AT502872A2 - PROCESS FOR LOWERING REFRIGERATING IN PART LOAD OPERATION IN A FUEL POWER MACHINE - Google Patents

Description

       

  The invention relates to a method for reducing the friction in part-load operation in an internal combustion engine having at least two cylinder groups, wherein the intake and Auslassteuerzeiten can be changed independently and the exhaust strands are performed separately with the associated exhaust aftertreatment groups cylinder groups.
Overflow, throttling and friction losses are exploited for the engine braking effect of an internal combustion engine in overrun operation. However, there are operating conditions in which a lower engine braking effect or a reduction of the friction power in part-load operation is desired.

   Furthermore, it may be desirable to shut down individual cylinders during part-load operation to reduce fuel consumption and emissions.
EP 0 915 234 A2 discloses a camshaft drive for an internal combustion engine and a method for reducing the pumping losses and for reducing the fuel consumption of internal combustion engines in coasting mode. It is provided that in a predefined engine operating range, the exhaust camshaft and the intake camshaft are retarded. The rotation of the intake camshaft results in the sum of the rotational movements resulting from a first and a second phase shifter.
EP 1 013 899 A2 discloses an internal combustion engine with two cylinder groups and in each case two camshafts, which are interconnected by a coupling drive.

   The two camshafts of a cylinder group each have their own phase shifter, so that the exhaust camshaft are rotatable by a first phase shifter and the intake camshaft by a second phase shifter so that the phase adjustment of the intake camshaft results as the sum of the actuating movements of the two phase shifter.
From DE 31 32 907 AI it is known to perform the shutdown of individual cylinders of an internal combustion engine by suppressing the injections in cyclic order.
The object of the invention is to achieve the simplest possible way a significant reduction in fuel consumption and emissions.
According to the invention, this is realized in that, in the partial load operation, the cylinders of at least one first cylinder group, preferably a first cylinder row,

   deactivated by switching off the injection and friction minimum operation and that the cylinders of at least one second cylinder group, preferably a second row of cylinders, are operated with optimal motor efficiency.
Partial load operation, the cylinders of at least one first cylinder group are deactivated by switching off the injection and operated friction minimum and that the cylinders of at least one second cylinder group are operated in an optimal motorized manner.
Preferably, after a defined operating time the deactivation and the engine operation between first and second cylinder group is changed,

   wherein the cylinders of the first group of cylinders are operated with optimum engine efficiency and the cylinders of the second cylinder group are deactivated by switching off the injection and operated in an optimally friction-stable manner.
In order to avoid that the catalysts of the deactivated cylinder group cool down too much, it is provided that the first and the second cylinder group are alternately deactivated or operated with optimum engine efficiency.

   Thus, between the two cylinder groups is changed, alternately the first cylinder group and the second cylinder group are turned off alternately.
It is preferably provided that the friction-minimum or efficiency-optimized operation takes place by adjusting the intake and / or Auslassteuerzeiten, it being particularly advantageous if at least one exhaust camshaft and at least one intake camshaft of a cylinder group are retarded to lower the friction power, preferably the Adjustment of the intake camshaft is greater than the adjustment of the exhaust camshaft. Switching is torque-neutral. First, the deactivated cylinder group is brought to efficiency-optimal control time. Thereafter, the fuel injection is switched from one to the other cylinder group.

   Finally, the newly deactivated cylinder group is brought to friction-optimum control time.
The adjustment ranges for the exhaust camshaft are about 40 [deg.] To 60 [deg.], For the intake camshaft about 40 [deg.] To 120 [deg.].
It is particularly advantageous if the exhaust opening takes place at the latest at 210 [deg.] Crank angle, preferably at the latest at 200 [deg.] Crank angle after the top dead center of the combustion. The inlet closure should be at least 610 ° C, preferably at least 630 ° C. The intake deadline of conventional internal combustion engines, by comparison, is between 540 ° and 610 °. All timing refers to 1 mm valve lift.

