EP0251159A2 - Return line for leak gas from a crank case - Google Patents

Abstract

1. A return conduit for leakage gases from the crankcase of a four-stroke internal-combustion engine into the suction pipes of the cylinders, characterised in that the return conduit (6) is in communication with each suction pipe (3) of a cylinder through an opening (8), wherein the diameters of the openings (8) change, seen in the direction of flow of the leakage gases in the return conduit (6), and the last opening has a substantially larger diameter than the first opening and its direction of exit into the suction pipe is different from that of the first opening.

Description

The invention relates to a return line for leak gases from the crankcase of a four-stroke internal combustion engine into the intake pipes of the cylinders.

In the four-stroke process of an internal combustion engine, gases pass the pistons and into the crankcase during the compression and combustion cycles. The reason is that the piston rings can never create a 100% seal between the cylinder and crankcase. So-called leakage gases enter the crankcase, which partly consist of an unburned air-fuel mixture and partly of the combustion gases. While the crankcase was previously vented to the environment, it is now necessary to recycle the leakage gases for environmental reasons. With four-stroke petrol engines, the return is usually behind the air filter in the intake pipe of the carburetor, with four-stroke diesel engines behind the air filter in front of the intake pipes of the cylinders.

The recirculation of the leakage gases has a positive side effect, especially with diesel engines. The leakage gases returned in front of the intake pipes tear oil droplets out of the Crankcase with. These finely divided, entrained oil droplets are sufficient to lubricate the valve seats of the intake valves and to protect them from wear. This is much more advantageous than if lubrication along the valve stems were caused by seeping oil. Because of the heat acting on the valve stem there is a risk that the oozing oil cokes on the valve stems and thus narrows the cross section of the intake pipe.

However, if the leakage gases are returned in an uncontrolled manner in front of the intake pipes of the cylinders via a single opening, there is a risk that the cylinder which is closest to the opening of the return line will suck in most of the leakage gases and that the most distant cylinder will no longer be able to suck in leakage gases . This naturally leads to an uneven distribution of the oil mist to the individual cylinders, so that the inlet valves of the cylinders that draw in most of the oil mist are clogged with oil carbon, while in the case of valves of the cylinders that no longer suck in leakage gases, valve damage due to lack of lubrication due to valve seat wear occur.

In order to avoid the disadvantages of this uncontrolled leakage gas recirculation, the invention has set itself the task of distributing the leakage gases evenly over each cylinder that sufficient lubrication of the valve seats of all intake valves is ensured.

The object is achieved with the aid of the characterizing features of claim 1.

The return line is advantageously connected to each intake pipe of a cylinder via an opening. This ensures that each of the cylinders can suck in leakage gases and thus its inlet valves are adequately lubricated in the valve seats. The different diameters of the orifices in the return line, as seen in the direction of flow of the leak gases, change so that the last orifice has a much larger diameter and a different exit direction into the intake pipe than the first orifice, ensure that the same of each cylinder Amount of leakage gases can be sucked in. According to the flow laws, the area of an opening and the direction of its exit can be used to directly influence the amount of gas flowing through this opening per unit of time. The cylinder lying first in the flow direction of the return line sucks in the leakage gases from the smallest opening. The leakage gases still contain the highest proportion of oil mist in this part of the return line. The amount of leakage gases and their oil mist content decreases in the return line from intake pipe to intake pipe. In order to supply all cylinders with leakage gases evenly and thereby ensure lubrication of the valve seats of the inlet valves, the last opening in the return line, viewed in the direction of flow of the leakage gases, is considerably larger than the first.

In an embodiment of the invention, the openings are arranged in a spiral or almost spiral line around the return line, the first opening, viewed in the direction of flow of the return line, being drawn on the side facing away from the suction opening of the suction pipe and the last on the side facing the suction opening of the suction pipe opposite side of the return line. This arrangement of the holes advantageously prevents oil from dripping through a vertically downward opening at the point where the leakage gases have the highest content of oil mist and oil droplets can precipitate on the wall, get into the intake port of the cylinder and for an oversupply of oil. Even if oil droplets are deposited at the location of the first hole, only oil mist with the leakage gases gets into the intake pipe of the cylinder. Since the number of cylinders causes the leakage gases to become less oil-rich, the openings can also be turned towards the intake manifold. At the last intake pipe, the leak gases have already become so low in oil mist that there is no danger that larger oil drops will separate.

