KR101815762B1 - Method and device for connecting three injection valves to a power supply source by means of only two switching element groups - Google Patents

Abstract

The present invention relates to a method for connecting one energy supply source and three injection valves (CYL1, CYL2, CYL3) in a sequence set in advance using a single first and second switching element group (Bank1, Bank2) Wherein each switching element group Bank1 and Bank2 is connected to each of the three injection valves CYL1, CYL2 and CYL3 by respective switching elements SE1 to SE12, in which the first, The third injection valves CYL1, CYL2 and CYL3 are individually assigned and alternately arranged for a predetermined period and in the same sequence, for each injection valve in one working cycle and for each injection cycle, Is connected to the energy source through the group (Bank1) or the second switching element group (Bank2).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method and apparatus for connecting one energy source and three injection valves using only two groups of switching elements.

The present invention relates to a method and apparatus for connecting one energy source and three injection valves using only two switching element groups.

Automotive combustion engines typically have a plurality of cylinders, in which case even numbered cylinders such as 4, 6, 8 or 12 are the most common. These cylinders may be formed as a series engine, a V-engine or a flat engine, in which case these cylinders are arranged in a so-called cylinder bench. In other words, in the case of a V6 engine, three cylinders each are arranged in one bench, in which case the two cylinder benches are oriented in a V-shape with respect to each other. In a corresponding manner, the arrangement of the injection valves assigned to the individual cylinders and the arrangement of the corresponding benches are also mentioned, and the switching element connecting one energy source and the injection valves is also referred to as being oriented in the bench.

Since the injection valves assigned to the cylinders are largely driven and controlled in a continuous manner, according to German patent application DE 10 2008 040 860 A1, for example, one more 4-cylinder engine for two injection valves It is possible to provide a single switching element for coupling with a high potential, and yet still be able to freely exploit a 360 ° angle of spray for one working cycle of a 720 ° crankshaft angle.

One unique selection switch is provided for each injection valve in order to connect the respective injection valve to the low potential of the energy source so that it can be connected to the energy source as intended. More specifically, two switching element groups are provided for four injection valves.

However, the German patent application DE 10 2008 040 860 A1 also proposes that a separate group of switching elements is provided for each injection valve, so that each injection valve has a complete working cycle of 720 ° crankshaft angle While the crankshaft rotates two times, it can be connected to an energy source for pre-injection, main injection and post-injection.

In the case of a three-cylinder engine, one switching element group or a single switching element group may be provided in a similar manner, per injection angle, for all three injection valves. Thereby, no high cost is required, or only a 240 ° angle of incidence is possible.

In WO 2012/032076 A1, a drive control concept for three injection valves with only two switching element groups is known, in which case two injection valves are controlled by one first switching element group and by one The third injection valve may be connected to the energy source by one second switching element group or the two injection valves may be connected by the first or second switching element group and the third injection valve may be connected to the energy supply by the first half of the injection angle 1 switching element group and in the second half the switching element group can be connected to the energy source by a different switching element group.

An object of the present invention is to realize a variable injection concept.

The above problem is solved by the method according to claim 1 and the apparatus according to claim 4. Preferred embodiments are described in detail in the dependent claims.

Thereby, one group of switching elements is connected to each of the three injection valves by an individual switching element, and one group of switching elements is used to switch one energy source and three In the method for connecting the injection valves, the first, second and third injection valves are individually assigned and are operated by injection valves in one operation cycle for a preset period and in the same sequence, Are alternately connected to the energy source through the first switching element group or the second switching element group.

More specifically, first, the first injection valve is driven for a first time period preset with the energy source through the first switching element group, i.e. before or after the first predetermined period of time has elapsed, For a second period pre-established with the energy source through the second switching element group, i.e. before or after the second predetermined period of time has elapsed, a third injection valve is connected to the energy source During a third predetermined period of time, after which the first injection valve is set in advance with the energy source through the second switching element group for a fourth period, and then the second injection valve is energized through the first switching element group During the fifth period pre-set with the source and finally the third injection valve is energized through the second switching element group The circle is connected for a sixth period set in advance, in which case two working cycles may be repeated periodically.