   It is particularly advantageous if the adjustment range of the intake camshaft results from the addition of the adjustment ranges of a first and a second phase shifter. In this case, a coupling drive can be provided, through which add the adjustment paths and the adjustment speeds of the two phase shifter.
Even after phasing the camshafts, there should be minimal valve overlap.

   Preferably, it is provided that in the overlap region, the stroke of the intersecting valves is at least 0.1 mm, preferably at least 0.3 mm.
This makes it possible to lower the compression in partial load operation with late position of both phase shifter, to minimize the filling and thereby reduce the friction loss.
In a further embodiment of the invention can be provided that the gas flow of the deactivated cylinder group is passed past the catalyst of this cylinder group. By this measure, a cooling of the catalysts of the deactivated cylinder group can be avoided.
Alternatively or additionally, it may further be provided that the supplied air mass of each cylinder group is controlled individually by at least one separate throttle element, wherein the air mass flow of the deactivated cylinder group is reduced.

   Characterized in that each cylinder group is assigned a throttle body, the air mass for each cylinder group can be controlled individually, thereby reducing the air mass flow flowing through the deactivated catalysts.
The invention will be explained in more detail below with reference to FIGS.
2 shows an internal combustion engine in a second embodiment, and FIG. 3 shows an internal combustion engine in a third embodiment, FIG. 4 shows valve lift curves for maximum efficiency, FIG. 5 shows valve lift curves 6 shows an operating parameter time diagram for the method according to the invention, FIG. 7 shows schematically a possible camshaft arrangement for carrying out the method, FIG.

   8 shows an internal combustion engine in a fourth embodiment and FIG. 9 shows an internal combustion engine in a fifth embodiment.
Functionally identical parts are provided in the embodiment variants with the same reference numerals. 1 to 3 show schematically an internal combustion engine 10 with two, for example, V-shaped cylinder rows, each cylinder row forms a cylinder group 11, 12. The internal combustion engine has an intake system 13 and an exhaust system 14. Each cylinder group 11, 12 is associated with an exhaust line 15, 16, wherein in each exhaust line 15, 16 exhaust aftertreatment devices 17, 18; 19, 20, for example, catalysts are arranged.
8 and 9 show internal combustion engines 10, which are designed as a series engine.

   The cylinders Z of the single cylinder bank are subdivided into cylinder groups 12, wherein each cylinder group 11, 12 is assigned its own exhaust gas line. For example, in a 4-cylinder inline engine, the cylinders 1 and 4 on the one hand and the cylinders 2 and 3 on the other hand each with its own exhaust aftertreatment device 17, 18; 19, 20 equipped.
By suspending the injection, the cylinders Z can be shut off in rows. It is provided that in each case one cylinder group deactivated and the other cylinder group is operated with optimum efficiency. The control times of the deactivated cylinder group are set so that minimal friction losses occur.

   Prerequisite for this is that the timing of the two cylinder groups 11, 12 can be adjusted independently.
To cool the exhaust aftertreatment devices 17, 18; To avoid 19, 20, the activation and deactivation of the cylinder Z cyclically between the cylinder groups 11, 12 is changed, whereby the timing of the intake and exhaust valves cylinder group is changed between efficiency optimal and friction minimum power setting.
In order to cool the exhaust aftertreatment devices 17, 18; 19, 20 to avoid or reduce, in the embodiments shown in FIG. 2 and FIG. 9 further for each exhaust line 15, 16, a bypass line 21, 22 for the exhaust aftertreatment devices 17, 18; 19, 20 are provided, wherein in each bypass line 21, 22, a switching member 23, 24 is arranged.

   Each of the deactivated cylinder group 11; 12 coming relatively cool gases (only air, no exhaust gas components) are at the exhaust aftertreatment devices 17, 18; 19, 20 passed by.
In the embodiment variants illustrated in FIGS. 1 and 2, the intake system 13 has a common intake manifold 25 and a common throttle valve 26 for both cylinder groups 11, 12. By contrast, in the case of the intake systems 13 illustrated in FIGS. 3 and 9, a separate intake manifold 25a, 25b is provided per cylinder group 11, 12, with each intake manifold 25a, 25b having its own throttle valve 26a, 26b.

