RU2580191C1 - Internal combustion engine - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: mechanism for changing piston stroke of internal combustion engine in each cycle of its operation comprises gearing with first gear wheel installed in engine housing without possibility of rotation, and second gear wheel with teeth formed on its inner surface, wherein second gear is engaged with first gear wheel to ensure constant length of crank and variable length cam to get variable length of piston stroke in full cycle of engine operation. Orientation of crank and eccentric relative to axis of piston reciprocation is set so that crank and eccentric together provide positive torque at crankshaft, when piston is at TDC. Also selectively set dimensions and location of gearing so that to ensure preset ratio of length of cam to length of crank.

EFFECT: high output torque, output power, fuel efficiency, power per unit volume and low level of harmful emissions.

1 cl, 13 dwg

Description

BACKGROUND OF THE INVENTION

[0001] The present invention relates generally to internal combustion engines, and more particularly to so-called variable piston engines, in which the mechanical connection between the reciprocating pistons and the engine crankshaft changes during the movement of the piston in the engine cycle . Typically, the goal of such mechanisms is to increase the efficiency of internal combustion engines by increasing the effective length of the crankshaft crank in the expansion stroke and reducing the effective length of the crankshaft in the suction stroke.

[0002] The operation of traditional internal combustion engines is based on a repeating sequence of piston movements (strokes): suction stroke, compression stroke, expansion stroke (stroke), and exhaust cycle. The indication "cycle" refers to the reciprocating movement of the piston as it moves back and forth in a cylindrical combustion chamber in the engine housing (cylinder block). Instead of indicating “stroke”, the indication “stroke of the piston” may also sometimes be used. Accordingly, an engine operating in the above manner is usually referred to as a four-stroke engine, indicating that in order to complete a full power cycle, the engine must make four reciprocating movements in the cylinder. The indication "cycle" is used to describe the complete duty cycle of the engine. The use of these terms corresponds to terminology well understood by specialists in this field of technology.

[0003] As already indicated, various designs have been proposed that provide movement of the engine piston at different distances in suction, compression, expansion and exhaust strokes, or combinations thereof, as well as for changing the speed of the piston on some part of its stroke. For example, the so-called top or bottom dead center of the piston is shifted up or down for each revolution or for every two revolutions. All of these conditions are various versions of a variable stroke engine. In patents US No. 1,326,129 (Ghadbourne) and US No. 4,044,629 (Clarke) describes an engine with an increased expansion stroke. The increased expansion stroke was put into practice in a Millenia car created by Mazda using a Miller cycle engine designed in 1947 by an American engineer Ralph Miller. Miller's engines were used for some time on ships and in stationary power plants. The purpose of this design is to reduce the degree of compression of the engine without compromising the performance of power in the expansion stroke. In an engine with a Miller cycle, the piston rises one fifth of its stroke before the intake valve closes. After combustion of the mixture occurring in the upper part of the piston stroke, expanding gases push the piston all the way to the lower point, so that the degree of expansion does not change.

[0004] In the first half of the twentieth century, it was widely believed among specialists in the field of internal combustion engines that combustion products should be removed from the cylinders as completely as possible in the exhaust stroke following the expansion stroke and preceding the next suction stroke. Many patents have proposed various methods for providing an increased output cycle. Such methods were proposed, for example, in US patent No. 1,326,733 (Hulse), US No. 2,394,269 (Svete), US No. 1,786,423 (Cady), US No. 1,964,096 (Tucker) and US No. 1,278,563 (Austin). US patents No. 1,326,129 (Ghadbourne) and US No. 4,044,629 (Clarke) also apply to engines with increased expansion and exhaust strokes. However, due to stringent emission standards introduced over the last decades of the last century, new engine designs have been proposed in which part of the exhaust gas is returned back or remains in the combustion chambers to reduce emissions of NO _x oxides resulting from nitrogen oxidation in the combustion chamber. To do this, a vacuum is created in the intake manifold to draw exhaust gas into the intake manifold through a valve of the exhaust gas recirculation system.

[0005] Other inventors have used variable piston designs to vary the compression ratio of an engine. Much work has been done, especially in Europe and Japan, to achieve a variable compression ratio using a mechanism that changes the position of the piston relative to the cylinder head.

[0006] The compression ratio is the ratio of the volume of the cylinder to the volume of the combustion chamber. In other words, the compression ratio determines how many times the air-fuel mixture is compressed, which enters the cylinder in the suction stroke. In general, the greater the compression ratio, the higher the engine efficiency. There are some limitations, such as pre-ignition of the mixture, detonation, engine temperature and even engine design. Since the compression ratio is one of the main factors determining the engine efficiency, it is desirable to optimize it for various operating parameters (speed, load, acceleration, etc.). US Pat. No. 5,165,368 (Schechter) describes a typical example of such an engine.

