EP0016381A1 - Air-cooled four-stroke internal-combustion engine with rotary slide valve - Google Patents

Abstract

1. Air-cooled four-stroke internal-combustion engine which is controlled by a rotary valve, with a cylinder liner, mounted in a bearing-bore in the cylinder block, in a manner permitting rotation about its axis, with a fixedly attached bottom which bears against the cylinder head in a manner effecting sealing, and forms the rotary valve, the liner being driven from the crankshaft via a gearwheel-drive in the ratio 1:2, wherein the bottom has a passage port and the cylinder head has at least one inlet port and at least one exhaust port, all three ports being located on the same diameter, (14, 26) is provided in the cylinder block (2), contiguous in a manner known per se with the outer wall (3a) of the cylinder liner (3), and extending from the crankcase (9) essentially up to the cylinder head (6), and opening, at the end adjacent to the cylinder head (6), into a second passage (17), and in that the crankcase (9), which is otherwise closed on all sides, communicates with the outside air via an inlet passage (19, 20; 27) and an automatic valve arrangement (20, 21; 28), which permits outside air to flow into the crankcase (9) during the upward movement of the piston (22) from its lower to its upper dead centre, and closes the inlet passage (19, 20; 27) during the downward movement of the piston (22), so that the air which has been drawn into the crankcase (9) is displaced through the first and second passages (14, 26, 17) for cooling.

Description

The invention relates to an air-cooled, rotary valve-controlled four-stroke internal combustion engine with a cylinder liner rotatably mounted about its axis in a bearing bore of the cylinder block, which has a fixedly connected to it, sealingly abutting the cylinder head, forming the rotary slide valve, and via a gear transmission from the crankshaft in Ratio 1: 2 is driven, the bottom having a passage opening and the cylinder head having at least one inlet and one outlet opening, all of which are arranged on the same diameter.

Known rotary valve-controlled four-stroke internal combustion engines of this type (cf. DE-OS 27 14 351) are used in practice primarily as Tiodell engines, that is to say for driving model aircraft, model ships and model cars. Up to a cubic capacity of about 6 cc, such rotary valve-controlled four-stroke internal combustion engines also work relatively well. With a larger displacement, however, cooling and lubrication is no longer sufficient with air-cooled engines. The heat generated in the rotating cylinder liner must namely be transferred to the cylinder block via its outer wall and from there via cooling fins to the outside air. Some of the heat is also transferred from the bottom of the cylinder liner to the cylinder head. In the case of larger air-cooled engines, however, the heat dissipation is insufficient, so that in particular the cylinder liner heats up inadmissibly. Furthermore, in such a rotary valve-controlled four-stroke internal combustion engine, it is absolutely necessary that the cylinder liner rotating with a high number of revolutions is lubricated on its outer wall.

So far, this has been done in that the oil contained in the crankcase is thrown up by the movement of the crankshaft and also in the crankcase driven gear transmission and penetrates into the gap between the outer wall of the cylinder liner and the bearing bore. However, this type of lubrication is insufficient for engines with a larger displacement.

There is also known a water-cooled, rotary valve-controlled four-stroke internal combustion engine (US Pat. No. 1,614,634) in which a helical groove which is open towards the cylinder liner is incorporated into the wall of the bearing bore for the cylinder liner. In the . An intake port is provided in the cylinder head and communicates with this helical groove via an annular channel. Lubricating oil is pressed into the helical groove through this inlet channel and the ring channel. This lubricating oil lubricates the rotating cylinder liner and then enters the crankcase. The cylinder block is double-walled, with cooling water being pumped through the cavity between the two walls.

However, this known water-cooled internal combustion engine is considerably more expensive than an air-cooled engine due to the water cooling. In addition to the double-walled design of the cylinder block, a water pump, a cooler and a driven fan must also be provided for the cooling water. There is also a pump for the oil to be pumped into the helical groove and, if necessary, an oil cooler. Apart from the increased manufacturing costs, such additional units are also subject to wear and are therefore prone to repair and malfunction. They also increase the overall weight of the engine, what is particularly disadvantageous for model engines.

The invention has for its object to provide an air-cooled, rotary valve-controlled four-stroke internal combustion engine of the type mentioned, in which sufficient cooling and lubrication is ensured in a simple manner without essential additional units.

This is achieved according to the invention in that, in a manner known per se, adjacent to the outer wall of the cylinder liner in the cylinder block, at least one first channel extending from the crankcase to the cylinder head is provided, which opens into a second channel on the cylinder head side and that otherwise All-round closed crankcase communicates with the outside air via an inlet channel and an automatically acting valve arrangement, which allows outside air to flow into the crankcase when the piston moves upwards from its lower dead center to its top dead center and closes the inlet channel when the piston moves downward, so that the inlet valve closes Crankcase intake air is displaced through the first and second channels.

