The present disclosure relates to a sliding cam system for a variable valve train, to a variable valve train, to a motor vehicle and to a method for operating an internal combustion engine.
Valve-controlled internal combustion engines comprise one or more controllable inlet and outlet valves per cylinder. Variable valve control systems make flexible actuation of the valves possible in order to change the opening time, closing time and/or the valve lift. As a result, the engine operation can be adapted, for example, to a specific load situation.
DE 196 11 641 C1 has disclosed a valve train, by way of which the actuation of a gas exchange valve using a plurality of different lift curves is made possible. To this end, a sliding cam with at least one cam section which comprises a plurality of cam tracks is mounted on the camshaft fixedly so as to rotate with it but such that it can be displaced axially, which sliding cam comprises a lift contour, into which an actuator in the form of a pin is introduced radially from the outside in order to produce an axial displacement of the sliding cam. By way of the axial displacement of the sliding cam, a different valve lift is set at the respective gas exchange valve. After the axial displacement of the sliding cam relative to the camshaft, said sliding cam is latched in its axial relative position on the camshaft by virtue of the fact that at least one spring-loaded latching ball which is received and mounted in the camshaft engages into at least one latching groove in a manner which is dependent on the axial relative position. The axial displacement of the sliding cam in order to change the valve lift takes place exclusively in what is known as the base circle of the or each cam section or the cam tracks thereof. As a result, the switching rotational speed of the valve train is limited.
The shorter the base circles of the cams which coincide with one another, the less time is available for the axial displacement of the sliding cam. The less time is available for the axial displacement of the sliding cam system, the steeper the ramp of the switching guide plate (engagement track) has to be configured. In the case of the axial displacement of the sliding cam, considerable forces can occur in part in the case of the contact between the pin of the actuator and the switching guide plate. Particularly great forces can occur, in particular, in the case of steep ramps, which particularly great forces can have a negative influence on the service life of the sliding cam system and/or limit a maximum switching rotational speed.
DE 10 2012 112 482 A1 has disclosed a method for operating an internal combustion engine having a plurality of cylinders. In order to actuate gas exchange valves, the internal combustion engine comprises a valve train with at least one rotatably mounted camshaft and with at least one sliding cam which can be displaced axially on the respective camshaft. The respective sliding cam comprises at least one guide plate section with at least one groove which is configured on an outer circumferential face of the respective guide plate section, the respective sliding cam comprising at least one cam section with a plurality of cam tracks for setting different valve lifts. In order to bring about an axial displacement of the respective sliding cam, an actuable pin of an actuator is introduced radially from the outside into a groove of the guide plate section. The axial displacement of the respective sliding cam is carried out in a manner which is dependent on the axial displacement direction of said sliding cam and/or in a manner which is dependent on a valve play outside a base circle of the or each cam section of said sliding cam.
The present disclosure is based on the object of providing an alternative or improved sliding cam system and a method for operating an internal combustion engine, in the case of which the forces which occur during the displacement operation of the cam carrier are reduced in comparison with conventional systems.
The sliding cam system is configured for a variable valve train of an internal combustion engine of a motor vehicle, in particular a commercial vehicle. The sliding cam system comprises a camshaft and a cam carrier. The cam carrier is arranged on the camshaft fixedly so as to rotate with it and such that it can be displaced axially between a first axial position and a second axial position, and comprises a first cam, a second cam and a first engagement track for the axial displacement of the cam carrier. The sliding cam system comprises a cam follower which is operatively connected to the first cam in the first axial position of the cam carrier and is operatively connected to the second cam in the second axial position of the cam carrier. The sliding cam system comprises a first actuator which comprises an element which can be retracted and extended, in particular a pin, for engaging into the first engagement track for the axial displacement of the cam carrier. The first cam and the second cam are arranged offset with respect to one another along a longitudinal axis of the camshaft. The first cam comprises a base circle region and a valve lift region with a limiting section which adjoins the base circle region of the first cam. The second cam comprises a base circle region and a valve lift region with a limiting section which adjoins the base circle region of the second cam. The limiting section of the first cam and the limiting section of the second cam are of identical configuration and are arranged at an identical circumferential position about the longitudinal axis of the camshaft. The first actuator, the cam follower and the first engagement track are arranged and configured in such a way that an axial displacement of the cam carrier can be carried out while the cam follower is operatively connected to the limiting section of the first cam and/or the limiting section of the second cam.
