DE19503444C1 - Two=stroke opposed=piston engine - Google Patents

Abstract

One or more cylinders each have inlet and outlet slots and contain two opposed pistons coupled to a common crankshaft. The outer crankpins of the latter are coupled by pull rods to the piston furthest from it, and the third one to that closest to it.Two connecting rods (33,34) are coupled between the piston (14) furthest from the crankshaft (5) and a sleeve (32) sliding in the engine housing in a guide (39) parallel to the vertical axis (40) of the engine. The pull rods (35-38) between the sleeve and piston can be situated inside the outer crankpins when seen in the direction of the vertical axis. The sleeve and guide can be formed by opposite sectors of a cylinder.

Description

The invention relates to a two-stroke counter-piston engine according to the preamble of claim 1.

DE 41 35 386 C2 is already a two-stroke counter-piston engine Tor of the generic type known, the two cylinders with each Weil inlet and outlet slots, an inlet and an outlet channel and two oppositely interacting pistons (inlet and Exhaust piston) includes direct force flow elements on a common crankshaft act. The crankshaft has two Main bearing journal and three crank pins, of which the two outer Outer crank pin with the piston remote from the crankshaft over train rods are connected and the third crank pin with the cure Belwell near the piston is connected via a crank loop.

The general technical background is still under pressure publications DE 33 27 225 C2 and WO 89/07704 referenced.

A disadvantage of generic two-stroke counter-piston engines is that their overall length is relatively large, especially when the multi-cylinder design. Another disadvantage Generic engines is the poor guidance of the crank piston remote from the shaft.

The invention has for its object a generic Two-stroke counter-piston engine as simple and inexpensive as possible form that the leadership of the distant crankshaft at improved as compact as possible the structure of the engine becomes.  

The object is achieved by the in the characteristic of Main claim given characteristics solved.

An advantage of the two-stroke counter-piston engine according to the invention is that the slide rods in the frame through the sliding sleeve of the available installation space as desired, depending on its scope can be arranged, whereby the motor according to the invention structurally much more compact than generic motors. Furthermore, the sliding sleeve Guide of the drawbars significantly improved.

It is due to the configuration according to the invention according to claim 2 possible, the tie rods in the direction of view normal to the axis of rotation to arrange the crankshaft within the crankpin. This leads to a considerable reduction in the overall length of the motor, especially with multi-cylinder construction, because the lateral distance between the cylinders can be significantly reduced without on the advantageous merging of the inlet and outlet channels to a common flange on each motor side to have to do without.

Further configurations and advantages of the invention go out the other subclaims and the description.

In the drawing, the invention is based on an exemplary embodiment game explained in more detail. Show it:

Fig. 1 is a full section in the direction of a cylinder vertical axis and normal to the axis of rotation of a crankshaft of a two-stroke counter-piston engine according to the invention in an embodiment with two cylinders offset by 180 ° and each with two oppositely interacting pistons, which act on direct force flow elements on a common crankshaft, the the two pistons remote from the crankshaft are designed as multi-acting pistons for pre-compression of fresh gas and the pistons near the crankshaft are integrally connected to one another to form a double-acting piston,

Fig. 2 is a full sectional view in the direction of the cylinder vertical axis and in the direction of the rotational axis of the crankshaft of the two-cycle opposed-piston engine of FIG. 1,

Fig. 3 shows a section III-III of FIG. 2, vertical axis normal to the cylinder and shaft parallel to the axis of rotation of the crank,

Fig. 4 is a view of the two with a connecting piece a lumpy connected, close crankshaft piston of Figs. 1 and 2,

Fig. 5 shows a section VV of Fig. 2 normal to the cylinder vertical axis and parallel to the axis of rotation of the crankshaft through inlet channels and inlet slots and

Fig. 6 is a section VI-VI of Fig. 2 normal to the cylinder vertical axis and parallel to the axis of rotation of the crank shaft through outlet channels and outlet slots of the two-stroke counter-piston engine according to the invention.