The rotary valve-controlled four-stroke internal combustion engine achieves excellent cooling and significantly improved lubrication of the cylinder liner by very simple means that do not require any significant design effort. It is only necessary to provide one or expediently several channels acting as cooling air channels in the cylinder block adjacent to the outer wall of the cylinder liner and an outlet channel and the valve arrangement mentioned above in the cylinder block or cylinder head. The piston moving up and down serves its upward movement draws cool outside air into the crankcase. When the piston moves downward, this can only be displaced by the cooling air channels and the outlet channel, since the valve arrangement closes the inlet channel when the piston moves downward. The air flowing along the outer wall of the cylinder liner cools the cylinder liner, this cooling extending over a larger circumferential area of the cylinder liner, since the latter rotates past the cooling air channels. The cooling air also pulls oil droplets out of the crankcase into the cooling air channel or channels. These oil droplets attach themselves to the outer wall of the cylinder liner and are also carried into the gap between the cylinder liner and the bearing bore when the cylinder liner rotates. The cooling air channels also ensure excellent lubrication, in particular of the parts of the cylinder liner that are distant from the crankshaft.

Advantageous embodiments of the invention are characterized in the subclaims.

• Figuren 1 und 2 je einen Längsschnitt durch ein erstes Ausführungsbeispiel des Motors mit zwei verschiedenen Kolbenstellungen,
• Figur 3 einen Halb-Querschnitt nach der Linie III-III der Figur 1,
• Figur 4 einen Querschnitt nach der Linie IV-IV der Figur 2,
• Figur 5 einen Teillängsschnitt durch ein zweites Ausführungsbeispiel und
• Figur 6 einen Hälb-Querschnitt nach der Linie VI-VI der Figur 5.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawing. It shows

• FIGS. 1 and 2 each show a longitudinal section through a first embodiment of the engine with two different piston positions,
• 3 shows a half cross section along the line III-III of FIG. 1,
• FIG. 4 shows a cross section along the line IV-IV in FIG. 2,
• Figure 5 shows a partial longitudinal section through a second embodiment and
• 6 shows a half cross-section along the line VI-VI of Figure 5.

In a bearing bore 1 of the cylinder block 2, a cylinder liner 3 is rotatable about its axis and can be displaced to a limited extent in the axial direction. The upper end of the cylinder liner 3 is closed by a bottom 4 which is firmly connected to the cylinder liner. This bottom 4 has an eccentrically arranged through bore 5. The bottom 4 rests with a flat sealing surface 4a on the cylinder head 6 and is initially held against the cylinder head 6 with little force by springs, not shown, which act on the flange 7. The cylinder head 6 has an inlet opening 8 and an invisible outlet opening, which is arranged on the same diameter, but which displaces the inlet opening 8 in the circumferential direction. Another opening, which is also arranged on the same diameter, serves to receive a glow plug. The bottom 4 forms a rotary slide valve which interacts with the cylinder head 6.

The crankcase 9 adjoins the cylinder block 2 at the bottom. Only to simplify the drawings, cylinder block 2 and crankcase 9 are shown in one piece in the exemplary embodiment shown, but in practice both parts are usually manufactured separately and screwed together during assembly. The crankshaft 10 is mounted in the crankcase 9. It carries a pinion 11 which, via a first bevel gear 12, the bevel gear 13, which is fixedly connected to the cylinder liner 3, In the embodiment shown, four, axially parallel grooves 14, which are open towards the outer wall 3a of the cylinder liner 3 and are used as cooling air channels and for the supply of lubricant, are provided in the wall of the bearing bore 1. The grooves 14 extend from the crankcase 9 to approximately the cylinder head 6 over approximately the entire length of the cylinder liner 3. On the cylinder head side, the grooves 14 open into an annular channel 15 which is incorporated into the cylinder head-side end 2a of the cylinder block 2. In addition, part of the annular channel 15 is formed by an annular shoulder 16 screwed into the sealing surface 4a on the circumference of the base 4. This ring shoulder 16 has at the same time the effect that the sealing surface 4a lying against the cylinder head 6 is reduced and thus the friction between the two parts is reduced. In addition, lubricant can also penetrate better to the remaining sealing surface 4a. An outlet channel 17 provided in the cylinder head 6 opens into the ring channel 15. However, this outlet channel can optionally also be arranged at the end 2a of the cylinder block 2 on the cylinder head side.

