting rod for a reciprocating engine, in particular for a reciprocating internal combustion engine, which has a hydraulic device with which a length of the connecting rod is adjustable, and a switching valve for controlling an inflow and outflow of the hydraulic device.

Furthermore, the invention relates to a reciprocating engine with a connecting rod according to the invention, in particular such, designed as a reciprocating internal combustion engine reciprocating engine, as well as a vehicle with such a reciprocating engine.

The connecting rod of a reciprocating engine generally connects the crankshaft to the piston, the connecting rod converting the linear motion of the power piston into the circular motion of the crankshaft (linearly oscillating axial motion), or conversely, a circular motion into a linear motion.

At the smaller connecting rod eye, the piston is preferably fastened with a piston pin, at the larger connecting rod eye a conrod bearing is generally provided, via which the connecting rod is fastened to the rotating crankshaft. Between the smaller connecting rod eye, which is located at the connecting rod end, and the larger connecting rod eye, which is located at the big end, the conrod shaft is generally arranged. Adjustable connecting rods are used in particular in reciprocating engines with variable compression ratio for adjusting the compression ratio. By adjusting the connecting rod length can

Be changed compression ratio, since the top dead center of the

Piston movement is shifted. Length adjustable connecting rods are from the

The prior art is basically known, for example from WO 2015/055582 A2, AT 512 334 A1 or DE 10 2012 020 999 A1.

In general, in the case of length-adjustable connecting rods, the problem arises as to how an actuation or control of the length adjustment of the connecting rod can be transmitted from an actuating system of the reciprocating engine to the connecting rod which moves in a linear oscillating manner.

In the prior art, the following approaches are found, for example, for a mechanical or hydromechanical transmission:

Document WO 2014/019684 A1 relates to a variable compression reciprocating internal combustion engine having an actuator unit for varying a variable compression of the reciprocating internal combustion engine, wherein the variable compression operating unit comprises a variable length variable end piston engine, a variable length piston Compression height and / or a crankshaft with a variable crankshaft radius of the reciprocating internal combustion engine actuated and the actuating unit in a lower region of

Hubkolbenverbrennungskraftmaschine is arranged.

The publication DE 10 2005 055 199 A1 relates to a reciprocating internal combustion engine with at least one adjustably variable compression ratio in a reciprocating piston by means of an adjusting mechanism, the at least one arranged in a connecting rod eye or a Hublagerauge a connecting rod eccentric to change a effective length of the connecting rod comprises an adjustment of the eccentric, along which the eccentric is moved by means of a caused by a movement of the connecting rod acting torque, and at least one variable resistor which acts on an adjustment movement of the eccentric and at least one damped adjustment movement ung causes the eccentric.

In Applicant's PCT / EP 2016/064193, the length adjustment of the connecting rod is controlled by the pressure of a hydraulic medium.

It is an object of the invention to provide an improved connecting rod or an improved connecting rod for a reciprocating piston engine whose effective or effective connecting rod length can be adjusted. In particular, it is an object of the invention to improve control of the adjustment, in particular to make it more reliable. Further more particularly, it is an object of the invention to improve the transmission of an actuating pulse for length adjustment of an actuating system to the connecting rod.

This object is achieved by a connecting rod according to claim 1. Advantageous embodiments of the invention are claimed in the dependent claims. The teaching of the claims is hereby made part of the description.

A first aspect of the invention relates to a length-adjustable connecting rod for a reciprocating engine, in particular a reciprocating internal combustion engine, comprising: a hydraulic device, with which a length of the connecting rod is adjustable, and

a switching valve for controlling inflow and outflow of a hydraulic medium into or out of the hydraulic device, wherein the switching valve is electromagnetically actuated.

A second aspect of the invention relates to a reciprocating engine, in particular a reciprocating internal combustion engine with such a length-adjustable connecting rod, and a third aspect of the invention relates to a vehicle with a reciprocating engine, in particular a reciprocating internal combustion engine having such a length-adjustable connecting rod.

A connecting rod in the context of the invention is a usually present in reciprocating engines, elongated and arranged between the piston and the crankshaft connecting element, via which the piston is mechanically connected to the crankshaft.

A reciprocating piston engine according to the invention is a machine with which a linear stroke of a piston can be converted to a rotational movement of a shaft or vice versa a rotational movement of a shaft to a linear lifting movement of a piston.

Drainage in the sense of the invention means that a hydraulic medium return, that is a reduction of the hydraulic medium in a working space, is made possible. In particular, drainage takes place by an outflow of hydraulic medium from the hydraulic device. In particular, the drainage can be effected by forces or pressures which act on the connecting rod from outside the connecting rod, for example by the ignition process in an internal combustion engine or by a movement of the piston due to the crankshaft movement, for example centrifugal forces at top dead center.

An anchor element according to the invention is the movable part of an electromagnetic actuator, in particular a valve, and preferably comprises ferromagnetic material or magnetizable material, in particular, the anchor element consists of this material. In particular, an anchor element can have one or more anchors.

The invention is particularly based on the recognition that an electromagnetic actuation of a switching valve for controlling the inflow of hydraulic medium into the hydraulic device or the outflow of hydraulic medium from the hydraulic device by an electromagnetic control pulse allows easy transmission of the control pulse to the connecting rod in motion. Preferably, the necessary for the actuation of the switching valve of such a switching valve electrical energy and the actuating pulse itself via magnetic induction, preferably via two coils, one disposed in the housing of the reciprocating engine and one on or in the connecting rod itself, be realized.

In contrast to a hydraulic transmission of an actuating pulse via the lines of a hydraulic medium or a mechanical transmission via mechanical adjusting elements, as known from the prior art, a transmission of an electromagnetic actuating pulse can be realized without a signal routing through a bearing, in particular the main bearing of the connecting rod to the crankshaft at the large connecting rod eye, to provide. In particular, no components must be provided in this case, which are arranged directly on such a bearing and therefore subject to the resulting by a rotational movement wear.

Furthermore, there are no frictional losses caused by additional components or by the actuating pulse itself.

Inasmuch as actuation energy is diverted from the movement of the connecting rod according to the invention by magnetic induction, this is not lost because with this, the switching valve is actuated. These Actuation energy is then saved on the other side of electrical energy to produce an induction field.

In an advantageous embodiment of the connecting rod according to the invention, this has a first connecting rod section and a second connecting rod section, wherein the connecting rod sections for adjusting a connecting rod length, in particular along a longitudinal axis of the connecting rod, are displaceable relative to each other. Preferably, the hydraulic device has a first hydraulic cylinder with a first pressure chamber and a second pressure chamber, which are separated by a piston, wherein one of the two connecting rod sections with the hydraulic cylinder and the other of the two connecting rod sections are connected to the piston. The connecting rod preferably has a hydraulic medium supply line and / or a drainage line, which can be connected in a fluid-communicating manner with the first pressure chamber and / or the second pressure chamber. In this advantageous embodiment, the length of the connecting rod is set directly via the position of a piston in a hydraulic cylinder. The hydraulic device controls directly the inflow and outflow of the hydraulic medium in the pressure chambers of this hydraulic cylinder. The forces acting on the movement of the connecting rod forces are absorbed by the hydraulic cylinder and passed on to the hydraulic medium. If the hydraulic medium supply line and, if appropriate, the drainage are closed, a change in the length of the connecting rod is prevented. If the hydraulic medium supply line or the drainage is opened, in particular by the corresponding switching position of the switching valve, a change in the length of the connecting rod can be effected, depending on the applied forces or pressures.

In a further advantageous embodiment, the length-adjustable connecting rod has a first connecting rod section with a nut section and a second connecting rod section with a spindle element section, wherein the nut section and the spindle element section meshing and rotatable relative to each other for adjusting a connecting rod length, in particular along a longitudinal axis of the connecting rod, and wherein the hydraulic device is adapted to control relative rotation of the nut portion and the spindle element portion, and wherein the connecting rod is a hydraulic medium supply line and / or a drainage has, which are fluidkommunizierend connected to the hydraulic device. Alternatively or in addition to a hydraulic cylinder with a piston, a screw drive can be provided for the actual adjustment of the length of the connecting rod. The thread gear formed by this thread gear can in this case be self-locking or not self-locking. If the thread is not self-locking, then a length adjustment of the connecting rod can be done via the forces acting on the connecting rod from the outside (passive). If the thread, however, self-locking, a length adjustment of the connecting rod can be done for example via a rotary valve, which is rotatably connected either with the mother section or the spindle element section (active). By providing the thread drive, the forces or pressures acting on an electromagnetically actuated switching valve can be substantially reduced or even avoided.