Figs. 1 and 2 show a twin-cylinder two-stroke counter-piston motor having a motor housing 1, the two offset by 180 ° Zy relieving blocks 2 and 3 and a crankcase 4 includes, in which a crankshaft 5 in two main bearings 6 and 7 is mounted. An oil pan W is arranged on the motor housing 1 . For a better graphic representation, the motor according to the invention is bezüg Lich its preferred position of use rotated by 90 ° represents Darge.

In the cylinder blocks 2 and 3 there are cylinders 8 and 9 , the cylinder 8 comprising an inlet channel E1 with inlet slots 10 and an outlet channel A1 together with outlet slots 12 and the cylinder 9 including an inlet channel E2 with inlet slots 11 and an outlet channel A2 together with outlet slots 13 . The inlet and outlet channels E1 and A1 leading to the inlet and outlet slots 10 and 12, respectively, are brought together to form a common flange 53 and 54 on one engine side (see FIG. 3). The Zylin of 8 and 9 are completed with cylinder covers D and D '.

In the cylinders 8 and 9 , two oppositely acting pistons 14 and 15 (cylinder 8 ) and 16 and 17 (cylinder 9 ) are each guided, which act on the common crankshaft 5 via power flow elements K described in more detail below.

In the cylinder 8 , the remote crankshaft piston 14 controls a lassschlitze 10 and the near-crankshaft piston 15, the outlet slots 12th Analogous to this, controls in the cylinder 9 of the piston 16 kurbelwel lenferne the inlet slots 11 and the kurbelwellenna he piston 17, the exhaust ports. 13

The crankshaft 5 has two outer crank pins 18 and 20 as well as two inner crank pins 19 and 46 . The two outer cure belzapfen 18 and 20 are designed as a stroke eccentric. The two inner crank pins 19 and 46 are connected to the piston 17 near the crankshaft.

The inner crank pin 19 and 46 are offset to the outer crank pin 18 and 20 by a crank angle α in the range of 160-180 °. In Figs. 1 and 2, a displacement of the Kurbelwin kels α of 180 ° is shown.

Piston rings aj are arranged on the pistons 14-17 in a manner known in principle. The piston rings a and b of the piston 14 and the piston rings h and i of the piston 16 are preferably designed as compression rings.

The above-mentioned direct force flow members K between the pistons 14 , 16 remote from the shaft and the crankshaft 5 comprise two connecting rods 33 and 34 connected to a sliding sleeve 32 , and tie rods 35 and 36 (for the piston 14 ) and tie rods 37 and 38 (for the piston 16 ), the sliding sleeve 32 on a slide 39 in the engine housing 1 parallel to a cylinder vertical axis 40 and connected via the tie rods 35 , 36 and 37 , 38 with the crankshaft distant pistons 14 and 16 respectively.

The sliding sleeve 32 and the slideway 39 form a pair of slidings, which, viewed from a rotational axis 45 of the crankshaft 5 , each comprise two opposing cylinder jacket sectors S1, S2 or S3, S4, which in the direction of the cylinder vertical axis 40 be viewed between connecting rod receptacles 43 , 44 of the sliding sleeve 32 are arranged (see Fig. 3). In a non-illustrated embodiment of the invention, if only a connecting rod is used for the articulation of the piston near the crankshaft, the pairing can be carried out in such a way that it only comprises two cylinder jacket sectors which are cut through a cylinder meridian plane normal to the axis of rotation of the crankshaft.

Each of the parallel to the cylinder vertical axis 40 Zugstan gene 35-38 is at least about the crankshaft radius r normal to the crankshaft 5 and viewed in the direction of the cylinder vertical axis 40 between the connecting rod receptacles 43 , 44 of the sliding sleeve 32 .

The two pistons 14 and 16 remote from the crankshaft are designed as multi-acting pistons and serve as a flushing pump for the two-stroke counter-piston engine according to the invention.