The sliding cam system makes an extension of the available time period for the axial displacement of the cam carrier possible by way of an expansion into the limiting sections of the cams. On account of the larger switching region, the accelerations and therefore the mass forces can be reduced in the case of an identical switching rotational speed for the axial displacement. This can firstly be utilized, for example, to increase the functional reliability and service life on account of lower forces and pressures. Secondly, this can be utilized, for example, to increase the maximum switching rotational speed of the system.
In particular, the first cam can be configured so as to directly adjoin the second cam.
In one particularly preferred embodiment, the first actuator, the cam follower and the first engagement track are arranged and configured in such a way that an axial displacement of the cam carrier begins and/or ends while the cam follower is operatively connected to the limiting section of the first cam or the limiting section of the second cam. In this way, in particular, the beginning and/or the end of the axial displacement of the cam carrier can be moved into the limiting regions. In this way, the available time duration for the axial displacement of the cam carrier can be extended.
In one embodiment, the limiting sections extend over a region of greater than or equal to 1° camshaft angle.
In one development, the limiting sections extend over a region between 5° and 45° camshaft angle, in particular between 15° and 30° camshaft angle.
In a further embodiment, the limiting sections form a common flat ramp.
In one design variant, the limiting sections are arranged in a run-out region of the first and second cam. As an alternative or in addition, the axial displacement of the cam carrier begins when the cam follower is operatively connected to the limiting section of the first cam or the second cam. The axial displacement preferably ends while the cam follower is operatively connected to the base circle region of the first cam or the second cam. It is also possible, however, that the axial displacement does not end until in a further limiting section in a run-in region of the first or second cam, the further limiting sections of the first and second cam once again being of identical configuration and being arranged at an identical circumferential position about the longitudinal axis of the camshaft.
In a further design variant, the limiting sections are arranged in a run-in region of the first and second cam. As an alternative or in addition, the axial displacement of the cam carrier ends when the cam follower is operatively connected to the limiting section of the first cam or the second cam. The axial displacement of the cam carrier preferably begins while the cam follower is operatively connected to the base circle region of the first cam or the second cam. It is also possible, however, the axial displacement already begins in another limiting section in a run-out region of the first or second cam, the other limiting sections of the first and second cam once again being of identical configuration and being arranged at an identical circumferential position about the longitudinal axis of the camshaft.
In one exemplary embodiment, the cam carrier comprises a second engagement track for the axial displacement of the cam carrier in an opposed direction with respect to an axial displacement which is brought about by the first engagement track. Furthermore, the sliding cam system comprises a second actuator which comprises an element which can be retracted and extended, in particular a pin, for engaging into the second engagement track for the axial displacement of the cam carrier. The second actuator, the cam follower and the second engagement track are arranged and configured in such a way that an axial displacement of the cam carrier can be carried out (in particular, begins and/or ends) while the cam follower is operatively connected to the limiting section of the first cam or the limiting section of the second cam.
In particular, the first actuator and the second actuator can be provided separately from one another. It is also possible, however, that the first actuator and the second actuator are provided in a common housing.
The first engagement track and the second engagement track are preferably provided separately from one another. It is also possible, however, that the first engagement track and the second engagement track are arranged in an identical region of the cam carrier. The first engagement track and the second engagement track can preferably cross one another.
In a further exemplary embodiment, the first engagement track has a cross-sectional constriction for the reduction of the play between the first engagement track and that element of the first actuator which can be retracted and extended during the engagement (of the extended element into the first engagement track). The cross-sectional constriction is arranged in such a way that the reduction in the play takes place before the cam follower passes into an operative connection with the limiting section of the first cam or the second cam. In this way, that section of the engagement track which is provided for the reduction of the play does not shorten that section of the engagement track which is provided for the axial displacement of the cam carrier.
In order to achieve the same advantages, it is also possible that the second engagement track comprises a cross-sectional constriction for the reduction of the play between the second engagement track and that element of the second actuator which can be retracted and extended during the engagement (of the extended element into the second engagement track). The cross-sectional constriction is arranged in such a way that the reduction in the play takes place before the cam follower passes into an operative connection with the limiting section of the first cam or the second cam.
In one particularly preferred embodiment, the first engagement track and/or the second engagement track extend/extends spirally about the longitudinal axis of the camshaft.