   This makes it possible to reduce the intake air of the respective deactivated cylinder group 11, 12, so that the exhaust aftertreatment devices 17, 18; 19, 20 of the respective deactivated cylinder group 11; 12 supplied a smaller amount of cool gas and thus too rapid cooling of the exhaust aftertreatment devices 17, 18; 19, 20 is prevented.
The control time adjustment between optimum efficiency operation and friction power minimum operation is effected by phase shifting of the intake and exhaust control time. Fig. 4 shows the lift curves E, A of the intake and exhaust valves for efficiency-optimal operation, Fig. 5 contrast, the lift curves E, A of the intake and exhaust valves for loss-minimal operation, each applied over the crank angle [alpha].
Fig. 7 shows a valve actuating device 1 for carrying out the control timing adjustment.

   The valve operating device 1 has an exhaust camshaft 2 and an intake camshaft 3. The exhaust camshaft 2 is driven by a traction means 7 by a crankshaft, not shown. About exhaust cam 2a not shown exhaust valves and inlet cam 3a not shown inlet valves are actuated. The two camshafts 2, 3 are connected to one another via a coupling drive 4, for example a spur gear or a traction mechanism. The exhaust camshaft 2 can be rotated via a first phaser 5. In the embodiment, between the coupling drive 4 and the intake camshaft 3, a second phase adjuster 6 is arranged, via which the Eilnassnockenwelle 3 can be rotated relative to the exhaust camshaft 2.

   But it is also possible to arrange the second phase adjuster 6 between the exhaust camshaft 2 and the coupling drive 4, as indicated in FIG. 6 by dashed lines. The adjustment of the intake camshaft 3 is composed of the sum of the rotational movements due to the first phase adjuster 5 and the second phaser 6, wherein not only the adjustment paths, but also the Verstellgeschwindigkeiten the two phase shifters 5, 6 for the intake camshaft 3 add. As a result, the adjustment range of the exhaust valves is between 40 [deg.] To 60 [deg.] And the adjustment range of the intake valves between 40 [deg.] And 120 [deg.]. The inlet closing is preferably after 610 [deg.] Crank angle [alpha] after the top dead center of the ignition. The start of the exhaust opening, based on 1 mm stroke, is a maximum of 210 ° crank angle.

   Even after the adjustment there should be a minimum overlap of the inlet and outlet valves. By retarding the exhaust control times and the intake control times to the specified extent, the compression can be reduced for the deactivated cylinder group 11, 12 in partial load operation, the filling can be minimized and the frictional loss can be reduced.

   By the illustrated coupling drive 4 and the described arrangement of the phaser 5, 6 is achieved that when adjusting the timing of optimal efficiency in the friction minimum operation, the adjustment of the intake camshaft is greater than the adjustment of the exhaust camshaft, as shown in FIGS. 4 and 5 can be seen ,
In Fig. 6, the adjustment angles ssn, 5, ssu, 6; ss [iota] 2/5, ss [iota] 2/6 for the phase shifters 5, 6 of the first cylinder group 11 and the second cylinder group 12, and the injection quantities in, i [iota] 2 for the cylinders Z of the first cylinder group 11 and for the Cylinder Z of the second cylinder group 12 shown over the time t.

   From the diagram, a switching sequence between the two cylinder groups 11, 12 can be seen, wherein up to the time Ti, the first cylinder group 11 is deactivated with low-friction control timing and only the second cylinder group 12 is operated by a motor. The injection quantity of the second cylinder group 12 corresponds to twice the average value of both cylinder groups for the respective load point, plus an additional amount for overcoming the frictional loss of the deactivated cylinder group 11. The switching between the cylinder groups 11, 12 takes place torque neutral, at the time Ti, the deactivated cylinder group 11th First, by adjusting the phaser are brought to optimal efficiency control times, as indicated by the curves ssn, 5ssn, 6 in Fig. 6.