In the following the invention is explained on the piston 14 remote from the crankshaft in the cylinder 8 and of course applies to the piston 16 remote from the crankshaft for the cylinder 9 in an analogous manner.

The crankshaft distant piston 14 partially limits two vonein other independent working chambers 21 and 22 , which serve the pre-compression of fresh air and from which this fresh air is supplied to the inlet slots 10 . The working chamber 21 is bordered by the piston 14 and the cylinder block 1 and the working chamber 22 by the piston 14 , the cylinder block 1 and the cylinder cover D be.

Each of the two working chambers 21 , 22 comprises an inlet valve 25 , 26 controlled with an inlet valve 23 , 24 for the supply of fresh air and an outlet valve 27 , 28 controlled outlet opening 29 , 30 for outlet of the pre-compressed fresh air to the inlet slots 10 . The outlet valves 27 , 28 of the two working chambers 21 , 22 open into a chamber 31 which has a direct flow connection to the inlet slots 10 of the cylinder 8 .

The inlet opening 25 and the outlet opening 29 in the first Ar beitskammer 21 is in the region of the bottom dead center of the multi-acting piston 14 and the inlet opening 26 and the outlet opening 30 in the second working chamber 22 is arranged in the region of the top dead center of the multi-acting piston 14 .

As can be seen in FIG. 1, the multi-acting piston 14 remote from the crankshaft controls the inlet slots 10 .

Analog reference numerals for the piston 14 / cylinder 8 area are shown apostrophied in the piston 16 / cylinder 9 area . This affects, among other things, the working chambers 21 'and 22 ', the one inlet valves 23 'and 24 ', the inlet openings 25 'and 26 ', the outlet valves 27 'and 28 ', the outlet openings 29 'and 30 ' and the chamber 31 'and the cylinder cover D '.

On the right side of the engine housing 1 in Fig. 1, each because between the inlet and outlet channels E1, A1 and E2, A2, injectors 41 , 42 and spark plugs Z1, Z1 'are arranged. Of course, the invention is not limited to this embodiment. For example, two-stroke engines according to the invention can also be designed as prechamber diesel engines or direct injection diesel engines.

When the two-stroke counter-piston engine is designed with two cylinders 8 , 9 ; and two opposing pistons 14 , 15 and 16 , 17 , respectively, the tie rods 35 , 36 of the first piston 14 remote from the crankshaft and tie rods 37 , 38 of the second piston 16 remote from the crankshaft are attached to the sliding sleeve 32 , so that the two pistons 14 remote from the crankshaft , 16 are rigidly connected. In a non-Darge presented embodiment of the invention, instead of the two tie rods between the crankshaft distant pistons 14 and 16 and the sliding sleeve 32 , for example, four tie rods each may be arranged if this is possible from the installation space and for reasons of rigidity is desirable.

The compression ratio of the two-stroke counter-piston engine can be adjusted by installing the tie rods 35 , 36 or 37 , 38 .

Between the outer crankpins 18 and 20 of the crank shaft 5 are shown in FIG. 2, two crank pins 19, arranged 46, 48 are connected to the crankshaft close piston 17 via two connecting rods 47, wherein the bearing width B of the two outer Kurbelzap fen 18, 20 and the two inner crank pins 19 , 46 is the same.

The two crankpins 19 and 46 are coupled to the crankshaft close piston 17, the piston 17 is connected to the piston 15 with a connector 49 rigid. The connecting piece 49 between the pistons 15 and 17 has a cutout 50 for the implementation and for free running of the crankshaft 5 .

The two rigidly connected pistons 15 and 17 together with connecting piece 49 are arranged within the sliding sleeve 32 , the sliding sleeve 32 extending parallel to the cylinder vertical axis 40 from cuts 51 , 52 (see FIG. 3) for the freewheeling of the inner crank pins 19 and 46 of the crankshaft 5 has.