In a further embodiment, that element of the first actuator and/or the second actuator which can be retracted and extended can be moved radially with regard to the longitudinal axis of the camshaft.
The present disclosure also relates to a variable valve train for an internal combustion engine. The variable valve train comprises a sliding cam system as disclosed herein. The variable valve train comprises a gas exchange valve, in particular an inlet valve or an outlet valve, which is operatively connected to the cam follower. The first cam and the second cam bring about different valve lifts, opening times and/or closing times of the gas exchange valve.
In one development, the gas exchange valve is an outlet valve. The first cam is configured for a normal operation mode of the internal combustion engine, in the case of which normal operation mode the first cam holds the outlet valve open in the exhaust stroke. The second cam is configured for an engine braking operation mode of the internal combustion engine, in the case of which engine braking operation mode the outlet valve is preferably first of all kept closed in the compression stroke and in the exhaust stroke and is opened before a top dead centre of a piston movement is reached.
In one exemplary embodiment, the second cam is configured in such a way that the outlet valve opens between 100° crank angle and 60° crank angle (crankshaft angle) before the top dead centre is reached. As an alternative or in addition, the second cam is configured in such a way that the outlet valve closes after the opening in the exhaust stroke in the region between the top dead centre and 30° crank angle after the top dead centre. As an alternative or in addition, the second cam is configured in such a way that the outlet valve closes after the opening in the compression stroke in the region between the bottom dead centre and 30° crank angle after the bottom dead centre.
The present disclosure also relates to a motor vehicle, in particular a commercial vehicle (for example, a truck or omnibus), comprising a variable valve train as disclosed herein or the sliding cam system as disclosed herein.
The present disclosure also relates to a method for operating an internal combustion engine with a sliding cam system. The sliding cam system comprises a cam carrier which is arranged fixedly on a camshaft so as to rotate with it, can be displaced axially, and comprises a first cam and a second cam. The first cam and the second cam in each case comprise a base circle region and a valve lift region with a limiting section which is arranged adjacently with respect to the respective base circle region. The limiting section of the first cam and the limiting section of the second cam are of identical configuration and are arranged at an identical circumferential position about a longitudinal axis of the camshaft. The sliding cam system comprises a cam follower which is selectively operatively connected to the first cam or the second cam. The method comprises the axial displacement of the cam carrier, the axial displacement of the cam carrier being carried out, in particular beginning or ending, while the cam follower is operatively connected to the limiting section of the first cam and/or the second cam.
The method affords the same advantages as the sliding cam system which is disclosed herein. In addition, the method has a higher flexibility, since it is not restricted to the axial displacement of the cam carrier by means of the actuators and engagement tracks as disclosed herein.
In particular, the method can use the sliding cam system disclosed herein, preferably with elements of actuators which can be retracted and extended radially and engage into spiral engagement tracks, for the axial displacement of the cam carrier. It is also possible, however, that the method uses a different displacement system for the axial displacement of the cam carrier.
In one embodiment, the axial displacement of the cam carrier begins while the cam follower is operatively connected to the limiting section of the first cam or the second cam, and/or ends while the cam follower is operatively connected to the base circle region of the first cam or the second cam.
As an alternative or in addition, the axial displacement of the cam carrier begins while the cam follower is operatively connected to the base circle region of the first cam or the second cam, and/or ends while the cam follower is operatively connected to the limiting section of the first cam or the second cam.
The above-described embodiments and features of the present disclosure can be combined in any desired way with one another.
Further details and advantages of the present disclosure will be described in the following text with reference to the appended drawings, in which:
The embodiments which are shown in the figures match one another at least partially, with the result that similar or identical parts are provided with the same reference signs, and reference is also made to the description of the other embodiments or figures in order to describe them, so as to avoid repetitions.
In the following text, a variable valve train with a sliding cam system is first of all described with reference to
The camshaft 12 is configured as an outlet camshaft which actuates the outlet valves 20 and 22. The camshaft 12 is part of a double camshaft system (not shown in detail) which additionally comprises an inlet camshaft (not shown) for actuating one or more inlet valves. The camshaft 12 is arranged together with the inlet camshaft as an overhead camshaft. The camshaft 12 and the inlet camshaft therefore form what is known as a DOHC system (Double Over Head Camshaft). As an alternative, the camshaft 12 might also form what is known as an SOHC system (Single Over Head Camshaft). In other embodiments, the camshaft 12 can also be arranged as an OHV camshaft.