The device according to the invention is formed with three output terminals to which are connected the terminals for the potential of the energy source and the injection valve and two switching element groups formed by the switching elements, The element group is connected to each of the three injection valves by an individual switching element.

In one embodiment of the device according to the invention, one switching element is formed with two MOSFETs connected in series.

In an improvement of the device according to the invention, the terminal for the high-potential of the energy supply is connected to the first terminal of each injection valve through a respective one switching element of the first switching element group, And a terminal for the low-potential is connected to the second terminal of each injection valve through a respective one of the switching elements of the second switching element group.

In a particularly preferred refinement of the method according to the invention, according to the injection strategy for driving control of the injection valve, one injection valve alternates with the energy source through the first and second switching element groups of each of the three injection valves The first switching element group is connected to the energy source through the first switching element group and then the second switching element group through the second switching element group, The sub-period may overlap the second sub-period of the injection valve previously associated with the energy source.

In more detail, in the above improvement example, the first injection valve is connected to the first switching element group through the first switching element group for the first predetermined first partial period and the second switching element group for the predetermined subsequent second partial period, Source, that is, before or after the pre-established second sub-period, for the third sub-period in which the second injection valve is pre-set, through the first switching element group and in the subsequent predetermined fourth sub-period Through the second switching element group, that is to say through the first switching element group for a fifth predetermined sub period in which the third injection valve is effected before or after the preset fourth sub-period is terminated, and During the subsequent predetermined sixth sub-period, the second switching element group It is connected to the energy source.

The device according to the invention, the method according to the invention and the improvement of these embodiments provide a high degree of flexibility because of the different drive control concepts for the injection valve, depending on the operating conditions and the requirements on the output of the combustion engine This can be realized.

The present invention will be described in detail below with reference to the drawings, in which the embodiments are shown. In the drawing:
1 shows a drive control concept for a three-cylinder-engine with two switching element groups;
Fig. 2 shows an apparatus for realizing such a drive control concept; Fig. And
3 shows a drive control concept for a 4-cylinder-engine which can be implemented by a simple extension of the device according to the invention;

Figure 1 shows in a schematic manner the drive control concept for a 3-cylinder-engine (3-CYL). The first, second and third injection valves CYL1, CYL2, CYL3 must be connected to an energy source (not shown) through only two switching element groups (Bank1, Bank2).

In the right part of FIG. 1, two working cycles of a crankshaft angle of 720 ° are shown, each of which is subdivided into complete rotations of a 360 ° crankshaft on its side. The three magnetic valves CYL1, CYL2 and CYL3 and the magnetic coils installed in these injection valves and for actuating the tappet of the injection valve during the same spray angle of 280 ° are connected to the first switching element group Bank1 or 2 switching element group (Bank2). As can be seen in Figure 1, the spray angles are superimposed because in non-overlapping operation only a maximum spray angle of 240 [deg.] Per work cycle will be possible.

In the following, in the case of being referred to as the " injection period ", this injection period does not mean that the injection process is continuously performed during this preset period, but rather, during this injection period, The fact that one injection process is possible, that is, the fact that a particular group of switching elements (Bank1 or Bank2) can be used to connect to the energy source, must be expressed.

More specifically, in the example shown in FIG. 1, the connection of the energy source and the first injection valve (CYL1) must be possible at a crankshaft angle of -60 degrees, and this connection may be up to a crankshaft angle of 220 degrees It must last. For this purpose, the first switching element group (Bank1) must first be available. Since it is related to the crankshaft angle, it is necessary to be able to connect the energy supply source and the second injection valve CYL2 in advance before the end of this period depending on the number of rotations. For this purpose in the illustrated example, Bank2) may be used. The third injection valve CYL3 must be able to be connected to the energy source again before the predetermined time period for the connection of the energy supply source and the second injection valve CYL2 is ended and for this purpose, The element group Bank1 may be used because the period provided for the connection of the energy supply source and the first injection valve CYL1 has expired. If the first injection valve CYL1 has to be able to be connected again with the energy supply in the next working cycle, then the second switching element group Bank2 can be used, followed by the connection of the second injection valve CYL2 The first switching element group (Bank1) may be used and continue in this manner.