In a further advantageous embodiment of the connecting rod, the hydraulic device further comprises an actuating valve, in particular a slide valve, wherein the switching valve for hydraulic actuation of the actuating valve is formed and the actuating valve for opening or closing a fluidkommunizierenden connection between the hydraulic medium supply line and the drainage -Leitung is formed with the two pressure chambers or for generating a relative rotation between the nut portion and the spindle element. By providing an actuating valve, in addition to the switching valve, which is hydraulically actuated by the switching valve, forces or pressures, which act on the length-adjustable connecting rod, can be absorbed or reduced by the actuating valve. This makes it possible to Electromagnetically actuated switching valve, which depending on the design can hold only comparatively low applied forces or pressures, to use for controlling the hydraulic device.

In a further advantageous embodiment of the length-adjustable connecting rod lying in an axis of the actuating valve and an axis of the switching valve in a plane, in particular, the axes are aligned parallel to the axis. Preferably, the axes of the valves are each aligned so that the smallest possible external forces, such as centrifugal forces, act on the moving parts of the valves. In this embodiment, both valves are preferably aligned parallel.

In a further advantageous embodiment of the length-adjustable connecting rod, an axis of the closing valve and an axis of the switching valve are arranged axially parallel to the crankshaft. In this embodiment, forces that arise due to acceleration or deceleration of the movement of the connecting rod, exert no influence on the switching action of the valves.

In a further advantageous embodiment, the actuating valve has a second hydraulic cylinder with a first chamber and a second chamber, which are separated by an actuating piston, wherein the actuating piston is arranged to actuate at least one closing valve, in particular a ball valve, or with the mother section or Spindle element portion is rotatably connected. Preferably, the actuating valve can thereby remove the ball of the ball valve from a valve seat to allow drainage of a pressure chamber. Alternatively, the actuating valve can preferably inhibit (passively) a rotational movement of a thread drive by external forces or pressures on the connecting rod or effect a length adjustment (active) by applying a force to the thread gear. In a further advantageous embodiment of the length-adjustable connecting rod, the switching valve, in particular a 4/3-way valve, an inlet, a first outlet, a second outlet, a first switching connection, which in a first switching state of the switching valve with the inlet and in a the second switching state of the switching valve is fluidly communicating with the first outlet, and a second switching port, which is in a second switching state of the switching valve to the inlet or in a first switching state of the switching valve to the second outlet fluidly communicating, wherein the switching valve with the hydraulic device via the first switching port and the second switching port is connected fluid communicating. Preferably, the first outlet and the second outlet are connected to or form drainage at least one drain, and the inlet is connected to a hydraulic medium supply line. By providing two switching ports and two outlets, two pressure chambers or chambers can be filled or drained independently of one another with hydraulic medium by means of the switching valve.

In a further advantageous embodiment of the length-adjustable connecting rod, the switching valve has:

An inlet, a first outlet, and a first switching port, which in a first

Switching state of the switching valve is connected in fluid communication with the inlet or in a second switching state of the switching valve to the first outlet. Preferably, the outlet is connected to a drainage or forms the drainage. The inlet is preferably connected to a hydraulic medium supply line. By such a switching valve can be a filling or drainage a chamber of an actuating valve or a pressure chamber of a hydraulic cylinder are controlled. Depending on the amount of hydraulic medium, which is located in the chamber or the pressure chamber, in a system in which the connecting rod is adjusted by external forces, the length can be set exactly or fixed or fixed.

In a further advantageous embodiment of the length-adjustable connecting rod, the first pressure chamber or the first chamber with the first switching port and the second pressure chamber or the second chamber with the second switching port fluidkommunizierend connected.

In a further advantageous embodiment of the length-adjustable connecting rod, the switching valve has:

 a first coil; and

 an anchor element which has a ferromagnetic or magnetizable material and is displaceable between exactly two switching positions.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element and the first coil are mounted in a common receptacle, wherein the anchor element by a single first return device, in particular a spring element, which cooperates with the receptacle, in particular with cover elements of the receptacle, in a defined Position, preferably a first switching position is held.

A receptacle in the sense of the invention is an assembly in which the switching valve is received. A receptacle may in particular be a separate housing or a bore or a cavity, preferably in the connecting rod itself. In a further advantageous embodiment of the length-adjustable connecting rod, the switching valve has a neutral position in which the inflow and outflow into / from the hydraulic device is prevented and preferably no electromagnetic actuation of the switching valve takes place, in particular no electromagnetic induction. This is particularly advantageous because a set length of the connecting rod can be maintained without requiring actuation of the switching valve. In particular, this energy can be saved and in case of failure of the electromagnetic actuation, a reciprocating engine can continue to operate, the last set length of the connecting rod is maintained.

In the case of a neutral switching position according to the invention, the switching connection or the switching connections are connected neither to the inlet nor to the outlet. In particular, in particular the first switching connection and the second switching connection are connected in the neutral switching position neither with the inlet nor with one of the outlets and preferably closed.

In a further advantageous embodiment of the length-adjustable connecting rod, the switching valve has:

A first coil and a second coil, which are spaced apart from each other, and an anchor member which comprises a ferromagnetic or magnetizable material and between at least two, in particular three, switch positions is displaceable.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element and the coils are mounted in a common receptacle and the anchor element is replaced by two Restoring devices, in particular spring elements, which cooperate with the receptacle, in particular with cover elements of the receptacle, held in a defined position, preferably a neutral switching position.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element has at least one radial feed bore and at least one axial feed bore, which are connected in a fluid-communicating manner and adapted to fluidly communicate the inlet with the first switching port or with the second switching port, and / or wherein the anchor member has at least one radial drainage bore and at least one axial drainage bore fluidly communicating and configured to fluidly connect the first switchportion to the first outlet and the second switchportion to the second outlet. In this embodiment, pressures of the hydraulic medium in the first switching connection or in the second switching connection are exclusively perpendicular to the direction of movement of the anchor element. Therefore, by these pressures preferably no movement of the armature element can be generated without an electromagnetic actuation, which prevents unwanted switching between switching positions, or at least makes it difficult.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element has two axial drainage holes, and radial drainage holes are connected to either a first axial drainage bore or a second axial drainage bore, wherein the radial drainage holes, which are connected to the different axial drainage holes axially in Relative to the anchor element each lie in a different plane. In a further advantageous embodiment of the length-adjustable connecting rod are radial drainage holes, which are connected to the same axial drainage hole, in a plane.

In a further advantageous embodiment of the length-adjustable connecting rod connects at least one radial drainage hole, which is connected to the second axial drainage hole in the first switching state, the second switching port to the second outlet, and at least one radial drainage hole, which is connected to the first axial drainage hole , Connects in the second switching state, the first switching port to the first outlet.

In a further advantageous embodiment of the length-adjustable connecting rod, the at least one radial feed bore and the at least one radial drainage bore and / or the at least one axial feed bore and the at least one axial drainage bore are arranged in the anchor member in such a way that they have no connection, in particular the at least one radial lead bore and the at least one radial drainage bore are axially in relation to an axis of the anchor member in another plane, and wherein the at least one axial lead bore and the at least one axial drainage bore are radially displaced with respect to an axis of the anchor member.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element has a first circumferential groove, which connects the radial supply bores fluid-communicating with each other. Circulating grooves allow the openings of the individual elements of the connecting rod need not be aligned when a fluid connection is to be established between them.

In a further advantageous embodiment, a first gap between the anchor element and the housing is present in the first switching state by which is a fluid-communicating connection between the inlet and the first switching port is formed, and in the second switching state, a second gap between the anchor member and the housing is provided, through which a fluid-communicating connection between the inlet and the second switching port is formed.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element has a first circulation groove which is set up to connect the inlet in a first switching state to the first switching port and in a second switching state to communicate with the second switching port fluidkommunizierend.

In a further advantageous embodiment of the length-adjustable connecting rod, the cover elements or spring plate with retaining rings are attached to the receptacle.

