Charge air line of an internal combustion engine and internal combustion engine

Abstract

A charge air line of an internal combustion engine for supplying multiple cylinders of a cylinder bank of the internal combustion engine arranged in-line with charge air, has multiple charge air line sections. Emanating from each charge air line section a branch leads to a cylinder, the branch screwable to a cylinder head of the respective cylinder. The charge air line has an upstream end, via which charge air is feedable to the charge air line, and a downstream end, which is closed by an end cap. At the downstream end, the charge air line has a larger flow cross section than at the downstream end.

Claims

1. A charge air line (1) of an internal combustion engine for supplying a plurality of cylinders (2) of a cylinder bank (3) of the internal combustion engine arranged in-line with charge air, the charge air line (1) comprising: a plurality of charge air line sections (6), each of the plurality of charge air line sections (6) having, emanating therefrom, a branch (7) that leads to a respective one of the plurality of cylinders (2), the branch (7) being screwable to a cylinder head (4) of the respective one cylinder (2); an upstream end (9), via which charge air is feedable to the charge air line (1); and a downstream end (10) of the charge air line (1), which is closed by an end cap (11), wherein the charge air line (1) at the upstream end (9) has a larger flow cross section than at the downstream end (10), so as to provide a flow cross section decrease, and wherein each of the plurality of air line sections (6) is a segment of the charge air line (1) connected to an adjacent air line section by a connector (12), and the decrease in flow cross section occurs in a single charge air line section.

2. The charge air line according to claim 1, wherein the plurality of charge air line sections are N in number and are configured to supply N cylinders (2) of the cylinder bank (3) with the charge air, the charge air line (1) in a region of the upstream end (9), and emanating, as seen from the upstream end (9), in a region of 1-st to J-th charge air line sections (6), has a first flow cross section, wherein J<N, and the charge air line (1) emanating, as seen from the upstream end (9) at least in the region of the N-th charge air line section (6) and in a region of the downstream end (10) has a second flow cross section that is smaller than the first flow cross section.

3. The charge air line according to claim 2, wherein the flow cross section of the charge air line (1) decreases, in the region of the J-th charge air line section (6), from the first flow cross section to the second flow cross section.

4. The charge air line according to claim 2, wherein J=N−2.

5. The charge air line according to claim 1, wherein the plurality of charge air line sections are N in number and are configured to supply N cylinders (2) of the cylinder bank (3) with the charge air, the charge air line (1) in a region of the upstream end (9), and emanating, as seen from the upstream end (9), in a region of 1-st to N−1th charge air line sections (6), has a first flow cross section, and the charge air line (1) emanating, as seen from the upstream end (9) at least in the region of the N-th charge air line section (6) and in a region of the downstream end (10) has a second flow cross section that is smaller than the first flow cross section.

6. The charge air line according to claim 5, wherein the flow cross section in the region of the N−1-th charge air line section (6) decreases from the first flow cross section to the second flow cross section.

7. The charge air line according to claim 6, wherein the flow cross section continuously decreases from the first flow cross section to the second flow cross section.

8. The charge air line according to claim 7, wherein the flow cross section decreases funnel-like or conically from the first flow cross section to the second flow cross section.

9. The charge air line according to claim 8, wherein for the ratio V=A2/A1 between the second flow cross section A2 and the first flow cross section A1 0.3≤V≤0.7 applies, or 0.4≤V≤0.5 applies, or V=0.5 applies.

10. An internal combustion engine comprises: at least one cylinder bank (3), wherein each cylinder bank (3) comprises multiple cylinders (2) arranged in-line, at least one charge air line (1) configured to supply the cylinders (2) of the respective cylinder bank (3) with charge air, wherein the respective charge air line (1) is configured according to claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Preferred further developments of the invention are obtained from the following description. Exemplary embodiments of the invention are explained in more detail by way of the drawings without being restricted to this. In the drawings:

(2) FIG. 1 is an extract from an internal combustion engine in the region of a cylinder bank and a charge air line; and

(3) FIG. 2 is the charge air line in sole representation.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS

(4) FIG. 1 shows an extract from an internal combustion engine according to an aspect of the invention in the region of a charge air line 1 according to the invention, which extends along multiple cylinders 2 of a cylinder bank 3 arranged in-line.