[0007] Variable stroke length designs have also been used to optimize the pressure acting on the piston. For this purpose, the piston speed is reduced, compared with the piston speed of a conventional engine, near the top dead center to ensure maximum efficiency of the combustion process and the maximum magnitude of the forces acting on the piston. US Patents No. 5,158,047 (Schaal et al.), US No. 5,060,603 (Williams), as well as US No. 3,686,972 (McWhorter); US No. 3,861,239 (McWhorter) and US No. 4,152,955 (McWhorter).

[0008] US Pat. No. 5,927,236, later issued, describes the design of an internal combustion engine that uses a gear mechanism to connect the crankshaft to the piston rod of the engine through offset bearing surfaces to change the stroke length of the piston in a full engine duty cycle. In particular, this design is aimed at increasing the piston stroke due to the increased effective length of the crank in the expansion stroke to increase the output torque, as well as to reduce the piston speed in the suction and exhaust strokes to increase the volumetric efficiency, which improves the heat efficiency in the engine.

SUMMARY OF THE INVENTION

[0009] By and large, the aim of the present invention is to further improve the above invention according to US patent No. 5,927,236.

[0010] More specifically, an object of the present invention is to further increase the output torque, power output, fuel efficiency, power per unit displacement, and reduce emissions of harmful substances from an internal combustion engine with a variable piston stroke mechanism according to US Pat. No. 5,927,236.

[0011] To achieve this goal, the present invention proposes an improved four-cycle internal combustion engine in which the piston reciprocates within the combustion chamber: in the suction stroke in the first direction, in the compression stroke in the second direction, expansion stroke - in the first direction and in the exhaust cycle - in the second direction. The position of the piston at the end of the compression stroke and at the beginning of the expansion stroke is defined as top dead center. The engine of the present invention comprises a housing forming at least one combustion chamber, a crankshaft rotatably mounted in the engine housing, a piston mounted inside the combustion chamber for reciprocating movement along the axis of the combustion chamber, and a connecting rod connected to the piston turning.

[0012] In accordance with the present invention, a mechanism for providing a variable piston stroke in an internal combustion engine uses a gear assembly to rotate the connecting rod to the crankshaft to convert the reciprocating motion of the piston into rotational motion of the crankshaft. The mechanical assembly comprises a gear including at least a first gear installed in the motor housing without rotation, and a second gear engaged with the first gear. The second gear wheel has a first bearing surface to which the connecting rod is connected, and a second bearing surface connected to the crankshaft for rotating the second gear wheel together with the crankshaft. The second supporting surface is offset from the axis of the crankshaft to move in a circular path around the axis of the crankshaft to ensure a constant length of the crank of the crankshaft in a four-cycle cycle of the engine. The first and second bearing surfaces are at a certain offset distance from each other, as a result of which the first bearing surface moves alternately along the internal and external elliptical trajectories around the crankshaft to provide a variable length of the eccentric on the crankshaft. Thus, the total length of the crank and eccentric is changed to change the length of the piston stroke in a four-stroke cycle of the engine.

[0013] In accordance with one embodiment of the invention, the inner and outer elliptical trajectories of the first abutment surface intersect at a point that is located on or near the axis of the combustion chamber, so that the crank and the eccentric together provide positive torque to the crankshaft while the piston is in top dead center. For example, in one embodiment, the inner and outer elliptical trajectories of the first abutment surface intersect at a point aligned with the axis of the combustion chamber. In another embodiment, the inner and outer elliptical trajectories of the first abutment surface intersect at a point at a predetermined angular distance, preferably not exceeding about twenty-five degrees, in front of the axis of the combustion chamber in the direction of rotation of the crankshaft, to ensure the position of the piston at the end of the exhaust cycle and at the beginning of the suction stroke at a predetermined distance below the top dead center, so that a predetermined amount of exhaust gas remains in the combustion chamber at the beginning of the suction stroke.

[0014] In accordance with another embodiment, such shapes and sizes of the first and second supporting surfaces of the second gear are selectively set to provide a predetermined ratio of the length of the eccentric to the length of the crank. Preferably, the length of the eccentric is at least about 20% of the length of the crank and can reach about 100% of the length of the crank.

[0015] According to another embodiment, the ratio of the length of the eccentric to the length of the crank is selected to provide a given working volume of the combustion chamber at the end of the suction stroke.

[0016] The first gear wheel can preferably be a pinion gear, and the second gear wheel can preferably have a crown with teeth formed on the surface of the circular case facing inward in the radial direction, for gearing with the pinion gear to rotate around it, as in planetary gear. The second gear also preferably has a support portion extending outward from the crown gear, with a first support surface formed on the outer surface of the support part and a second support surface formed on the inner surface of the support part. Thus, the connecting rod can rotate on the first supporting surface and the second supporting surface can rotate on the crankshaft.