In a further advantageous embodiment of the length-adjustable

Connecting rod has the receptacle:

 a first groove, which is designed in such a way, in the first switching state, to connect the at least one radial supply bore or a radial drainage bore to the first switching connection and / or to connect the first circulation groove of the anchor element to the first switching connection in the second switching state, and

a second groove, which is designed in such a way, in the first switching state, to connect the at least one radial supply bore or a radial drainage bore to the second switching connection and / or to connect the first circulation groove of the anchor element to the second switching connection in the second switching state. In a further advantageous embodiment of the length-adjustable connecting rod, the spring elements are arranged radially with respect to an axis of the anchor element inside or outside of the coils.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor element has a first armature and a second armature, which are each supported by a spring element at a central part of the receptacle. In this embodiment, both anchors may preferably be actuated independently of each other. In this way, for example, a function check of the switching valve can be made without a length adjustment of the connecting rod takes place.

In a further advantageous embodiment, the length-adjustable connecting rod has two closure elements, wherein a first closure element is arranged relative to the first anchor with respect to a central part of the receptacle and wherein a second closure element is arranged with respect to the second anchor with respect to the middle part.

In a further advantageous embodiment, the first closure element has radial and axial bores, which are connected to one another and connect the inlet and the first switching port in a fluid-communicating manner in the first switching state and connect the first outlet and the first switching port in a fluid-communicating manner in the second switching state wherein the second closure element has radial and axial bores, which connect the inlet and the second switching port in a fluid-communicating manner in the second switching state and in the first switching state connect the second outlet and the second switching port in a fluid-communicating manner.

In a further advantageous embodiment of the length-adjustable connecting rod between the anchors and the receptacle at least one cavity, in particular at least one axial groove formed, which is preferably formed with anchoring elements. In a further advantageous embodiment of the length-adjustable connecting rod, a first gap is formed in the first switching state between the first closure element and the first armature, which connects the inlet with the radial and axial bores of the first closure element, in particular via the cavity, fluidkommunizierend, and in the second switching state a second gap is formed between the second closure element and the second anchor, which connects the inlet fluid-communicating with the radial and axial bores of the second closure element, in particular via the cavity.

In a further advantageous embodiment of the length-adjustable connecting rod, the first closure element and the second closure element grooves, in particular recirculating grooves, which are preferably adapted to each connect a plurality of radial bores fluidkommunizierend each other.

In a further advantageous embodiment of the length-adjustable connecting rod, the anchor elements are guided by the closure elements and / or by the receptacle.

In a further advantageous embodiment, the length-adjustable connecting rod has a first cover element which closes the axial bores of the first closure element in the first switching state to the outside of the switching valve, and a second cover element, which the axial bores of the second closure element in the second switching state to the outside of the Closing the switching valve.

In a further advantageous embodiment of the length-adjustable connecting rod, the receptacle in the region in which the inlet is arranged, which is divided in particular into two inlet pipes, at least one circumferential groove which is adapted to the first gap between the first closing element and the first anchor element and / or the second gap between the second closure element and the second anchor element to communicate in fluid communication with the inlet.

In a further advantageous embodiment of the length-adjustable connecting rod, a first passage, in particular an opening, is arranged between the first armature and the first closure element, which connects a first gap to the first switching connection, and wherein between the second armature and the second closure element second passage, in particular an opening is arranged, which connects the second gap with the second switching port.

These and other features and advantages will be apparent from the claims and from the description of the drawings, wherein the individual features may be implemented alone or in combination in the form of sub-combinations in an embodiment of the invention and an advantageous and protectable Unless otherwise expressly excluded.

The foregoing features and advantages with respect to the first aspect of the invention apply equally to the second and third aspects of the invention.

The invention will be explained in more detail below with reference to non-limiting embodiments, which are shown at least partially in the figures. Further features and advantages will become apparent from these embodiments in conjunction with the corresponding figures. At least partially schematically show:

Figure 1 is a plan view of a first embodiment of a connecting rod 7 according to the invention; Figure 2 is a plan view of a second embodiment of a connecting rod 7 according to the invention;

 Figure 3 is an illustration of the terminals of a first type of switching valve according to the invention;

 Figure 4 is an illustration of the terminals of a second type of switching valve according to the invention;

 FIG. 5 shows a circuit symbol for a switching valve according to the invention of the type according to FIG. 3;

 Figure 6 is an illustration of a first embodiment of a switching valve according to the invention;

 Figure 7 is a cross-section along the plane C-C of Fig. 6;

 FIG. 8 shows a cross section along the plane D-D from FIG. 6;

 Figure 9 is a perspective top view of an armature of the first

 Embodiment of FIG. 6;

 FIG. 10 shows a further illustration of the first exemplary embodiment according to FIG

 Fig. 6;

 Figure 11 is an illustration of a second embodiment of the switching valve according to the invention;

 Figure 12 is a perspective top view of a sleeve of the second

Embodiment of FIG. 11; FIG. 13 shows a perspective top view of an anchor element of the second exemplary embodiment according to FIG. 11;

Figure 14 is a further illustration of the second embodiment according to

 Fig. 1 1;

Figure 15 shows an alternative embodiment of the second embodiment;

FIG. 16 shows a further alternative embodiment of the second

 Embodiment;

Figure 17 is an illustration of a third embodiment of the switching valve according to the invention;

FIG. 18 shows an alternative embodiment of the third exemplary embodiment according to FIG. 17;

Figure 19 is an illustration of a fourth embodiment of the switching valve according to the invention;

FIG. 20 shows a further illustration of the fourth exemplary embodiment according to FIG

 Fig. 19;

Figure 21 is an illustration of a fifth embodiment of a switching valve according to the invention;

Figure 22 is a side elevational view of the elements of the invention

 Switching valve of the fifth embodiment of FIG. 21 without a receptacle;

Figure 23 is a perspective top view of an anchor of the fifth

Embodiment of FIG. 21; FIG. 24 shows a cross section of the sectional plane DD of the fifth exemplary embodiment according to FIG. 21;

FIG. 25 shows a further illustration of the fifth exemplary embodiment according to FIG

 Fig. 21;

Figure 26 is an illustration of a sixth embodiment of the switching valve according to the invention; and

Figure 27 is a further illustration of the sixth embodiment according to

 Fig. 26.

FIGS. 1 and 2 show two exemplary embodiments of a length-adjustable connecting rod 7 according to the invention.

The connecting rod 7 has a first connecting rod portion 7a and a second connecting rod portion 7b. These are preferably telescopically slidable. In the illustrated case, the first connecting rod portion 7a, which is fixedly connected to the large connecting rod eye, the second connecting rod portion 7b, which is fixedly connected to the small connecting rod eye, on.

The length adjustment of the connecting rod 7 can in this case hydraulically, for example by means of a hydraulic cylinder having a piston, or mechanically, for example via a threaded gear, which has a nut portion and a spindle element section done.

A hydraulic system is described for example in the aforementioned WO 2015/055582 A2. This 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 eye and with a second rod part with a large connecting rod eye, which two rod parts are telescopically and / or slidable, the second rod part forming a guide cylinder and the first rod part a longitudinally displaceable in the guide cylinder piston member, wherein on the large connecting rod eye facing side of the piston element between the second rod part and the piston element, a first high-pressure chamber is opened, in which at least one first oil passage opens, in which in particular a first check valve opening in the direction of the first high-pressure chamber is arranged, wherein from the first high-pressure chamber at least a first return channel emanates, the outflow cross section through a Control valve in a first position closed and can be released in a second position, wherein preferably the control valve in a receiving bore of the second rod portion of the connecting rod axially displaceable actuating piston has, which 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 is displaceable, wherein the piston member is designed as a double-acting piston, preferably as a stepped piston.

A system in which a helical gear or a rotary spindle is used, for example, from the application A 50725/2015 known. There, a length-adjustable connecting rod for a reciprocating engine, in particular for an internal combustion engine, described, with at least a first rod member and a second rod member, which two rod parts relative to each other via a helical gear in the direction of the longitudinal axis of the connecting rod are displaceable, wherein the helical gear at least a first gear part and having a second gear part engaging with the first gear part, wherein the first gear part is formed as a spindle nut or threaded spindle and the second gear part as a threaded spindle or spindle nut, wherein the helical gear is not formed self-locking, wherein a - preferably in the first rod part rotatably mounted - first gear part with at least one by means of at least one Switching device switchable Drehsperreinrichtung is connected, which prevents in at least a first position, a rotation of the first gear part in at least one direction of rotation and allows in at least a second position.