In a further embodiment of the invention, the openings in the return line have a nozzle-like extension toward the outside. This configuration of the openings advantageously ensures that the leakage gases flow out uniformly and thus the oil mist is evenly distributed in the intake air of the intake pipes.

In a development of the invention, the return line is used as a separate tube in the intake box. This design is advantageously used when the intake box is flanged to the cylinder head of the internal combustion engine as a separate component, for example made of plastic. It is also provided according to the invention to incorporate or integrate the return line directly into the cylinder head. In this embodiment according to the invention, the return line extends as a rectilinear channel along the intake channels in the cylinder head and the openings open directly into the intake ducts leading to the inlet valves.

By integrating the return line into the block cylinder head or the single cylinder head according to the invention, the space requirement for the return line is limited to a minimum and the number of attachments is reduced.

In an advantageous embodiment, the cylinder head cover is formed in one piece and the return line is integrated into the cylinder head cover.

In an alternative embodiment, the cylinder head is composed of single cylinder heads and the return line is integrated into the single cylinder heads or also into the single cylinder head covers. In this case, a continuous return line is formed by connecting pieces arranged between the individual cylinder heads.

In all of the embodiments, the return line is expediently designed as a bore or is left out when the cylinder head is cast. Furthermore, the return line can also, for. B. are cast as a tube in the cylinder head or the cylinder head.

So that the leakage gases can be distributed to all cylinders, the return line advantageously runs through the entire length of the cylinder head and is arranged in the immediate vicinity of the intake pipes in order to achieve a short connecting line from the return line to the intake pipes. These connecting channels are expediently designed as bores or as throttle screw plugs. To avoid an oil sump in the The return line expediently leads the connecting channels into the return line at the geodetically lowest point. In order that, in the flow direction, all cylinders receive the same amount of leakage gases, the flow cross-section of the connecting channels in the flow direction of the returned leakage gases is expediently formed.

In order to ensure that the oil contained in the leakage gases flows into the cylinders even when the engine is in an inclined position, the intake pipes advantageously protrude from the cylinder head base plate at an angle of approximately 30 °.

Furthermore, it is expedient to flange the return line directly to a breather valve housing via sealing elements in order to achieve the most compact possible construction of the engine.

A supply line for the return line is advantageously incorporated into the cylinder head.

Further features of the invention result from the description and the figures, which show different embodiments of the invention and are described in more detail below.

• Fig. l: den geöffneten Ansaugkasten eines Viertakt-Dieselmotors von der Luftfil­terseite aus gesehen,
• Fig. 2: einen Querschnitt durch diesen Ansaugkasten mit Blick auf ein Ansaugrohr,
• Fig. 3: eine in den Zylinderkopf eingearbeitete Rückführleitung,
• Fig. 4 u. 5: Querschnitte durch die Rückführleitung im Bereich der Öffnungen in die Ansaugkanäle,
• Fig. 6: einen Ausschnitt aus einem Zylinderkopf mit integrierter Rückführleitng für Leckgase,
• Fig. 7: einen Ausschnitt aus einem Zylinderkopf mit in die Zylinderkopfhaube integrierter Rück­führleitung und
• Fig. 8: eine Ansicht und einen Schnitt von einem am Motor angeordneten Entlüftungsventilgehäuse.

It shows:

• L: the open intake box of a four-stroke diesel engine seen from the air filter side,
• 2 shows a cross section through this intake box with a view of an intake pipe,
• 3: a return line incorporated in the cylinder head,
• Fig. 4 u. 5: cross sections through the return line in the area of the openings into the intake ducts,
• 6: a section of a cylinder head with an integrated return line for leak gases,
• Fig. 7: a section of a cylinder head with a return line integrated in the cylinder head cover and
• 8: a view and a section of a vent valve housing arranged on the engine.

In Fig. L, the intake box of a four-cylinder four-stroke diesel engine is shown in the open state. The view is from the air filter side. The housing of the intake box 1 is fastened to the respective cylinder heads with fastening tabs 2, which are not shown here. The four intake pipes 3 can be seen in the top view in the intake box 1. They are inclined with their intake openings 3ʺ to the left and below the intake box, the flanges 4 can be seen for connection to the intake port of the respective cylinder. Af on the left side, the return line 6 for the leak gases is led to the crankcase from a connecting piece 5. The return line 6 is located as a tube inside the intake box 1 above the intake tubes 3. With a Screw connection 7, the return line 6 is fastened to the housing of the intake box 1.