[0017] The present invention can be adapted to substantially any internal combustion engine, and can preferably be applied to a multi-cylinder engine having a plurality of combustion chambers and a plurality of gears, the number of which is less than or equal to the number of combustion chambers.

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] Figure 1 is a perspective view of an improved internal combustion engine with a mechanical assembly (mechanism) to provide a variable piston stroke length in accordance with one preferred embodiment of the invention.

[0019] Figure 2 is a perspective view of a variable stroke stroke mechanism according to the embodiment of Figure 1.

[0020] Figure 3 is a schematic view of a partial section of an internal combustion engine and a variable piston stroke length mechanism shown in Figures 1 and 2.

[0021] Figure 4 is a second schematic view of a partial cross-section of a variable piston stroke length mechanism shown in Figure 3.

[0022] Figure 5 is a schematic views illustrating an expansion stroke of an internal combustion engine with a variable piston stroke mechanism in accordance with one preferred embodiment of the invention.

[0023] Figure 6 is a schematic views illustrating an exhaust stroke of an internal combustion engine in accordance with the embodiment of Figure 5.

[0024] Figure 7 is a schematic views illustrating a suction stroke of an internal combustion engine in accordance with the embodiment of Figure 5.

[0025] Figure 8 is a schematic views illustrating a compression stroke of an internal combustion engine in accordance with the embodiment of Figure 5.

[0026] Figure 9 is a schematic comparison of the embodiment of the invention shown in figures 5-8 with the invention of US patent No. 5,927,236.

[0027] Figure 10 is a schematic views similar to the views of figures 5-8, which shows another variant of the variable stroke length of the piston of an internal combustion engine of the present invention.

[0028] Figure 11 is a comparative graph of torque for an internal combustion engine with a variable stroke length mechanism of the present invention and for a conventional four stroke internal combustion engine.

[0029] Figure 12 is a diagram of the paths described by the ends of the eccentric and crank, in various embodiments of the variable stroke length mechanism of the piston of the present invention, which use different preset ratios of the length of the eccentric to the length of the crank.

[0030] Figure 13 is a table of comparative data for different preset ratios of the length of the eccentric to the length of the crank in one embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0031] As shown in the accompanying drawings, primarily in Figures 1-4, the improved internal combustion engine according to one of the preferred embodiments of the invention is indicated generally by the reference numeral 10 and the engine housing is indicated by the reference number 12. It should be borne in mind that the housing 12 the engine is shown only partially and schematically as a support for the mechanical assembly of the present invention. In addition, to simplify the description below, an engine having only two cylinders is considered. However, it will be understood by those skilled in the art that the mechanism of the present invention can be adapted to different engine configurations with different number of cylinders.

[0032] The crankshaft 16 used in conventional engines has a bearing surface 17 at its junction with the engine housing 12. On the bearing surface 17 sits a bearing cap 19, having a vaulted shape, with two holes for bolts and with an arcuate bearing surface 21 in its lower part, and the bearing cover 19 is attached to the motor housing 12 using conventional bolts that pass through the holes in the housing 12 and through the corresponding holes in the bearing cap 19, as a result of which the crankshaft 16 is locked in position.

[0033] The engine housing has inside two cylindrical grooves 14 (figures 3 and 4) with conventional pistons 22 mounted in the cylinders for reciprocating motion. Two identical conventional connecting rods 24 are rotatably connected to the pistons 22 and also connected to the crankshaft 16 through the mechanical assembly of the present invention, as will be described in detail below. Conventional bearing caps 26 are attached to the cranks 24 to hold them rotatably connected to the crankshaft 16. As will be described in detail below, the connecting rods 24 are not attached directly to the crankshaft 16, but to the supporting surface of the mechanism of the present invention.

[0034] The mechanical assembly of the present invention comprises a gear 30 attached to the crankshaft 16 for connecting to each piston-connecting rod assembly, so that the gears 30 form the main drive portion of the present invention. Each gear 30 includes a first gear 32, preferably in the form of a pinion gear, which is engaged with the second gear 36, preferably in the form of a ring gear. For balancing purposes, eccentric counterweights 20 are attached to the crankshaft, as is usually done in a two-cylinder engine. Two gears 30 are designed as mirror images of each other and essentially divide the engine 10 into two mirror symmetric halves with gears 30 in the middle.

[0035] In figure 2, the first gear 32 is shown in a preferred form of a pinion gear having a cylindrical housing with a series of teeth 34 formed on its circular surface. The second gear wheel 36 is shown in a preferred form of a ring gear having a cup-shaped cylindrical body 37, on the inner circular surface of which a series of teeth 38 is formed. The two first gears 32 are separated from each other by a cylindrical support element 35 to which they are attached and which, in its in turn, is attached to the motor housing by a clamping member 33, as shown in FIG. 1. Each first gear 32 is fixed inside the motor housing so that it cannot rotate. The teeth of the second gear 36 are engaged with the teeth of the first gear 32 in such a way that the second gear 36 can rotate while moving relative to the first gear 32, as in a planetary gear.