The content of the application WO 2015/055582 A2 and the application A 50725/2015 is also made subject matter of this application by express reference. In particular, hydraulic or mechanical versions for adjusting the length of the connecting rod 7 may be formed as described in these two documents.

Regardless of whether the length adjustment is accomplished via a hydraulic piston or other means, the respective device according to the invention can be hydraulically controlled. The hydraulic device 8 shown in Figures 1 and 2 may comprise the means for length adjustment here, or these, as in the case of a hydraulic piston, form, or, as in the case of a screw thread, control or actuate the device for length adjustment.

Preferably, the hydraulic device 8, as shown in Fig. 2, further comprises an actuating valve 12. Such an actuating valve, which may be designed in particular as a slide valve or rotary valve, is described in particular in the applicant's PCT / EP2016 / 064194. This relates to a length-adjustable connecting rod or a length-adjustable connecting rod for a reciprocating engine with at least a first rod part and a second rod part, wherein the two rod parts by means of a length adjustment in the direction of a longitudinal axis of the connecting rod in particular telescopically zoom in and / or into each other, wherein the length adjustment via at least one hydraulic channel with a hydraulic medium can be fed and wherein the at least one hydraulic channel is flow-connected by a control device with at least one hydraulic medium supply channel, wherein the Control means comprises a first valve and a second valve, each having a valve body arranged in a valve body, the valve bodies are each pressed by a restoring force against a valve seat, wherein a first valve chamber of the first valve with a first hydraulic channel and a second valve chamber of the second valve a second hydraulic channel is fluidly connected, and the valve body are operatively connected to each other via a at least between a first position and a second position connecting means, wherein in the first position of the connecting means of the first valve body and in the second position of the connecting means of the second valve body by the connecting means respectively can be lifted against the restoring force of the associated first and second valve seat and the corresponding first and second valve chamber is fluidly connected to the hydraulic medium supply channel, and in each case in the other position of the connecting device, the first valve body rests on the first valve seat and the second valve body rests on the second valve seat and blocks the flow connection to the hydraulic medium supply channel.

The content of this application PCT / EP2016 / 064193 is also the subject of this application by express reference. In particular, the design of the length adjustment device and the control device, the hydraulic and / or mechanical connection of the control device and the length adjustment device and arrangement and orientation of the control device can be designed according to the invention as in said PCT / EP 2016/064193.

The two exemplary embodiments of FIGS. 1 and 2 have in common that they have a switching valve 9 for controlling the inflow and outflow of a hydraulic medium into or out of the hydraulic device 8.

The hydraulic medium supply line is, as shown in Figures 1 and 2, preferably with a pressurized hydraulic medium, in particular Oil or pressure oil supplied from the large connecting rod eye or the main bearing of the connecting rod 7. In particular, the hydraulic medium is lubricating oil, which is supplied to the main bearing.

Preferably, the switching valve 9, as shown in Fig. 3, five ports. An inlet for hydraulic medium, which is preferably connected to a hydraulic medium supply line 10, a first outlet 2, which is preferably connected to a drainage 1 1, a second outlet 3, which is preferably also connected to a drainage 11, and a first switching Port HD1 and a second switching port HD2, which are connected to the hydraulic device 8 and / or the closing valve 12.

Preferably, the switching ports HD1, HD2 are each connected to a pressure chamber of a hydraulic cylinder of the hydraulic device 8, when the device for length adjustment is designed hydraulically. In this case, these two pressure chambers each filled or drained by connecting with a hydraulic medium supply line 10 or with a drainage 1 1 with hydraulic medium, i. be emptied.

The second embodiment of FIG. 2 differs from the first embodiment of FIG. 1 in particular in that between the switching valve 9 and the hydraulic device 8 in addition an actuating valve, in particular a slide valve or rotary valve is connected. If such a further exists, it preferably has an actuating piston or valve body which divides a hydraulic cylinder into a first chamber and a second chamber. In this case, the switching ports HD1, HD2 are each connected to one of these chambers, so that a displacement of the actuating piston or valve body is effected by supplying hydraulic medium into one chamber and draining the other chamber in a switching state. The movement of the actuating piston or valve body of the actuating valve 12 causes switching Ports of the actuating valve 12 is opened or closed, with which, in the case of a hydraulic device for length adjustment of the piston rod 8, each one of the pressure chambers can be filled and / or drained.

The system shown in Figures 1 and 2 for the adjustment of the length of the connecting rod 7 is suitable both for systems in which the length adjustment is operated passively, that is, in which external forces acting on the connecting rod 7, used to effect the length adjustment be, as well as for systems in which the adjustment of the connecting rod length 7 is active, that is, in which by the hydraulic device 8 or the device for length adjustment, a force is generated to move the first connecting rod portion 7a and the second connecting rod portion 7b against each other.

A circuit diagram of a switching valve 9 of FIG. 3 is shown in FIG. The valve with the inlet 1 or the drainages 2, 3 and the switching terminals HD1, HD2 is held in a defined position by means of the rear-part device 21, 22 and via actuators, which of the first coil 13 and the anchor member 15 and the second coil 14 and the anchor member 15 are respectively formed actuated. Preferably, the switching valve 9 has two switching states and is therefore bistable. Alternatively, the switching valve 9 preferably has three switching states, wherein in this case preferably in a switching state, the switching ports HD1, HD2 are neither drained nor connected to the inflow 1 1 and thus forms a neutral switching position.

As indicated in Figures 1 and 2, the drainages 11 are led out of the connecting rod 7, so that the oil can escape into an oil sump of a reciprocating engine. Alternatively, it can also be provided that the oil can also escape from the pressure chambers of the hydraulic device 8 or the chambers of the actuating valve 12 via the hydraulic medium supply line 10. In particular, can also be provided be that the switching valve 9 has only a single outlet 2 and the switching ports HD1, HD2 are both drained via this outlet 2.

In an alternative embodiment, which is shown in FIG. 4, the switching valve 9 has only a single switching port HD1 and only a single outlet 2. This embodiment for an example of a switching valve is used in particular when the hydraulic device 8 or the actuating valve 12 have only one pressure chamber or a chamber and / or are actuated exclusively by means of a pressure chamber or a chamber.

Furthermore, it can be provided with respect to all embodiments of the switching valve 9 that, for example, the inlet 1 is divided into two ports. The same applies to the other connections, such as, for example, the switching connections HD1, HD2 and the outlets 2, 3.

FIG. 6 shows a first concrete exemplary embodiment of an electromagnetically actuated switching valve 9 with a total of five connections according to FIGS. 3 and 5.

An anchor 15, which preferably comprises or consists of magnetizable or ferromagnetic material, has substantially the cross section of a cross with a central portion, which has radial bores 16, 18 and axial bores 17, 19, and lesser, narrower portions extending to the left two electromagnetic coils 13, 14 are arranged in a receptacle 20. The information radially and axially relate in this context to a central axis of the switching element 12. The receptacle 20 preferably surrounds the arrangement of the elements of the switching valve 9 in the coil 13, 14. In particular, the receptacle 20 covers the switching valve 9 with the cover elements 23 after left and right to the connecting rod 7 or, depending on the arrangement of the switching valve 9, outside the connecting rod 7 to the interior of the reciprocating engine. At These cover elements 23 are each based on a first rear part, in this embodiment, a spring and a second rear part 22, in the present case also a spring, preferably from and hold in the axial direction of the coils 21, 22 displaceable armature 15 in a by the spring force and Compression of the springs 21, 22 defined position.

If the first coil 13 is activated or is put under tension and the second coil 14 is deactivated, then forms between the first coil 13 and the armature 15, a magnetic field, which causes the armature 15 by an electromagnetic force to the right is pulled toward the first coil 13, wherein the electromagnetic force overcomes the restoring force of the spring 21. Accordingly, the armature 15 moves to the left to a second switching position when the second coil 14 is activated and the first coil 13 is deactivated.