(5) In the exemplary embodiment shown in FIG. 1, the cylinder bank 3 comprises six cylinders 2 arranged in-line. By way of the charge air line 1, all cylinders 2 of the cylinder bank 3 can be supplied with charge air. FIG. 2 shows the charge air line 1 in sole representation in a position rotated relative to FIG. 1.

(6) In FIG. 1, two cylinder heads 4 of the two outermost cylinders 2 are shown. Of the cylinders 2 arranged in between the cylinder heads are not shown in FIG. 1, so that in FIG. 1, for these cylinders, a view of exhaust lines 5 is cleared, via which exhaust gas, incurred during the combustion of the fuel in the cylinders 2, can be discharged from the cylinders 2.

(7) As already explained, the charge air line 1 supplies the cylinders 2 with charge air, wherein the charge air line 1 comprises multiple charge air line sections 6. From each charge air line section 6, a branch 7 leads to the respective cylinder 2 in order to supply the respective cylinder 2 with charge air line. The respective branch 7 branches perpendicularly or approximately perpendicularly off the respective charge air line section 6.

(8) The respective branch 7 is screwable or screwed to the cylinder head 4 of the respective cylinder 2 via a flange connection, wherein in particular FIG. 2 shows the flanges 8 formed on the branches 7, via which the charge air line 1 or the branch 7 of the respective charge air line section 6 can then be screwed to the respective cylinder head 4 of the respective cylinder 2.

(9) The charge air line 1 composed of the multiple charge air line sections 6 comprises an upstream end 9, via which the charge air line 1 can be supplied with charge air.

(10) Emanating from the upstream end 9, charge air can thus be fed to the charge air line 1. Emanating from this upstream end 9 of the charge air line 1, the charge air flows in the direction of a downstream end 10 of the charge air line 1, wherein this downstream end 10 of the charge air line 1 is closed by an end cap 11.

(11) The individual charge air line sections 6 are provided by corresponding segments, which are connected to one another via the connecting devices 12. By way of this it is possible to adapt the length or the number of the charge air line sections 6 to the number of the cylinders 2 of the internal combustion engine.

(12) In the illustrated exemplary embodiment, the cylinder bank 3 comprises a number N=6 of cylinders 2. Accordingly, the air line 1 in this case comprises a number N=6 charge air line sections 6. Emanating from each charge air line section 6, a branch 7 branches off in the direction of the cylinder head 4 of the respective cylinder 2, to thus supply each cylinder 2 with charge air.

(13) The number N=6 of the cylinders 2 and of the charge air line sections 6 is purely exemplary in nature. The number N can also be greater than six or smaller than six. Accordingly, N can be, for example, ten or seven or five.

(14) At the upstream end 9 of the charge air line 1, the charge air line 1 has a larger flow cross section than at the downstream end 10. Because of this, a transverse force, which in the region of the last charge air line segment 6 seen in the flow direction of the charge air is generated by the closing of the charge air line 1 via the end cap 11, can be reduced. Because of this, screw connections, via which the flanges 8 of the branches 7 of the charge air line segments 6 are screwed to the cylinder heads 4 of the cylinders 2 can be dimensioned smaller and lighter.

(15) The charge air line 1, in the region of the upstream end 9 and emanating, seen from the upstream end 9, in the region of the 1-st to J-th charge air line section 6 has a first flow cross section. J is smaller than N. The charge air line 1 emanating, seen from the upstream end 9, at least in the region of the N-th charge air line section 6 and of the upstream end 10 and thus in the region of the end cap 11 has a second flow cross section which is smaller than the first flow cross section.

(16) In the shown exemplary embodiment, J=N−1. From this it follows that in the shown exemplary embodiment the charge air line 1 in the region of the downstream end 9 and emanating, seen from the upstream end 9, in the region of the 1-st to N−1-th charge air line section the first flow cross section and that the charge air line in the region of the N-th charge air line section and of the downstream end 10 as well as end cap 11 has the second flow cross section which is smaller than the first flow cross section. Here it is evident from FIGS. 1 and 2 that in the region of the J-th charge air line section 6, i.e., in the illustrated exemplary embodiment in the region of the N−1-th charge air line section 6, the flow cross section decreases from the first flow cross section to the second flow cross section, namely directly adjoining the branch 7, namely directly upstream of the branch 7 of the J-th charge air line section 6. The J-th charge air line section 6, namely in the illustrated exemplary embodiment the N−1-th charge air line section 6 accordingly has a part section 13, in which the flow cross section decreases from the first flow cross section to the second flow cross section, namely preferentially continuously, in particular in the manner of a funnel or conically.