A valve arrangement is also provided which controls the supply of outside air into the crankcase, which is otherwise closed on all sides, in a certain way. In the exemplary embodiment shown in FIGS. 1-4, this valve arrangement is formed by parts of the crankshaft and a housing part (connecting piece) 18 connected to the crankcase 9. The crankshaft 10 has an axial bore 19 which is open towards the inside of the crankcase 9 and a radial bore 20 which is provided outside the actual crankcase in the region of the housing part 18. The two bores 19 and 20 together form an inlet channel. The housing part 18 surrounding the crankshaft 10 has one over a Part of the circumference of the crankshaft 10 extends _' with the radial bore 20 in a radial plane lying inlet opening 21. This inlet opening 21 can extend approximately over half the circumference of the crankshaft 10. The inlet opening 21 is arranged opposite the radial bore 20 such that the radial bore 20 moves in the region of the inlet opening 21 when the piston 22 moves upward from its lower to its upper dead center in the direction A, as shown in FIG. 1. When the piston moves downward in direction B, on the other hand, the radial bore 20 rotates in a region of the housing connector 18 which is not covered by the inlet opening 21. The radial bore 20 is thus closed by the nozzle 18 during the downward movement of the piston.

• Bei Aufwärtsbewegung des Kolbens 22 von seinem unteren Totpunkt zu seinem oberen Totpunkt in Richtung A entsteht in dem Kurbelgehäuse 9 ein Unterdruck, da der sich aufwärtsbewegende Kolben wie ein Pumpenkolben wirkt. Während der Aufwärtsbewegung des Kolbens 22 kann frische Außenluft durch die Einlaßöffnung 21, die Radialbohrung 20 und die Axialbohrung 19 in das Innere des Kurbelgehäuses 9 eindringen. Die Querschnitte und Längen der Bohrungen 19 und 20 und der Einlaßöffnung 21 sind gegenüber den Querschnitten und Längen der Kühlkanäle 14 des Ringkanales 15 und des Auslaßkanales 16 so bemessen, daß in den zuletzt genannten Kanälen ein größerer Widerstand entsteht als in den Bohrungen 19 und der Einlaßöffnung 21. Da die Luft stets auf dem Weg des geringsten Widerstandes strömt, ist sichergestellt, daß während der Aufwärtsbewegung des Kolbens Außenluft im wesentlichen nur durch die Einlaßbohrung 21 und die Bohrungen 19, 20 in das Innere des Kurbelgehäuses 9 einströmt.

The new cooling and lubrication system works as follows:

• When the piston 22 moves upwards from its bottom dead center to its top dead center in the direction A, a negative pressure is created in the crankcase 9, since the piston moving upwards acts like a pump piston. During the upward movement of the piston 22, fresh outside air can penetrate into the interior of the crankcase 9 through the inlet opening 21, the radial bore 20 and the axial bore 19. The cross sections and lengths of the bores 19 and 20 and the inlet opening 21 are dimensioned with respect to the cross sections and lengths of the cooling channels 14 of the annular channel 15 and the outlet channel 16 so that a greater resistance arises in the latter channels than in the bores 19 and the inlet opening 21. Since the air always flows on the path of least resistance, it is ensured that, during the upward movement of the piston, outside air essentially flows into the interior of the crankcase 9 only through the inlet bore 21 and the bores 19, 20.

When the piston 22 has reached its top dead center, the crankshaft 10 has rotated so far that the radial bore 20 no longer rotates in the region of the inlet opening 21. The bore 20 is now closed by the part of the housing part 18 shown on the right in FIG. 4. During the downward movement of the piston 22 in the direction B, the piston 22 also runs as a pump and displaces the cool outside air previously sucked into the cylinder housing 9 through the grooves 14 and the annular channel 15 into the outer channel 17. The cool one that runs along the outer wall 3a of the cylinder liner 3 Outside air cools the cylinder liner 3. Thanks to the rotation of the cylinder liner 3, this cooling extends not only to partial areas of the outer wall 3a, but also to the entire outer wall 3a of the cylinder liner 3.

The air displaced from the crankcase 9 entrains oil droplets from the crankcase into the grooves 14 and the annular channel 15. These oil droplets provide excellent lubrication between the cylinder liner 3 and the bearing bore 1. In addition, these oil droplets also reach the area of the sealing surface 4a via the annular channel 15 and in particular in paragraph 16 and also provide good lubrication there. This combined cooling and lubricating effect is achieved in the engine according to the invention without an additional pump.

The heated exhaust air emerging from the outlet duct 17 can either be discharged into the open or can also be returned to the carburetor V via a connecting line 23. The connecting line 23 prevents any oil droplets still present in the exhaust air from reaching the outside air. At the same time, however, it is also achieved that the oil droplets are supplied to the mixture via the carburetor V and cause additional lubrication between the piston 22 and the cylinder liner 3. So practically no oil is lost. The The connecting line 23 is expediently guided outside the cylinder head over a greater length, so that the connecting line 23 also serves as a heat exchanger and the exhaust air flowing through the connecting line 23 is cooled again by the outside air surrounding the connecting line 23.