The switching valve 9 can be switched both with alternating voltage (AC) and with direct voltage (DC). Basically, a direct current supply of the first coil 13 or the second coil 14 would be advantageous because a permanent power supply and thus electromagnetic power delivery would be guaranteed. However, a supply of the connecting rod 7 with AC voltage is easier to implement. In this case, the anchor element 15, which is formed in this first embodiment of a single anchor, although light, because the electromagnetic forces are not continuously present, but vary with the frequency of the alternating current. Due to the storage by the first spring 21 and the second spring 22 and, at least in this first embodiment, the damping by the in a first gap 28 or in a second gap 29 between the armature 15 and the receptacle 20 located hydraulic medium remains the desired switching position during However, an entire cycle of the alternating current is substantially preserved. If the springs 21, 22 are set in such a manner that the neutral position corresponds to a central position of the armature 15 in the receptacle 20, then neither the hydraulic medium supply line nor the hydraulic medium drainage are connected to the switching connections HD1, HD2. This corresponds to a neutral switching position in which no undesirable length adjustment can occur by actuation of the hydraulic device 8.

Since the AC voltage is preferably generated by an induction loop between the connecting rod 7 and the housing of the reciprocating engine, the frequency of the speed of the crankshaft to which the connecting rod 7 is fixed by means of the main bearing depends. At higher speeds of the crankshaft, the duration of the phases during a cycle during which no voltage is applied, decreases, so that the armature 15 remains permanently in the respective switching position due to its inertia, even if the electromagnetic forces during a cycle briefly suspended or weakened are.

The armature 15 has radial supply bores, which are connected in a fluid-communicating manner with axial supply bores 17. Furthermore, the armature 15 has radial drainage holes, which are connected in a fluid-communicating manner with axial drainage bores 19a, 19b.

The axial drainage bore 19a terminates with the first outlet 2, the axial drainage bore 19b with the second outlet 3. Depending on the switching position of the armature 15, right or second or left or first, the radial drainage holes 18 with the first switching port HD1 connected or the radial drainage holes 18b connected to the second switching port HD2 fluidkommunizizierend.

In the right and second switching position of the armature 15 shown in Figures 6 and 7, a second gap 29 is formed between the armature 15 and the left side of the receptacle 20, which is a fluidkommunizierende connection between the axial feed bores 17 and a second circulation groove 34 of the receptacle 20, which is formed in this area by the connecting rod 7, produces. In turn, the second switching port HD2 opens into the second Umlaufnut 34.

Accordingly, in the first switching position of the first exemplary embodiment shown in FIG. 6, a first gap 28 is formed between the first coil 13 or the receptacle 20 and the armature 15 (not shown). In this case, the axial supply bores 17 are fluid-communicatively connected to the first switching port HD1 via the first gap 28 and the first circulating groove 33.

FIG. 7 shows a cross section along the plane C-C through the armature 15 according to FIG. 6. FIG. 8 shows a cross section of the armature element along the sectional plane D-D in FIG. 6.

FIG. 9 shows the anchor element 15 according to FIG. 6 in a perspective view. Clearly visible is the Umlaufnut 35 of the armature, which connects the radial supply holes 16 on the outside of the anchor member 15 and ensures that, regardless of the angular position about the axis of the anchor member 15, always a fluidkommunizierende connection between radial supply holes 16 and the inlet 1 can be guaranteed, ie even if none of the supply bores 16 is aligned with the inlet 1.

Correspondingly, the first circulating groove 31 in the receptacle 20 and the second circulating groove 34 in the receptacle 20 ensure a fluid-communicating connection between the radial drainage bores 18a, 18b and the first switching port HD1 and the second switching port HD2. As an alternative to the circulation grooves 33, 34 of the receptacle 20, these circulation grooves could also be provided as second circulation grooves in the anchor element 15 at the level of the respective radial drainage bore 18a and the radial drainage bore 18b. FIG. 10 shows the flow direction of the hydraulic medium in the first exemplary embodiment of the switching valve 9 according to FIG. 6, when this is in the second switching state and a second pressure chamber or a second chamber is actively or passively filled with hydraulic medium and a first chamber or a first pressure chamber is active or is drained passively.

The hydraulic medium flows through the inlet 1 via the radial supply bores 16 in the axial supply bores 17 and from there into the second gap 29. From the second gap 29, the hydraulic medium or oil can now flow into the second circulation groove 34 of the receptacle 20 and from there reach the second pressure chamber and the second chamber via the second switching port 2.

Liquid from the first pressure chamber or chamber is drained via a conduit to the first switching port HD1 and reaches the first circulation groove 33 in the receptacle 20 which is in fluid communication with the radial drainage holes 18a so that the oil passes therethrough reaches the axial drainage hole 19a and from there the switching valve 9 and the connecting rod 7 leaves. The flow of oil is indicated by arrows.

FIG. 11 shows a second exemplary embodiment of the switching valve 9 according to the invention. This embodiment also preferably has a single armature as anchor element. This armature 15 also has radial drainage bores 18a, 18b and axial drainage bores 19a, 19b. Also in this second embodiment, a neutral switching position is determined by the restoring force of springs 21, 22, and also switch positions, which can cause a change in the length L of the connecting rod 7, by an induction of electromagnetic fields in the first coil 13 and in the second coil 14, which cooperate with the armature 15 as an electromagnetic actuator, respectively. In contrast to the first embodiment of Fig. 6, the armature 15 extends in the axial direction but only over a small area, which in particular less than the axial extent of the coils 13, 14, inside these coils when it is in a neutral position , For this purpose, the cover elements 23 preferably have extensions which extend in the interior of the coils 13, 14 towards the center of the switching valve 9 and further preferably limit an axial movement of the armature 15. Therefore, when the armature 15 is in the first or second switching position, a large part of the magnetic flux takes place through the cover element 23 and only a small part through the armature element 15.

In contrast to the first exemplary embodiment of FIG. 6, the second exemplary embodiment furthermore preferably has a sleeve 40, which is received in the receptacle 20 in the connecting rod 7 and supports the armature 15 in an axially displaceable manner. The sleeve has a circulation groove 41 which connects inlet channels 44 in a fluid-communicating manner with the circulation groove 35 of the armature 15. Furthermore, the sleeve has feed channels 42, which are set up in order to connect the circulation groove 35 of the armature 15 in a fluid-communicating manner with the circulation grooves 33, 34 of the receptacle 20 in accordance with the respective switching position. Finally drainage channels 43 serve the sleeve 40 to the circulation grooves 33, 34 of the receptacle 20, depending on the switching position of the armature 15, to communicate with the radial drainage holes 19a, 19b fluidkommunizierend.

FIG. 12 shows a perspective view of a sleeve 40 of the second exemplary embodiment of the switching element 9 according to FIG. 11.

Figure 13 shows a perspective view of the armature 15 of the second embodiment of the switching element 9 according to Figure 1 1. In this view of the armature 15 it can be seen that it has second circulating grooves 36 which fluidly connect the radial drainage bore 18a and the radial drainage bore 18b , Furthermore, ask these recirculating grooves ensure that, regardless of the rotational position of the armature 15 with respect to its axis, a fluid-communicating connection between the radial drainage holes 18a, 18b and the respective drainage channel 43 of the sleeve can be made.

In the second switching state shown in FIG. 11, in which a second pressure chamber or a second chamber, which is connected to the switching port HD2, can be filled, and a first chamber or a first pressure chamber, which is connected to the switching device. Port HD1 is connected, can be drained, the inlet 1 is in fluid communication with the first Umlaufnut 35 of the first armature 15th

On the opposite side of the anchor element 15, the first circulation groove 35 is in fluid communication with supply channels 42 of the sleeve 40, which in turn are in fluid-communicating connection with the second circumferential groove of the receptacle 20. This in turn is in connection with the second switching port HD2.

The first switching port HD1 is in fluid-communicating connection with the first circumferential groove 33 of the receptacle 20, which in turn is connected in a fluid-communicating manner via drainage channels 43 to the radial drainage bore 18a. The radial drainage bore 18a in turn communicates fluidly with the axial drainage bore 19a which opens into the first outlet 2.

Correspondingly, in the first switch position, not shown, of the armature 15, the inlet 1 would be connected in a fluid-communicating manner via a circulation groove 41 of the sleeve and the inlet channels 44 would be in fluid communication with the first circulation groove 35 of the sleeve 15. The first circulation groove 35 would in turn be connected in a fluid-communicating manner via the supply channels 42 of the sleeve and via the first circulation groove 33 of the receptacle 20 to the first switching port HD1. Conversely, in this switching state would be the second switching port HD2 via the second circulation groove 34, the drainage channels 43, the second circumferential groove of the anchor member 36, the radial drainage holes 18b and the axial drainage hole 19b to the second outlet 3 fluidkommunizizierend.