At the level of the suction opening 3ʺ of each suction pipe 3 there is an opening 8 in the return line 6. These openings 8 are located on an almost spiral line around the center line 9 of the return line 6. At the beginning of the return line 6 in the suction box 1 there is the opening Above the first intake pipe on the left almost on the opposite side of the intake opening 3ʺ of the intake pipe 3. In addition, the opening is very small compared to the subsequent openings, which are each rotated by several degrees in the direction of the intake openings of the intake pipes 3, so that the last opening above the last suction pipe points vertically downwards, directly in the direction of the suction opening 3ʺ of the suction pipe 3. This opening is the largest of all four openings shown.

If leakage gases heavily loaded with oil mist are sucked out of the crankcase, there is a risk of oil droplets being deposited in the oil line. This is particularly the case when the return line enters the intake box 1, where the cold, intake air flows around the pipe. If the opening 8 were directed downward directly in the area of the suction opening 3ʺ of the suction pipe 3, there would be the danger that the separated oil droplets would be sucked into the first suction pipe and thus an excess supply of oil would occur in the suction pipe underneath and thus at the inlet valve, while no oil would come in at the last intake pipe. The arrangement of the holes 8 on the return line 6 thus ensures that only oil mist when entering the intake box l is sucked in by the first suction pipe 3 and that the last suction pipe can also suck in the same amount of leakage gases with the same oil content. Tubes can also be inserted into the openings of the return line. If the tubes all have the same cross-section, an opening of any shape and size can be formed by pressing the end together. By bending the pipes, the openings can be rotated as desired in the area of the suction openings of the suction pipes.

Fig. 2 shows a section through the intake box l with a view of the intake opening 3ʺ of an intake pipe 3. On the right side of the intake box l you have to think of the air filter as supplemented, while the mounting bracket 2 is screwed to the associated cylinder head. The intake pipe 3 opens upwards towards the viewer, while it opens at the bottom left of the flange 4 into the intake port of the cylinder. The return line 6 runs above the intake pipe 3. An opening 8 can be clearly seen, which is directed downward at an angle of approximately 45 ° to the vertical through the center line 9 onto the intake opening 3ʺ of the intake pipe 3. The opening 8 has a nozzle-shaped extension l0 towards the outside. This shape of the opening ensures a uniform outflow of the leakage gases and an optimal fanning out of the emerging jet of leakage gases and oil mist, so that good mixing with the air sucked in by the suction pipe 3 takes place. The processing of the openings 8 must be done very carefully so that no burrs and unevenness arise. This could namely have a very strong influence on the flow, so that the leakage gases would be distributed unevenly. The position of the opening 8 in the return line 6 is accordingly shown intake manifold the penultimate of the exhaust pipes shown in Fig. L, counted from the left.

In order to improve the flow conditions in the intake box 1, the return line 6 can also be shielded from the upstream air filter by a short, downward-reaching sheet metal, not shown, which covers the pipe. This can prevent, depending on the position of the openings 8, the upstream filter from being wetted by oil mist.

In the present exemplary embodiment, as shown in FIG. 1, the diameter of the respective openings 8 in the return line 6 increases continuously in the same steps, as seen in the flow direction of the leak gases. If it is advantageous for the flow conditions due to the design, two successive holes can also have the same diameter.

In addition, it is conceivable that the selected angular misalignment of the holes on the circumference of the return line 6 does not take place in angular steps of the same size. For example, two successive holes can be located at the same point on the circumference, at the same angular degree.

In the exemplary embodiment according to FIG. 3, the return line 6 is incorporated directly into the cylinder head 10. The return line 6 is designed as a straight-line channel, which is cut out directly during the casting process of the cylinder head 2 by a corresponding casting core or is subsequently worked into the cylinder head 10, for example by drilling. The return line 6 is arranged above the intake ducts 11 and the openings 8 open directly into the housing walls of the intake ducts ll. The openings 8 are aligned in the intake ducts 11 in a manner analogous to the embodiments described in FIGS. 1 and 2. The supply line, from which the return line 6 is supplied with leakage gases and oil mist, is advantageously incorporated into the cylinder head l0 in this embodiment and connected to the crankcase of the internal combustion engine via corresponding lines and possibly valves.