5 and 6 show a further exemplary embodiment, the rotary slide valve-controlled four-stroke internal combustion engine functioning in the same way as the exemplary embodiment shown in FIGS. 1-4. Parts of the same function are therefore also designated with the same reference symbols, the above description being to be applied analogously. In the embodiment shown in FIGS. 5 and 6, however, a needle bearing consisting of a plurality of needles 24 is provided between the outer wall 3a of the cylinder liner 3 and the bearing bore 1 of the cylinder head 2. The needles 24 are kept at a distance by cage rings 25. The spaces 26 present between the individual needles 24 form the cooling air ducts in this exemplary embodiment. The oil droplets entrained by the cooling air lubricate the bearing needles 24. In this embodiment, it is very important that the cooling air flows through the spaces 26, since in this embodiment only very small contact areas between the outer wall 3a of the cylinder liner 3 and the bearing needles 24 on the one hand and between the latter and the bearing bore 1 are present on the other hand. The heat transfer from the cylinder liner 3 to the cylinder block 2 is therefore low. The heat dissipation by means of the cooling air flowing between the two parts and also the lubrication of the needle bearing is significantly improved by the cooling and lubrication system according to the invention.

5 should also be shown that the valve arrangement can be configured differently than in the embodiment shown in FIGS. 1-4. 5, an inlet channel 27 is provided in the wall of the crankcase 9. The valve flap 28 of a flutter valve is arranged on the inside of the crankcase 9. When the piston 22 moves upward, the valve flap 28 is lifted off the inlet channel 27 and cool outside air can flow into the interior of the crankcase 9. When the piston moves downward in direction B, an overpressure is achieved in the crankcase 9, which presses the valve flap 28 against the inner wall of the crankcase 9 and thus closes the inlet channel 27. The cool outside air sucked into the crankcase can now only escape through the spaces 26, the annular channel 15 and the outlet channel 17.

Claims (10)

1.Air-cooled, rotary vane-controlled four-stroke internal combustion engine with a cylinder liner which is rotatably mounted about its axis in a bearing bore of the cylinder block, which has a bottom firmly connected to it, which seals against the cylinder head and forms the bottom of the rotary valve and via a gear transmission from the crankshaft in a ratio of 1 : 2 is driven, the bottom having a passage opening and the cylinder head having at least one inlet and one outlet opening, all three of which are arranged on the same diameter, characterized in that, in a manner known per se, adjacent to the outer wall (3a) of the cylinder liner (3) in the cylinder block (2) at least one extending from the crankcase (9) substantially to the cylinder head (6) first channel (14, 26) is provided, which opens on the cylinder head side into a second channel (17) and that otherwise crankcase (9) closed on all sides with the outside air via an inlet duct (19, 20; 27) and e an automatically acting valve arrangement (20, 21; 28) is connected which, when the piston (22) moves upwards, allows outside air to flow into the crankcase (9) from its bottom dead center to its top dead center and closes the inlet channel (19, 20; 27) when the piston (22) moves downwards that the air sucked into the crankcase (9) is displaced for cooling by the first and second channels (14, 26, 17). 2. Motor according to claim 1, characterized in that the first channel in a known manner in the wall of the bearing bore (1) incorporated, to the outer wall (3a) of the cylinder liner (3) is open groove (14). 3. Motor according to claim 1, characterized in that the groove (14) extends in the axial direction of the bearing bore (1). 4. Engine according to claim 2 and 3, characterized in that a plurality of grooves (14) are provided which open on the cylinder head side in a with the second channel (17) in connection, known ring channel (15). 5. Engine according to claim 4, characterized in that the annular channel (15) at the cylinder head end (2a) of the cylinder block (2) is incorporated therein. 6. Motor according to one or more of the preceding claims, characterized in that a needle bearing (24, 25) is provided between the outer wall (3a) of the cylinder liner (3) and the bearing bore (1) and the first channels through which between the bearing needles (24) existing gaps (26) are formed. 7. Engine according to claim 1, characterized in that the valve arrangement (20, 21) is controlled by the crankshaft (10). 8. Engine according to claim 7, characterized in that the crankshaft (10) has an axial bore (19) with an outside of the actual crankcase (9) provided radial bore (20) which together form the inlet channel, and in that the crankshaft (10) in the area of the radial bore (20) is surrounded by a housing part (18) which has an inlet opening (21) which extends over part of the circumference of the crankshaft (10) and is arranged with the radial bore (20) in a radial plane. Engine according to claim 1, characterized in that the second channel (17) is connected to the carburetor (V) via a connecting line (23). 10. Motor according to claim 1, characterized in that the valve arrangement consists of a check valve (28).

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