The cam carrier 14 is arranged fixedly on the camshaft 12 so as to rotate with it. The cam carrier 14 is additionally arranged such that it can be displaced axially along a longitudinal axis of the camshaft 12. The cam carrier 14 can be displaced axially between a first stop 28 and a second stop 30.
In the following text, the cam carrier 14 is described with reference to
In addition, the cam carrier 14 has a first cam-free section 38 and a second cam-free section 40. The first cam-free section 38 is arranged at the second end of the cam carrier 14. The second cam-free section 40 is arranged between the second cam 34 and the third cam 36. In the first cam-free section 38, a first engagement track (switching guide plate) 42 extends spirally about a longitudinal axis of the cam carrier 14. In the second cam-free section 40, a second engagement track (switching guide plate) 44 extends spirally about the longitudinal axis of the cam carrier 14.
In order to displace the cam carrier 14 between the stops 28 and 30, the actuators 24 and 26 (
The displacement is triggered by virtue of the fact that the extended pin of the respective actuator 24, 26 is stationary with regard to an axial direction of the camshaft 12. As a consequence, the displaceable cam carrier 14 is displaced in a longitudinal direction of the camshaft 12 on account of the spiral shape of the engagement tracks 42, 44 when the extended pin engages into the respective engagement track 42, 44. At the end of the displacement operation, the pin of the respective actuator 24, 26 is guided by the respective engagement track 42, 44 in an opposed manner with respect to the extension direction and is therefore retracted. The pin of the respective actuator 24, 26 passes out of engagement with the respective engagement track 42, 44.
The first transmission apparatus 16 and the second transmission apparatus 18 (
If the cam carrier 14 is situated in the first axial position (as shown in
In the first axial position of the cam carrier 14, the second transmission apparatus 18 is operatively connected between the third cam 36 and the second outlet valve 22 via a cam follower 18A. The second outlet valve 22 is actuated in accordance with a contour of the third cam 36. In the second axial position of the cam carrier 14, the second transmission apparatus 18 does not actuate the second outlet valve 22. In the second axial position of the cam carrier 14, the cam follower 18A of the second transmission apparatus 18 lies at the same axial position with regard to the camshaft 12 as the first cam-free section 38. The first cam-free section 38 does not have an elevation for actuating the second transmission apparatus 18. If the cam carrier 14 is in the second axial position, the second outlet valve 22 is not actuated.
The first cam-free section 38 therefore has two functions. Firstly, the first cam-free section 38 accommodates the first engagement track 42. Secondly, the first cam-free section 38 serves to ensure that no actuation of the second outlet valve 22 takes place in the second axial position of the cam carrier 14. This functional integration is favourable for reasons of installation space.
In the embodiment which is shown, the first transmission apparatus 16 and the second transmission apparatus 18 are configured in each case as a rocker arm. In other embodiments, the transmission apparatuses 16 and 18 can be configured as toggle levers or tappets. In some embodiments, the transmission apparatuses 16 and 18 can comprise, for example, rotatably mounted rollers as cam followers 16A, 18A.
A locking apparatus 46 is shown with reference to
The limiting section 32C of the first cam 32 and the limiting section 34E of the second cam 34 are of identical configuration. The limiting section 32C of the first cam 32 and the limiting section 34E of the second cam 34 are arranged at an identical circumferential position with regard to a longitudinal axis of the camshaft 12. The limiting sections 32C, 34E form a common flat ramp. In this way, the limiting sections 32C, 34E make it possible that an axial displacement of the cam carrier 14 takes place not only in the base circle region 32A, 34A, but rather additionally in the limiting section 32C, 34E.
A dotted curve A indicates a valve lift of the outlet valve 20 in accordance with a normal operation mode, as brought about by the first cam 32. The curve A therefore corresponds to a followed cam profile of the first cam 32. In the normal operation mode, the outlet valve 20 is opened by way of the valve lift region 32B during the outlet stroke (exhaust stroke) in order to expel exhaust gas. Otherwise, the outlet valve 20 remains closed on account of the base circle region 32A of the first cam 32.