Figure 14 indicates the flow of a hydraulic medium in the second switching position of the switching element 9 according to the second embodiment by arrows. From the inlet 1 sucked or pressed hydraulic fluid flows through the Umlaufnut 41 of the sleeve 40 and the inlet channels 44 of the sleeve 40 in the first Umlaufnut 35 of the armature 15 and from there to the other side of the armature 15, where the hydraulic medium, the first Umlaufnut 35 via supply channels leaves the sleeve and flows into the second circulation groove 34 of the receptacle 20. From there, the hydraulic medium flows via the second switching port HD2 to the second pressure chamber or the second chamber.

Hydraulic medium or oil, which is pressed from the first pressure chamber or the first chamber in the first switching port HD1, flows to the first circumferential groove 33 of the receptacle 20 and from there into the inlet channel 44 of the sleeve and into a second circumferential groove 36 of the Anchoring element 15. From this circulation groove 36, the hydraulic medium passes via the radial drainage bore 18a into the axial drainage bore 19a and leaves therefrom the switching valve 9 or the connecting rod 7 via the first outlet 2.

An advantage of the second embodiment compared to the first embodiment is in particular that can be dispensed with in the anchor element on radial supply bores and axial supply bores. Furthermore, the armature 15 can be made smaller and thus lighter. This reduces the friction between the armature 15 and its storage, which at high speeds by the large occurring accelerations and centrifugal forces in the worst case can lead to a blockage, but at least to a hindrance to the movement of the armature 15. Figure 15 illustrates a modified embodiment of the second embodiment of the switching valve 9.

This modification differs from the embodiment in FIG. 11 essentially in that, as the rear part devices 21 and 22, pairs of permanent magnets are used. For example, the permanent magnet 21 b of a first rear part of the permanent magnet 21 a repelled, since they are arranged with opposite polarization. The same applies to the permanent magnet 22b with respect to the permanent magnet 22a, which are also arranged with opposite polarization. The permanent magnets 21a and 22a are in this case, as before the springs 21, 22, mounted on the cover elements 23. By the restoring forces, the anchor element 15 is preferably held in a neutral position when the coils 13, 14 are both not activated. In this neutral position, as in the previous embodiments, both inflow and outflow to and from the switching ports HD1, HD2 are blocked or blocked.

If the first coil 13 is energized, the anchor member moves to the left, since the attraction effect of the first coil 13, the repulsion of the magnet pairs 21 a, 21 b outweighs. If the second coil 14 is energized, the anchor member 15 moves to the right, since the attraction effect of the second coil 14, the repulsion of the magnet pairs 22a, 22b outweighs.

The flow of hydraulic medium through the switching valve shown in Fig. 15 is at least substantially identical to that of the embodiment of FIG. 1 in the first and second switching position.

FIG. 16 shows another alternative embodiment of the second exemplary embodiment of FIG. 11. Again, the rear part devices 21, 22 are designed as magnet pairs 21 a, 21 b and 22a, 22b. In contrast to the previous alternative embodiment, the permanent magnets are the Magnet pairs 21a, 21b and 22a, 22b, however, now aligned with rectified polarization, so that they act on each attracting.

If the first coil 13 is energized in this case, the armature 15 moves to the left, since the attraction effect of the first coil 13 is supported by the magnet pairs 21 a, 21 b on the left side. When the second coil 14 is energized, the armature 15 moves to the right, since the attraction effect of the second coil 14 is supported by the right magnet pairs 22a, 22b.

If neither of the two coils 13, 14 is energized, then the anchor element 15 remains in the last position assumed. Therefore, there is no middle position. The embodiment of FIG. 16 is therefore to be regarded as bistable, since there are only two equilibrium states of the armature 15. The flow of a hydraulic medium through this embodiment of the switching valve 9 is at least substantially identical to that of FIGS. 11 and 15.

FIG. 17 relates to a third exemplary embodiment of the switching valve 9 according to the invention.

This embodiment has only a single coil 13 and a single rear-part device 22. In the embodiment shown, the rear part device is formed by pairs of permanent magnets 22a, 22b, which are arranged with the same polarization, that is, attracting each other.

When the coil 13 is energized, the armature 15 moves to the left, since the attraction effect of the coil 13 is greater than the attraction of the magnet pairs 22a, 22b right. If the coil 13 is not energized, the armature 15 is due to the attraction of the magnet pairs 22a, 22b in the right position. Also in this embodiment, there is no middle position, so that it is also a bistable switching valve 9 here. The flow of a hydraulic medium through the switching valve 9 corresponds at least substantially to that of the embodiment of the second embodiment.

The pairs of magnets 22a, 22b may alternatively be arranged on the left side of the switching valve 9, which then have to be arranged with opposite polarization, so that they repel each other.

The third embodiment is particularly characterized by the fact that it is possible to dispense with a coil and a rear part device, which makes the switching valve 9 lighter and simpler in construction.

FIG. 18 shows an alternative embodiment of the third exemplary embodiment of the switching valve 9 according to the invention according to FIG. 17.

Instead of the magnet pairs as the rear part means now a spring 21 is provided, which causes a restoring force between the cover member 23 and the anchor member 15.

When the coil 13 is energized, the armature element 15 moves counter to the spring force of the spring 21 to the left. If the coil 13 is not energized, the armature 15 moves due to the spring force to the right.

Also in this alternative embodiment, there is no neutral position, so that it is also a bistable switching valve 9 here.

Alternatively, the spring 21 could also be replaced by a spring 22 on the left side of the switching valve 9, which attracts between the lid member 23 and the armature 15 on the left side. In this case, when the spool 13 is activated, the armature 15 would be pulled leftward against the spring force of the already tensioned spring 22. Figure 19 shows a fourth embodiment of a switching element according to the invention 9. Also in this embodiment, the anchor member 15 is a single armature, which are moved by coils 13, 14 by means of electromagnetic forces in a first switching position (anchor right) and a second switching position (anchor left) can.

In this embodiment, no back-up devices are used. In the illustrated second switching position, the inlet 1 is above the second gap 29 and the second passage with the axial inlet bore 17 and thus also with the radial inlet bore 16 in fluidkommunizierender connection, so that the inlet 1 is connected to the second switching port HD2 fluidkommunizizierend ,

FIG. 20 shows the flow of a hydraulic medium or oil through the switching valve 9 according to the fourth exemplary embodiment. This flows through the inlet 1 and the second gap 29 into the second passage 39 and from there through the axial feed bore 17 into the radial feed bore 16, where the hydraulic medium leaves the switching valve through the second switching port HD2. In the first switching position, the hydraulic medium would flow according to the inlet through a first gap 28 (not shown) in the openings of the first passages 38 and from there into the axial feed bore 17 and the radial feed bore 16 to the first switching port HD1 where the oil would leave the switching valve 9.

The drainage of a hydraulic device 8 or an actuating valve 12 is preferably carried out separately from the switching valve 9 in the fourth embodiment.

FIG. 21 shows a fifth exemplary embodiment of a switching valve 9 according to the invention. The anchor element 15 of this embodiment consists of two anchors, a first anchor 15a and a second anchor 15b. These armatures 15, 15b extend in the axial direction of the switching valve 9 and comprise the first coil 13 and the second coil 14 with cylindrical projections.

Between the cylindrical extension of the first armature 15a and the first coil 13, a first spring is disposed as the rear part 21, between the cylindrical extension of the second armature 15b and the second coil 14, a second spring is arranged as the second rear part 22. The springs support the anchors 15a, 15b in each case opposite a central part 24 of the receptacle. The armature 15a is guided by the middle part 24 and a first closure element 25, the second armature 15b by the middle part 24 and a second closure element 26.