The sections according to FIGS. 4 and 5 show the different openings of the openings 8 into the intake ducts 11 of the cylinder head 10, reference being made to the description of the drawing relating to FIGS. 1 and 2 with regard to the orientation of the openings 8.

The return line 6 according to the invention can be used in all types of four-stroke internal combustion engines. In addition to the two- and four-cylinder engines shown in the figures, three-, five-, six- and multi-cylinder engines are suitable for the application of the invention.

Fig. 6 shows a section of a cylinder head 3ʹ of a four-stroke internal combustion engine with integrated return line for leak gases. An intake pipe 2ʹ or an inlet channel for the combustion gases is arranged at an angle of approximately 30 ° from the cylinder head base plate 9ʹ projecting. Via an inlet valve l0ʹ the intake pipe 2ʹ is in communication with a combustion chamber, not shown. The inlet valve l0ʹ can be acted upon by a rocker arm llʹ against the force of a spring l2ʹ, the other, not shown end of the rocker arm llʹ with the cam shaft or the tappet tube of the motor is in operative connection. The rocker arm llʹ together with the spring l2ʹ is covered by a cylinder head cover 5ʹ, which is connected to the cylinder head 3ʹ via a seal l3ʹ. According to the invention, the cylinder head 3ʹ is designed as a block cylinder head or as a single cylinder head and in the cylinder head 3ʹ there is a return line 4ʹ running through the entire length of the head, ie the return line 4ʹ is integrated in the cylinder head 3ʹ.

If the cylinder head 3ʹ is composed of individual cylinder heads, the continuous return line 4ʹ is formed by connecting pieces arranged between the cylinder heads 3ʹ. As connectors are z. B. Double plug-in pieces are ideally suited.

The return line 4ʹ is arranged in the immediate vicinity of the intake pipes 2ʹ and is either designed as a hole or cast or recessed in the mold.

So that the recirculated leakage gases can get into the respective intake pipes 2ʹ of the cylinders, the return line 4ʹ is connected to the intake pipes 2ʹ via connecting channels 8ʹ. In this case, a connection channel 8 'is assigned to each intake pipe or inlet channel.

To avoid an oil sump in the return line 4ʹ advantageously the connecting channels 8ʹ open at the geodetically lowest point in the return line 4ʹ.

The connecting channels 8ʹ can advantageously be designed as bores or as throttle screw plugs 5ʹ be. Appropriately, the size of the connecting channel 8ʹ or its position to the intake pipe 2ʹ varies depending on the number of engine cylinders. In order to ensure a uniform supply of all intake pipes 2ʹ with the same amount of leakage gases, the flow cross section of the connecting channels 8ʹ in the flow direction of the returned gases is expediently formed. As can be seen in FIG. 6, the connecting channels 8 'are introduced into the return line 4' from the inside of the intake pipes 2 '. This eliminates additional locking parts that would be necessary if the connecting channels 8ʹ were introduced from the outside. Between the connecting channel 8ʹ and the intake pipe 2ʹ a recess l4ʹ is arranged, which serves for better attachment of the connecting channel 8ʹ.

Fig. 7 shows an alternative embodiment in which the cylinder head cover 5ʹ is formed in one piece and the return line 4ʹ is integrated into the cylinder head cover. The cylinder head cover 5ʹ is flanged to the cylinder head 3ʹ with the interposition of seals l3ʹ. From the return line 4ʹ towards the connection seam cylinder head cover-cylinder head leads a connection channel 8ʹ, which is designed as described in Fig. 6. The connecting channel 8ʹ can be easily inserted into the cylinder head cover 5ʹ before it is installed. The connecting channel 8ʹ is connected to the intake pipe 2ʹ via a further, larger diameter connecting channel 8ʹ. In the seam of the cylinder head cover-cylinder head, the two connecting channels 8ʹ merge. Due to the arrangement of the return line 4 Bereich in the area of the steeply rising intake pipes 2ʹ or inlet channels, there is an oil sump or an oil deposit in the air intake housing or in the intake pipe 2ʹ prevented. Even with extreme engine inclinations, the oil drain is guaranteed by the 30 ° angle of attack of the intake pipe 2ʹ to the cylinder head base 9ʹ (see Fig. 6), in the direction of valve seat l5ʹ.