   Thereafter, at time T ", the injection is switched from the second cylinder group 12 to the first cylinder group 11, and finally the newly deactivated cylinder group 12 is brought to the minimum friction duration, as indicated by the displacement angles ss [iota] 2.5ss [iota] 2/6. At time T2, the switching is completed. With the arrows fmins the settings of the phase shifters 5, 6 are for friction-minimum operation, with [eta] max the settings of the phase shifters 5, 6 are designated for efficiency-optimal operation.
The inventive method can be particularly advantageous in internal combustion engines with four gas exchange valves per cylinder realize.


    

Claims (14)

PATE CLAIMS E 1. A method for reducing the friction power in partial load operation in an internal combustion engine having at least two cylinder groups, wherein the inlet and Auslasssteuerzeiten can be changed independently and the exhaust strands (15, 16) with the associated exhaust aftertreatment devices (17, 18, 19, 20) separated cylinder groups characterized in that in the partial load operation, the cylinders (Z) of at least one first cylinder group (11), preferably a first cylinder row, deactivated by switching off the injection and friction minimum operation and that the cylinder (Z) at least one second cylinder group (12), preferably a second row of cylinders, motor efficiency operated optimal efficiency. 2. The method according to claim 1, characterized in that after a defined operating time, the deactivation and the engine operation between the first and second cylinder group (11; 12) is changed, wherein the cylinder (Z) of the first cylinder group (11) are operated with optimal efficiency motor and the cylinders (Z) of the second cylinder group (12) are deactivated by switching off the injection and operating friction-optimized. 3. The method according to claim 1 or 2, characterized in that the first and the second cylinder group (11; 12) are alternately deactivated, or powered optimal motor efficiency. 4. The method according to any one of claims 1 to 3, characterized in that the friction minimum or efficiency optimal operation by adjusting the intake and / or Auslassteuerzeiten takes place. 5. The method according to claim 4, characterized in that for lowering the friction power at least one exhaust camshaft (2) and at least one intake camshaft (3) of a cylinder group (11; 12) are retarded, wherein preferably the adjustment of the intake camshaft (3) larger is, as the adjustment of the exhaust camshaft (2). A method according to claim 4 or 5, characterized in that the exhaust camshaft (2) is retarded by 40 [deg.] To 60 [deg.]. 7. The method according to claim 5 or 6, characterized in that the intake camshaft (3) is adjusted by 40 [deg.] To 100 [deg.]. 8. The method according to any one of claims 5 to 7, characterized in that the exhaust opening at the latest at 210 ° crank angle (α), preferably at the latest at 200 ° crank angle (α) after top dead center Combustion - based on 1 mm valve lift - takes place. 9. The method according to any one of claims 5 to 8, characterized in that the inlet closing later than 610 [deg.] Crank angle ([alpha]), preferably later than 630 [deg.] Crank angle ([alpha]) after the top dead center of Combustion - based on 1 mm valve lift - takes place. 10. The method according to any one of claims 5 to 9, characterized in that the overlap between exhaust and intake stroke (A, E) is greater than 0 [deg.] Crank angle ([alpha]). 11. The method according to any one of claims 5 to 10, characterized in that in the overlap region, the stroke of the intersecting valves is at least 0.1 mm, preferably at least 0.3 mm. 12. The method according to any one of claims 1 to 11, wherein each cylinder group is assigned at least one catalyst, characterized in that the gas flow of the deactivated cylinder group (11, 12) on at least one exhaust aftertreatment device (17, 18, 19, 20) of this cylinder group bypasses becomes. 13. The method according to any one of claims 1 to 12, characterized in that the supplied air mass of each cylinder group (11; 12) is individually controlled by at least one separate throttle member (26a, 26b), wherein the air mass flow of the deactivated cylinder group (11; 12) is reduced. 14. The method according to any one of claims 1 to 13, characterized in that the switching between the first and second cylinder group (11, 12) is torque-neutral, wherein the phaser of the deactivated cylinder group (11, 12) is set to optimal efficiency control times, then the injection is switched from the previously active to the previously deactivated cylinder group (11, 12) and finally the phaser of the now disabled cylinder group (11, 12) is set to minimum friction control time.