The springs 21, 22, which are biased against the cylindrical extensions of the armatures 15a, 15b, hold the respective armatures 15a, 15b in a defined position, in particular a neutral position. The closure elements 25, 26 limit the movement of the armature 15a, 15b to the outside and store or guide the armature together with the central part 24th

The closure elements have radial drainage bores 18 and axial drainage bores 19, which are respectively connected in a fluid-communicating manner with the first port HD1 and the second port HD2. The axial drainage bores can be connected in a fluid-communicating manner both with the outlets 2, 3, and in the other switching position of the armatures 15a, 15b with gaps 28, 29 which can be connected in a fluid-communicating manner to the inlets 1 via cavities 27 in the anchors 15a, 15b , In this way, the drainage holes can also be used as a supply line to the switching terminals HD1 and HD2.

When the first coil 13 is energized, it attracts the first armature 15a to itself and the second coil 14 is energized, this pulls the second armature 15b to itself. Is not energized, both coils 13, 14 are inactive and the springs 21, 22 press both armatures 15a, 15b against the opening of the axial drainage 19. In this way, neither feeding nor draining the switching ports HD1, HD2 is possible, so that one length of the connecting rod is kept constant. This corresponds to a neutral switching position.

In Figure 21, the first armature 15a is in the drainage switching position, i. the hydraulic fluid can escape via the axial drainage bore 19 and the first outlet 2. The second armature 15b is in a Zuführschaltstellung, so that the right inlet 1 via the cavity 27 and the gap 29 and the radial drainage bore 18 to the second switching port HD2 is fluidkommunizizierend. The axial drainage holes 19 are closed on this right side by the second cover element 32, which is held by a spring plate 45.

FIG. 22 shows a side view of the elements of the switching valve 9 according to FIG. 21 without receptacle 20. FIG. 23 shows a perspective top view of the armature 15b. Clearly visible is the cylindrical extension, in which the cavities 27 are introduced. Figure 24 shows a section through the switching element 9 along the cutting plane D-D.

FIG. 25 again shows a view according to FIG. 21 of the fifth exemplary embodiment, the flow of hydraulic medium being indicated by arrows. In the switching position of the first armature 15a and the second armature 15b shown, hydraulic fluid can pass through the cavity 27 and the second gap 29 into the axial bores 19 via the inlet 1 and from there via the radial bores 18 and a circulation groove 30 of the closure element 31 get into the second switching port HD2. In contrast, hydraulic medium from the first switching port HD1 via the radial bores 18 of the first closure member 25 and its axial Bore 19 from the second outlet 2, as indicated by the arrows, emerge.

FIG. 26 shows a sixth exemplary embodiment of the switching element 9 according to the invention. Also in this exemplary embodiment, as in the fifth exemplary embodiment of FIGS. 21 and 25, the anchor element 15 consists of two anchors 15a, 15b, which are each displaceable between two switch positions.

When the first coil 13 is activated, the first armature element 15a overcomes the restoring force of the spring 21 and is attracted to the first coil 13. This creates a first gap 28 (not shown) and the first outlet 2 is closed. If the second coil 14 is activated, the second gap 29 is open and the second outlet 3 is closed.

Also in this embodiment, the closure elements 25, 26 have radial bores 18 and axial bores 19. The cover elements 31, 32 cooperate, as in the fifth exemplary embodiment, with the anchors 15a, 15b via spring plates 45 and securing elements 37, so that the cover elements 31, 32 are moved during a movement of the anchors 15a, 15b.

In a feed switching position for the first switching terminal HD1, the first coil 13 is activated so that a gap 28 (not shown) is formed between the armature 15a and the first terminal member 25, and at the same time, the axial drainage sheets 19 in the first shutter member 25 closed by the first cover element. Now, the first switching port HD1 communicates with the inlet 1 via the first circulation groove 33 in the receptacle 20 via the first gap 28, first passages 38 and the radial drainage bore 18 in fluid-communicating connection. Inverted, the first switching port HD1 in the drainage switching position of the first armature 15a shown in FIG. 26 passes over the radial drainage bore 18 and the axial ones Drainage holes 19 in fluid communication with the first outlet 2, since the axial bores 19 are not closed by the first lid member. Corresponding switching positions also exist for the second armature 15b.

Fig. 27 indicates the flow of the hydraulic medium in switching valves 9 in the switching state of FIG. 26 of the sixth embodiment by arrows.

The hydraulic medium can pass via the inlet 1 and a second circulation groove 34 of the receptacle 20 into the second gap 29 and from there via the second passages 39 into the radial bore 18, from where the hydraulic medium can flow to the second switching port HD2. On the other hand, hydraulic medium can pass from the first switching port HD1 through the radial drainage bore 18 into the axial drainage bores 19 and from there out of the first outlet 2.

The exemplified embodiments are merely examples that are not intended to limit the scope, applications and structure of the invention in any way. Rather, by the foregoing description, the skilled person will be given a guideline for the implementation of at least one exemplary embodiment, wherein changes, in particular combinations of individual features of different embodiments, with regard to the function and arrangement of the described components can be made without the disclosed scope leave. LIST OF REFERENCE NUMBERS

1 inlet

 2 First outlet

 3 Second outlet

 HD1 First switching connection

 HD2 second switching connection

 L connecting length

 7 connecting rod

 8 hydraulic device

 9 switching valve

 10 Hydraulic medium supply line

 1 1 drainage pipe

 12 closing valve

 13 First coil

 14 Second coil

 15 anchor element

 15a First anchor

 15b Second anchor

 16 Radial supply bore

 17 Axial feed bore

 18a, 18b Radial drainage hole

 19a, 19b Axial drainage hole

 20 recording

 21 First rear section device

 22 Second rear section device

 23 cover element

 24 middle section of the picture

 25 First closure element

 26 Second closure element

 27 cavity

28 First gap Second gap

 Groove of a closure element

First cover element

 Second cover element

 First circumferential groove of the recording

Second circumferential groove of the recording

First circumferential groove of an anchor element

Second circumferential groove of the anchor element

fuse element

 First passage

 Second passage

 shell

 Circumferential groove of the sleeve

 Supply channel of the sleeve

 Drainage channel of the sleeve

 Inlet channel of the sleeve

 spring plate

Claims

claims

1. Length-adjustable connecting rod (7) for a reciprocating piston engine, in particular for a reciprocating internal combustion engine, comprising:

 a hydraulic device (8), with which a length of the connecting rod is adjustable, and

 a switching valve (9) for controlling inflow and outflow of a hydraulic medium in or out of the hydraulic device (8), wherein the switching valve (9) is electromagnetically actuated.

2. Length-adjustable connecting rod (7) according to claim 1,

 the connecting rod (7) having a first connecting rod portion (7a) and a second connecting rod portion (7b),

 wherein the two connecting rod sections (7a, 7b) for adjusting a

Connecting rod length (L), in particular along a longitudinal axis of the

Connecting rod (7), are displaceable relative to each other,

 wherein the hydraulic device (8) has a first hydraulic cylinder with a first pressure chamber and a second pressure chamber, which are separated by a piston, wherein one of the two

 Connecting rod sections (7a) with the hydraulic cylinder and the other of the two connecting rod sections (7b) is connected to the piston, and

 wherein the connecting rod (7) has a hydraulic medium supply line (10) and / or a drainage (1 1), which are fluidkommunizierend connected to the first pressure chamber and / or the second pressure chamber.

3. Length-adjustable connecting rod (7) according to claim 1,

 the connecting rod (7) having a first connecting rod portion (7a) having a nut portion and a second connecting rod portion (7b) having a spindle element portion,

wherein the nut portion and the spindle member portion engage with each other and for adjusting a connecting rod length, in particular along a longitudinal axis of the connecting rod (7) are rotatable relative to each other,

 wherein the hydraulic device (8) is arranged to effect a relative rotation of the nut section and the spindle element section, and wherein the connecting rod (7) has a hydraulic medium supply line (10) and / or a drainage (11) connected to the

 Hydraulic device fluidkommunizierend connectable.

4. Length-adjustable connecting rod (7) according to claim 2 or 3, wherein the hydraulic device (8) further comprises an actuating valve (12), in particular a slide valve or rotary valve, wherein the switching valve (9) for the hydraulic actuation of the actuating valve (12) is and the actuating valve (12) for opening or closing of fluid-communicating connections of the two pressure chambers with the hydraulic medium supply line (10) and / or the drainage (1 1) or for generating a relative rotation between the nut portion and the spindle portion is formed.