More specifically, in the scheme according to the present invention, the first or second switching element group (Bank1, Bank2) can be alternately used for the injection valves CYL1 to CYL3 to be operated continuously, Each injection valve per cycle is connected to an energy source by another switching element group (Bank1, Bank2).

However, in the improvement of the present invention, similarly, the first switching element group (Bank1) is always used in the first half of the injection angle usable for one injection valve, and the second switching element group Bank2) can be used. As a result, the overlapping operation is also possible by this possibility. Depending on the manner of operation of the combustion engine, one drive control concept or another drive control concept may be preferred, in the manner according to the invention, either dynamically or statically selected between the two concepts, Depending on the condition or depending on the desired operating characteristic, the corresponding injection concept can be selected.

2, there is shown an apparatus such as may be used to implement the method according to the present invention. In this figure, two switching element groups (Bank1 and Bank2) are shown in a schematic manner, in this case in the illustration of the first switching element group (Bank1) for the sake of simplicity only the supply voltage of the energy supply And the output terminals V1 and V2 of the switching converter must be used as the terminals of the energy supply source. Three output terminal pairs A11, A12, A21, A22, A31 and A33 are shown, and these output terminals are connected to injection valves P1, P2, P3, which are actuated by injection valves, ) Are connected.

A total of six switching elements SE1 to SE6 are used to couple the terminals of the injection valves P1, P2 and P3 to the potentials V1 and V2, The high-potential of the energy source at the terminal V1 may be connected to the respective first terminal of the injection valves P1 to P3. On the other hand, the terminals for the low-potential of the energy source V2 may be correspondingly connected to the respective second terminals of the injection valves P1 to P3 via one switching element S4 to S6, respectively .

In the system according to the present invention, since the first switching element group (Bank1) is constituted in the same manner, the injection valves P1 to P3 are arranged in the same manner as the first switching element group (Bank2) A second group of switching elements (Bank2) with corresponding switching elements (SE7 to SE12) are provided, which can be connected to the first switching element (s) so that the method according to the invention can be carried out as described in connection with figure 1 have. In other words, the injection valves P1 to P3 can be driven and controlled in a superimposed manner by only two switching element groups (Bank1, Bank2).

In Fig. 2, a simple expansion of the device according to the invention with two switching element groups (Bank1, Bank2) makes it possible to drive-control a 4-cylinder-engine to which the drive control concept shown in Fig. The fourth injection valve P4, which must show the fact, is indicated by a broken line. In this figure, it can be seen that the overlapping operation of the injection valves CYL1 to CYL4 is possible by alternately using the first and second switching element groups (Bank1, Bank2) in a manner similar to that of the three-cylinder engine. Such a superposition operation can be done in a simple manner without a large expense.

Claims (6)

A method for connecting one energy supply source and three injection valves (CYL1, CYL2, CYL3) in a predetermined sequence using a single first and second switching element group (Bank1, Bank2) The element groups Bank1 and Bank2 are respectively connected to the three injection valves CYL1, CYL2 and CYL3 by the individual switching elements SE1 to SE12, and the first, second and third injection valves CYL1, CYL2, (CYL3) are individually assigned and are assigned to the first switching element group (Bank1) or the second switching element group (Bank1) for the predetermined period and in the same sequence, for each injection valve in one operation cycle and for each injection cycle A method for connecting an energy supply source and three injection valves, the method comprising: The method according to claim 1, wherein one injection valve (CYL1, CYL2, CYL3) is connected to each of the three injection valves (CYL1, CYL2, CYL3) according to a injection strategy for driving control of the injection valves (Bank1, Bank2) of the first switching element group (Bank1, Bank2), for the first partial period, through the first switching element group (Bank1) and then for the second period The first sub-period of the injection valve, which is connected to the energy source through the second switching element group (Bank2), is connected to one energy source, which can be overlapped with the second sub-period of the injection valve, And three injection valves. 3. The method according to claim 2, wherein the switching between the two drive control methods is made dynamically or statically. delete delete delete

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