A continuous curve B indicates a valve lift of the outlet valve 20 in accordance with an engine braking operation mode, as brought about by the second cam 34. The curve B therefore corresponds to a followed cam profile of the second cam 34. In the engine braking operation mode, the outlet valve 20 is opened slightly by way of the first valve lift region 34B towards the end of the compression stroke in the region of the top dead centre at approximately 60° crank angle to 100° crank angle before the top dead centre. This is shown in
In the engine braking operation mode, the outlet valve 20 can be held closed first of all by way of the second base circle region 34C after the bottom dead centre is reached at the end of the expansion stroke. Towards the end of the exhaust stroke (outlet stroke), the outlet valve 20 opens in the region of the top dead centre by way of the second valve lift region 34D. The opening takes place once again at approximately 60° crank angle to 100° crank angle before the top dead centre. This is shown in
As has been described in the above text, a double compression with a subsequent decompression occurs as a result of the use of the second cam 34 to control the outlet valve 20, with the result that an engine braking functionality is ensured.
As can be gathered, in particular, from
The dash-dotted curve C relates to a movement of the movable pin by one of the actuators 24 or 26 with regard to the cam carrier 14. The dashed curve D relates to a movement of the respective engagement track 42 or 44 and therefore of the cam carrier 14 along the longitudinal axis of the camshaft 12. The double dot-dashed curve E shows a course of a depth contour of the respective engagement track 42 or 44 (shown only in
First of all, the movable pin of the first actuator 24 is extended in the direction of the first engagement track 42 and in the process engages into the first engagement track 42. The engagement is made possible by way of the configured depth contour of the first engagement track 42 (see curve E). After the engagement, a reduction in the play between the pin of the first actuator 24 and the first engagement track 24 occurs as a result of a cross-sectional constriction of the first engagement track 42. The reduction of the play takes place in a region S (see
The axial displacement of the cam carrier 14 therefore also takes place outside the base circle regions 32A, 34A in the limiting section 32C of the first cam 32 and the limiting section 34E of the second cam 34. As a result, the time period for the axial displacement of the cam carrier 14 is increased. On account of the increased displacement region, the accelerations and therefore the mass forces can be reduced in the case of an identical switching rotational speed for the axial displacement of the cam carrier 14. This can be utilized firstly to increase the functional reliability and service life on account of lower forces and pressures. This can be utilized secondly to increase the maximum switching rotational speed of the system.
In the example which is shown, the additional displacement region V1 which is made possible by way of the limiting sections 32C, 34E of identical configuration extends over approximately 22° camshaft angle.
In order to make an axial displacement of the cam carrier 14 which is shown in the figures possible, it can be necessary to configure the cam-free section 38 which both serves as a zero cam and is provided with the second engagement track 42 with an additional axial tolerance region (clearance region). The adjacent cam 36 is correspondingly of narrower configuration. During the axial displacement within the limiting sections 32C, 34E from the second axial position to the first axial position, the cam follower 18A is then displaced axially within said additional tolerance region. A collision of the cam follower 18A with a cam run-out part of the third cam 36 is thus prevented.
Experts will recognize meanwhile that the sliding cam system which is described herein is not restricted to the application which is described herein. For example, as an alternative or in addition to the identical design of the run-off regions (run-out regions), an identical design of the run-on regions (run-in regions) of the cams can be provided in order to realize the limiting sections of identical configuration. It is also possible to use the principles which are described herein in the case of variable valve trains for inlet valves of an internal combustion engine. Thus, for example, a run-on region of a first cam for a normal operation mode can be of identical design to a run-on region of a second cam for a Miller operation mode, and can be positioned at the same circumferential position with regard to the longitudinal axis of the camshaft.
Furthermore, it is to be emphasized that the displacement apparatus which is disclosed herein (first actuator, second actuator, first engagement track, second engagement track) does not necessarily have to be used to extend the switching region for the axial displacement of the cam carrier. Rather, for example, a method for operating an internal combustion engine with any displacement apparatus for the cam carrier can comprise the displacement of the cam carrier while the cam follower is in contact with the limiting region or regions. In particular, an axial displacement can begin and/or end when the cam follower is in contact with a limiting region.
The present disclosure is not restricted to the above-described preferred exemplary embodiments. Rather, a multiplicity of variants and modifications are possible which likewise utilize the concept of the present disclosure and therefore fall within the scope of protection.
Number | Date | Country | Kind |
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102017116987.3 | Jul 2017 | DE | national |