5. Connecting rod according to claim 4, wherein the actuating valve has a second hydraulic cylinder having a first chamber and a second chamber, which are separated by an actuating piston, wherein the actuating piston is arranged to actuate at least one closing valve, in particular a ball valve or with the mother section or the spindle section is rotatably connected.

6. Length-adjustable connecting rod (7) according to any one of the preceding claims, wherein the switching valve (9), in particular a 4/3 way valve, comprising:

 an inlet (1),

 a first outlet (2),

a second outlet (3), a first switching port (HD1), which in a first switching state of the switching valve (9) with the inlet (1) or in a second switching state of the switching valve (9) with the first outlet

(2) is connected in fluid communication, and

 a second switching port (HD2), which in a second switching state of the switching valve (9) with the inlet (1) or in a first switching state of the switching valve (9) with the second outlet

(3) is connected in a fluid-communicating manner,

 wherein the switching valve (9) is in fluid communication with the hydraulic device (8) via the first switching port (HD1) and the second switching port (HD2).

7. Length-adjustable connecting rod (7) according to claim 6,

 wherein the first pressure chamber or the first chamber with the first switching port (HD1) and the second pressure chamber or the second chamber with the second switching port (HD2) are fluid-communicatively connected.

8. Length-adjustable connecting rod (7) according to one of the preceding claims, wherein the switching valve (9) has a neutral switching position, in which inflow and outflow into / from the hydraulic device (8) is prevented and preferably the switching valve (9) is not electromagnetic is actuated, in particular no electromagnetic induction takes place.

9. Length-adjustable connecting rod (7) according to one of the preceding claims, wherein the switching valve (9) comprises:

 a first coil (13); and

an anchor element (15) which has a ferromagnetic or magnetizable material and is displaceable between exactly two switch positions.

10. Length-adjustable connecting rod (7) according to claim 9, wherein the anchor element (15) and the first coil (13) are mounted in a common receptacle (20), and

 wherein the anchor element (15) by a single first rear part means (21), in particular a spring element which cooperates with the receptacle (20), in particular with cover elements (23) of the receptacle (20), in a defined position, preferably a first switching position is held.

A length-adjustable connecting rod (7) according to claim 9, wherein the switching valve (9) further comprises:

 a second coil (14) spaced from the first coil (13), and

 wherein the anchor element (15) is displaceable between at least two, in particular three, switching positions.

12. Length-adjustable connecting rod (7) according to claim 1 1, wherein the anchor element (15) and the coils (13, 14) are mounted in a common receptacle (20), and wherein the anchor element (15) by two return part means (21, 22 ), in particular spring elements which cooperate with the receptacle (20), in particular with cover elements (23) of the receptacle (20), are held in a defined position, preferably a neutral switching position.

13. Length-adjustable connecting rod (7) according to any one of claims 9 to 12, wherein the anchor element (15) has at least one radial feed bore (16) and at least one axial feed bore (17), which are fluidkommunizierend connected and are adapted to the

Inlet (1) with the first switching port (HD1) or with the second switching port (HD2) to connect fluidkommunizizierend.

14. Length-adjustable connecting rod (7) according to one of claims 9 to 13, wherein the anchor element (15) has at least one radial drainage bore (18) and at least one axial drainage bore (19), which are connected in a fluid-communicating manner, to connect the first switching port ( HD1) to the first outlet (2) and the second switching port (HD2) to the second outlet (3) fluidly communicating connect.

15. A length adjustable connecting rod (7) according to any one of claims 9 to 14, wherein the anchor member has two axial drainage holes (19a, 19b), and wherein radial drainage holes (18) either with a first axial drainage bore (19a) or with a second axial drainage bore (19b), wherein the radial drainage holes (18), which are connected to different axial drainage holes (19), are axially in relation to an axis of the anchor element (15) each in a different plane.

16. A length-adjustable connecting rod (7) according to claim 14 or 15, wherein at least one radial drainage bore (18) which is connected to the second axial drainage bore (19b), in the first switching state, the second switching port (HD2) with the second outlet ( 3), and wherein at least one radial drainage bore (18) connected to the first axial drainage bore (19a) connects the first switching port (HD1) to the first outlet (2) in the second switching state.

17. Length-adjustable connecting rod (7) according to any one of claims 13 to 16, wherein the anchor element (15) has a first circumferential groove (35) which connects the radial supply bores (16) fluid communicating with each other.

18. Length-adjustable connecting rod (7) according to one of claims 9 to 16, wherein the anchor element (15) has a first circulation groove (35) which is adapted to the inlet (1) in a first switching state with the first switching port (HD1). and in a second switching state with the second switching port (HD2) to connect in fluid communication.

19. A length-adjustable connecting rod (7) according to any one of claims 9 to 18, wherein the anchor member has a first armature (15 a) and a second armature (15 b), each of a rear part means (21, 22) at a central part (24) of Recording (20) are supported.

20. Length-adjustable connecting rod (7) according to one of claims 9 to 19, which has two closure elements (25, 26), wherein a first closure element (25) with respect to the first armature (15a) opposite a central part (24) of the receptacle (15). 20) is arranged and wherein a second closure element (26) with respect to the second armature (15b) opposite the central part (24) is arranged.

21. Length-adjustable connecting rod (7) according to claim 20, wherein the first closure element (25) radial (18) and axial bores (19) which are interconnected and in the first switching state, the inlet (1) and the first switching port ( HD1) connect fluidkommunizierend and in the second switching state the first outlet (2) and the first switching port (HD1) fluidkommunizizierend connect and wherein the second closure element (26) radial (18) and axial bores (19), which in the second switching state Inlet (1) and the second switching port (HD2) connect fluidly communicating and in the first switching state, the second outlet (3) and the second switching port (HD2) fluidly communicating connect.

22. Length adjustable connecting rod (7) according to any one of claims 19 to

21, wherein between the anchors (15a, 15b) and the receptacle (20) at least one cavity (27), in particular at least one axial groove, is formed, which is preferably formed in the anchors (15a, 15b).

23. Length adjustable connecting rod (7) according to any one of claims 20 to

22, wherein in the first switching state between the first closure element (25) and the first armature (15a), a first gap (28) is formed, which the inlet (1) with the radial (18) and axial bores (19) of the first closure element , in particular via the cavity (27), fluid communicating connects, and

 wherein in the second switching state between the second closure element (26) and the second armature (15b), a second gap (29) is formed, which the inlet (1) with the radial (18) and axial bores (19) of the first closure element (25 ), in particular via the cavity (27), fluidkommunizierend connects.

24. Length adjustable connecting rod (7) according to any one of claims 20 to

23, wherein the first closure element (25) and the second closure element (26) grooves (30), in particular circulation grooves, arranged to each of a plurality of radial bores (18) to communicate with each other in a fluid-communicating manner.

25. Length-adjustable connecting rod (7) according to one of claims 9 to 24, wherein the anchor element (15; 15a 15b) of the closure elements (25, 26) and / or of the receptacle (20) are guided.

26. Length-adjustable connecting rod (7) according to one of claims 20 to 25, which has a first cover element (31) which closes the axial bores (18) of the first closure element (25) in the first switching state to the outside of the switching valve (9) . and a second cover element (32) which closes the axial bores (18) of the second closure element (26) in the second switching state to the outside of the switching valve (9).

27. Length-adjustable connecting rod (7) according to one of claims 20 to

26, wherein the receptacle (20) in the region in which the inlet (1) is arranged, which in particular is divided into two inlet lines, has at least one circumferential groove (33), arranged around the first gap (28) between the first Closing element (25) and the first armature (15a) and / or the second gap (29) between the second closure element (26) and the second armature (15b) fluidly communicating with the inlet 1 to connect.

28. Length adjustable connecting rod (7) according to any one of claims 20 to

27, wherein between the first armature (15a) and the first closure element (25), a first passage (38), in particular an opening is arranged, which connects the first gap (28) with the first switching Anschuss (HD1), and wherein between the second armature (15b) and the second closure element (26), a second passage (39), in particular an opening is arranged, which connects the second gap (29) with the second switching port (HD2).

29. A reciprocating piston engine, in particular reciprocating internal combustion engine, which has a length-adjustable connecting rod (7) according to one of claims 1 to 28

30. Vehicle with a reciprocating engine, in particular a reciprocating internal combustion engine, which has a length-adjustable connecting rod (7) according to one of claims 1 to 28.