(17) In the exemplary embodiment of FIGS. 1 and 2, the transverse force is thus not exclusively incurred in the region of the, as seen in flow direction, last charge air line section 6 but rather in the region of the last and penultimate charge air line section 6.

(18) By suitably dimensioning a ratio V=A2/A1 between the second flow cross section A2 and the first flow cross section A1, that transverse force incurred with charge air lines known from practice exclusively in the region of the last charge air line section 6, can be distributed in a defined manner to multiple charge air line sections 6 in the illustrated exemplary embodiment 2, namely over the last and penultimate charge air line section 6. In particular when V=0.5, approximately identically sized transverse forces are incurred in the region of these charge air line sections 6. It is also possible to select a different ratio for V. Accordingly, 0.3≤V≤0.7 applies: preferably 0.4≤V≤0.5 applies.

(19) Although in the illustrated exemplary embodiment the change of the flow cross section, emanating from the first flow cross section to the second flow cross section, occurs in the region of the penultimate (N−1-th) charge air line section 6 it is also possible to make this change of the flow cross section on another charge air line segment 6, for example on the third or N−2-th charge air line segment 6.

(20) In the illustrated preferred exemplary embodiment, the decrease of the diameter from the first upstream flow cross section to the second downstream flow cross section occurs in the region of a single charge air line segment 6. It is also possible to make this change of the flow cross section stepped in two or three charge air line segments 6. Accordingly, a first decrease of the flow cross section can be performed, for example, in the region of the third from last charge air line section 6 and a second reduction of the flow cross section in the region of the penultimate charge air line section 6. In this case, a reduction of the flow cross section emanating from the first flow cross section to a third flow cross section then takes place in the region of the third from last charge air line section 6 and a reduction of the flow cross section emanating from the third flow cross section to the second flow cross section in the region of the penultimate charge air line section 6, so that the transverse force is then distributed over three charge air line sections 6.

(21) The version of FIGS. 1 and 2, in which the decrease of the flow cross section takes place in the region of a single charge air line section 6 emanating from the first flow cross section to the second flow cross section however is preferred in order to employ as many same parts as possible.

(22) With the invention it is possible to distribute a transverse force, which with charge air lines 1 known from practice exclusively acts on the last charge air line section 6, over multiple charge air line sections 6, in particular over two charge air line sections 6, namely over the last and the penultimate charge air line section 6, emanating seen from the upstream end 9 of the charge air line 1. In particular when the second flow cross section corresponds to half of the first flow cross section, the transverse force is then equally distributed over these two charge air line sections 6. By way of this it is ultimately possible to dimension a screw connection between the flange 8 of the respective branch 7 of the respective charge air line section 6 and the respective cylinder head 4 of the respective cylinder 2 smaller and lighter since lower transverse forces have to be absorbed and thus the corresponding screw connections can be dimensioned smaller and lighter.

(23) Thus, while there have been shown and described and pointed out fundamental novel features of the invention as applied to a preferred embodiment thereof, it will be understood that various omissions and substitutions and changes in the form and details of the devices illustrated, and in their operation, may be made by those skilled in the art without departing from the spirit of the invention. For example, it is expressly intended that all combinations of those elements and/or method steps which perform substantially the same function in substantially the same way to achieve the same results are within the scope of the invention. Moreover, it should be recognized that structures and/or elements and/or method steps shown and/or described in connection with any disclosed form or embodiment of the invention may be incorporated in any other disclosed or described or suggested form or embodiment as a general matter of design choice. It is the intention, therefore, to be limited only as indicated by the scope of the claims appended hereto.

LIST OF REFERENCE NUMBERS

(24) 1 Charge air line 2 Cylinder 3 Cylinder bank 4 Cylinder head 5 Exhaust line 6 Charge air line section 7 Branch 8 Flange 9 Upstream end 10 Downstream end 11 End cap 12 Connecting device 13 Intermediate section