The connecting rod ratio (ratio of crank radius r to connecting rod length l) λ _i and λ _{a of} the outer connecting rod pair 33 , 34 (r _a , l _a , λ _a = r _a / l _a ) and the inner connecting rod pair 47 , 48 (r _i , l _i , λ _i = r _i / l _i ) is the same and the crank radii r _i and r _a are different in the reverse ratio of the inner and outer piston masses m _i and m _a , respectively. This measure results in an external equilibrium weight of the oscillating mass forces of all orders. The rotating masses can be compensated by removing material (holes) in the stroke eccentrics. The internal mass force effects remain in the cylinder plane and do not affect the bearing and housing in another cylinder plane. This means that multi-cylinder engines with any number of cylinders can be represented without further compensatory measures.

Summarizing the gas and mass forces acting periodically on the outer crank pin 18 , 20 and on the other crank pin 19 , 46 forces to a resultant, there is a particular advantage of the two-cylinder two-stroke counter-piston engine according to the invention, because in each Crankshaft position only loads the differential force of the two resultants on the bearings. This reduces friction and wear on the bearings. This positive effect increases with increasing engine speed.

The compensation measures described above make counterweights on the crankshaft 5 superfluous. By executing the cure belzapfen 18 and 20 as a stroke eccentric cheeks for mass balance are not required on the crankshaft 5 and there is space for the connection of the inner and outer Kol benpaares (piston pairs 14 , 16 and 15 , 17 ) in the area the cure belwelle 5 in the manner described above.

With the combination of the inside piston pair 15 , 17 into a double-acting piston unit, the lossy pumping of the air located under the piston head is eliminated.

The side force introduced via the crank pin 18 and 20 (stroke eccentric) is absorbed by the sliding sleeve 32 which is guided and lubricated in the bel housing 4 . The outer pistons 14 , 16 are thus free of side forces, which is why no lubrication is required in this regard.

Since a stroke division is caused by the interaction of the two pistons 14 , 15 and 16 , 17 , the average piston speed is also reduced. The reduced average piston speed and the favorable conditions for maintaining cylinder roundness, for example the uniform slot distribution and cylinder cooling, speak for an overall very low lubricating oil requirement for the two outer pistons 14 , 16 .

The gas and mass forces acting on the outer pistons 14 , 16 are always directed outwards. Therefore 32 connecting rods 35-38 can be used as connec tion elements between the outer pistons 14 , 16 and the sliding sleeve. The cross section of the train rods 35-38 is dimensioned as thin as possible so that et mis misalignments between the outer pistons 14 , 16 and the sliding sleeve 32 compensate for low friction.

The mass balance described above is slightly affected by the 180 ° offset of the crank angle α in the range of 160-180 ° (preferably 170-175 °) between the outer crank pin 18 , 20 and the inner crank pin 19 , 46 . The offset ensures that the outlet slots 12 , 13 are opened earlier and closed earlier than the inlet slots 10 , 11th As a result, the overlap phase, in which both inlet and outlet slots are open, is less, whereby the filling of the cylinder with fresh air is significantly improved ver.

In Fig. 3 is a section III-III of Fig. 2 normal to the Zylin derhochachse 40 and parallel to the axis of rotation 45 of the crank shaft 5 is shown. To the right of the main bearing 7 and to the left of the main bearing 6 of the crankshaft 5 the connecting rod attachment (connecting rod receptacles 43 , 44 ) of the connecting rods 33 and 34 on the sliding sleeve 32 can be seen. For the sake of clarity, the piston 15 is not shown in this section. The same components from FIGS . 1 and 2 are identified by the same reference numerals.

FIG. 4 shows an enlarged view of the pistons 15 and 17 from FIGS . 1 and 2 that are firmly connected to the connecting piece 49 and close to the crankshaft.

FIG. 5 shows a section VV of FIG. 2 normal to the cylinder vertical axis 40 and parallel to the axis of rotation 45 of the crankshaft 5 through the inlet channels E1 and inlet slots 10 .