Fig. 8 shows a view Fig. 8a and a section of a vent valve housing 7ʹ arranged on the engine. This vent valve housing 7ʹ is part of the return line. It can be seen that the return line 4ʹ directly over sealing elements 6ʹ z. B. a round seal is flanged to the vent valve housing 7ʹ. The vent valve housing 7ʹ is in turn connected directly to the crankcase lʹ.

When the engine is operating, the leakage gases pass from the crankcase lʹ via the breather valve in the breather valve housing 7ʹ into the return line 4ʹ and from there via the connecting channels 8ʹ into the respective intake pipes 2 Zylinder of the cylinders. This embodiment according to the invention is inexpensive since no separate oil distribution pipe and no connecting line between the vent valve and the cylinder head is necessary. Furthermore, the space requirement is reduced to a minimum, since the return line 4ʹ is accommodated in the existing cylinder head space or in the cylinder head cover 5ʹ.

Claims (20)

1. return line for leak gases from the crankcase of a four-stroke internal combustion engine into the intake pipes of the cylinders,
characterized in that the return line (6) communicates with each intake pipe (3) of a cylinder via an opening (8), the diameter of the openings (8) changing in the direction of flow of the leakage gases in the return line (6) and the last opening has a much larger diameter and a different exit direction into the intake pipe than the first opening. 2. return line for leak gases according to claim l,
characterized in that the openings (8) are arranged in a spiral or almost spiral line around the return line (6), the first opening (8) seen in the flow direction of the return line (6) on that of the suction opening (3ʺ) of the suction pipe ( 3) facing away and the last on the side of the return line (6) facing the suction opening (3ʺ) of the suction pipe (3). 3. return line for leak gases according to claim l or 2,
characterized in that, viewed in the direction of flow of the leak gases, the diameter of the respective openings (8) in the return line (6) increases from the first to the last opening. 4. return line for leak gases according to one of claims 1 to 3,
characterized in that the openings (8) of the return line (6) have a nozzle-shaped extension (l0) towards the outside. 5. return line for leak gases according to one of claims l to 4,
characterized in that the return line (6) is arranged as a separate tube in the intake box (l). 6. return line according to one of claims 1 to 4,
characterized in that the cylinder head (3ʹ) is designed as a block cylinder head and the return line (4ʹ) is integrated in the cylinder head (3ʹ). 7. return line according to claim 6,
characterized in that the cylinder head cover (5ʹ) is formed in one piece and the return line (4ʹ) is integrated in the cylinder head cover (5ʹ). 8. return line according to one of claims 1 to 4,
characterized in that the cylinder head (3ʹ) is composed of individual cylinder heads, the return line (4ʹ) is integrated into the single cylinder heads and a continuous return line (4ʹ) is formed by connecting pieces arranged between the individual cylinder heads. 9. return line according to claim 8,
characterized in that the return line (4ʹ) is integrated in the single cylinder head covers. l0. Return line according to one of claims 6 to 9,
characterized in that the return line (4ʹ) is designed as a bore. 11. return line according to one of claims 6 to 9,
characterized in that the return line (4ʹ) is cast in. 12. return line according to one of claims 6 to ll,
characterized in that the return line (4ʹ) runs through the entire length of the cylinder head (3ʹ) and is arranged in the immediate vicinity of the intake pipes (2ʹ). 13. return line according to one of claims 6 to l2,
characterized in that the return line (4ʹ) is flanged directly to a vent valve housing (7ʹ) via sealing elements (6ʹ). 14. return line according to one of claims 6 to l3,
characterized in that the return line (4ʹ) is connected to the intake pipes (2ʹ) via connecting channels (8ʹ). 15. return line according to claim l4,
characterized in that the connecting channels (8ʹ) open into the return line (4ʹ) at the geodetically lowest point. 16. return line according to claim l4 or l5,
characterized in that the connecting channels (8ʹ) are designed as bores. 17. return line according to one of claims l4 to l6,
characterized in that the connecting channels (8ʹ) are designed as throttle screw plugs. 18. return line according to one of claims l4 to l7,
characterized in that the flow cross section of the connecting channels (8ʹ) increases in the direction of flow of the recirculated gases. 19. return line according to one of claims 6 to l8,
characterized in that the intake pipes (2ʹ) protrude from the cylinder head base plate (9ʹ) at an angle of approximately 30 °. 20. return line according to one of claims l to l9,
characterized in that a supply line for the return line (6) is incorporated in the cylinder head (l0).

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