In Fig. 6 is a section VI-VI of Fig. 2 normal to the cylinder derhochachse 40 and parallel to the axis of rotation 45 of the crank shaft 5 through the outlet channels A1 and outlet slots 12 of the inventive two-stroke counter-piston engine. The same construction parts from FIGS. 1 and 2 are marked with the same reference numerals.

In an embodiment of the invention, not shown with a single-cylinder two-stroke counter-piston engine with a short The cure is distant from the shaft and a piston near the crankshaft Pistons far from the shaft with a third piston via tie rods firmly connected, pre-compressible with the fresh air and this over a channel can be fed to the inlet slots.

Claims (7)

1. Two-stroke counter-piston engine, which comprises at least one cylinder with inlet and outlet slots and at least two oppositely co-operating pistons, which act via direct force flow elements on a common crankshaft, the crankshaft having at least three crank pins, of which the two outer crank pins are about Tie rods are connected to the piston remote from the crankshaft and the third crank pin is connected to the piston close to the crankshaft, characterized in that between the crankshaft remote piston ( 14 , 16 ) and the cure shaft ( 5 ) two connecting rods ( 33 ) connected to a sliding sleeve ( 32 ) , 34 ) are arranged, the sliding sleeve ( 32 ) on a slideway ( 39 ) of the motor housing ( 1 ) being displaceable parallel to the cylinder vertical axis ( 40 ) and connected via the tie rods ( 35-38 ) to the piston ( 14 , 16 ) remote from the crankshaft is. 2. Two-stroke counter-piston engine according to claim 1, characterized in that the tie rods ( 35-38 ) in the direction of the cylinder vertical axis ( 40 ) are arranged within the two outer crank pins ( 18 , 20 ). 3. two-stroke counter-piston engine according to claim 1 or 2, characterized in that the sliding sleeve ( 32 ) and the slideway ( 39 ) forms a sliding pairing, which consists of at least two opposite Zy cylinder jacket sectors ( 51 , 52 ) and in the direction of the Zy Linderhochachse ( 40 ) viewed between connecting rod receptacles ( 43, 44 ) of the sliding sleeve ( 32 ) is arranged. 4. two-stroke counter-piston engine according to one of claims 1 to 3, characterized in that each of the parallel to the cylinder vertical axis ( 40 ) extending tie rods ( 35-38 ) at least around the crankshaft radius (r) nor times to the crankshaft ( 5 ) spaced and in the direction the cylinder derhochachse ( 40 ) viewed between the connecting rod receptacles ( 43 , 44 ) of the sliding sleeve ( 32 ) are arranged. 5. Two-stroke counter-piston engine according to one of claims 1 to 4, characterized in that the tie rods ( 35 , 36 ) of the first remote crankshaft piston ( 14 ) and the tie rods ( 37 , 38 ) of the second remote crankshaft piston ( 16 ) on the sliding sleeve ( 32 ) are attached so that the two pistons ( 14 , 16 ) remote from the crankshaft are rigidly connected to one another. 6. Two-stroke counter-piston engine according to one of claims 1 to 5, characterized in that the two rigidly connected pistons ( 15 , 17 ) together with connec tion piece ( 49 ) are arranged within a sliding sleeve ( 32 ), the sliding sleeve ( 32 ) being parallel to a cylinder vertical axis ( 40 ) has cutouts ( 51 , 52 ) for free running the cure ( 19 , 46 ). 7. Two-stroke counter-piston engine according to one of claims 1 to 6, characterized in that between the two outer crank pins ( 18 , 20 ) two cure belzapfen ( 19 , 46 ) are arranged, both of which are connected to the near-crankshaft piston ( 17 ) , wherein the bearing width (B) of the two outer crank pins ( 18 , 20 ) and the two inner crank pins ( 19 , 46 ) is the same.