[0036] Figures 3 and 4 show a more detailed schematic representation of the mechanism of the present invention. As in the previous figures, the engine casing is shown only partially and schematically and indicated generally by reference numeral 12, with figures 3 and 4 showing only one cylinder 14 in which the piston 22 can move.

[0037] The second gear wheel 36 has a support member 48 in the form of an annular hub extending longitudinally outward from the outside of the cup-shaped housing 37, the support member 48 being offset linearly away from the inner teeth 38. The support member 48 has a first outer circular supporting surface 40 formed around the outer surface of the support member on which the connecting rod 24 is rotatably mounted, and a second inner support surface 42 formed around the pivoting radially inward direction features of the supporting element 48. The inner supporting surface 42 has the shape of a cylinder, described around a common central axis with a bowl-shaped cylindrical body 37. The outer supporting surface 40 also has the shape of a cylinder, but its axis is offset from the cylinder axis of the inner supporting surface 42 and the housing 37, resulting of which the housing of the support element 48 has an enlarged part 44, offset in the radial direction, between the supporting surfaces 40, 42. Thus, the maximum value 46 of the offset, which is described detail below. The support member 48 forming the support surfaces 40, 42 may be integrally formed with the gear 36, however this is not a requirement. The only requirement: the support element 48 must rotate as a unit with the gear 36, and the formation of these elements as a whole is the simplest way to fulfill this requirement.

[0038] As will be understood from the following description with reference to figures 3 and 4, the mechanical assembly of the present invention has three axis of rotation. The crankshaft 16 rotates around the axis 70 of the crankshaft, which, as can be seen in figures 3 and 4, coincides with the geometric axis of the first gear 32, that is, the axis around which the gear 32 would rotate if its fastening in the engine housing provided the possibility of free rotation. The first gear wheel 32 is installed with the possibility of adjusting its position (within a few degrees) relative to the axis 70 of the crankshaft. The second gear wheel 36, including its integral part, the supporting element 48, rotates around an axis 72 parallel to the axis of the crankshaft 70, but offset relative to it by a predetermined distance 50. Such an offset 50 is used in each internal combustion engine containing a crankshaft with cranks, having a constant length by which the reciprocating movement of the pistons is converted into rotation of the crankshaft. Due to the eccentricity of the support surface 40, the connecting rod 24 rotates around a separate axis 74, which also runs parallel to the crankshaft axis 70 and the offset axis 72. The distance between the offset axis 72 and the connecting rod axis 74 determines the maximum offset distance 46, which determines the variable length eccentric acting on the crankshaft the shaft 16. Thus, the maximum offset distance 46 together with the offset 50 of the crankshaft determines the total effective length of the crank, which, as will be described in detail below, varies with otvetstvii with the change of length of the eccentric (eccentric portion of the support member 48) in the working cycle of the engine.

[0039] Those skilled in the art will understand that an engine is described herein without indicating a valve system, a cooling system, an ignition system, and corresponding structural components that form a fully operational internal combustion engine. The engine, of course, must include all of these systems and components, but they are no different from conventional systems and components used in a conventional internal combustion engine. Thus, these components are optional for the purpose of understanding the essence of the present invention, and therefore are not considered here so as not to clutter up the description. Any suitable valve system, cooling system, ignition system, and corresponding structural components may be used with the mechanism of the present invention, and it should be noted that the present invention can be adapted to virtually any standard crankshaft internal combustion engine.

[0040] As in traditional internal combustion engines, the explosive combustion of the air-fuel mixture in the part of the combustion chamber of the cylinder 14 located above the piston 22 causes it to move downward, as a result of which the crankshaft 16 rotates. In multi-cylinder engines, several cylinder-piston pairs are used, in which in a given sequence there is explosive combustion of the air-fuel mixture for smooth rotation of the crankshaft. As a rule, the more cylinders, the higher the smoothness of the engine. Although the present invention is illustrated by the example of a two-cylinder engine, it can be fully adapted to engines having almost any number of cylinders. The present invention can equally be adapted to spark ignition engines, diesel engines and other compression ignition engines, as well as radial engines.

[0041] An improvement proposed in the present invention is to vary the effective stroke length, that is, the stroke length of the piston, during the entire engine operating cycle. The engine of the present invention operates according to a modified Atkinson cycle, in which the full cycle of the engine is formed by four separate cycles: suction or intake cycle; compression stroke; expansion beat or working beat; and exhaust cycle. In the suction stroke of a specific cylinder, the corresponding cylinder inlet valves are open, while the piston moves downward with a rotating crankshaft, as a result of which the air-fuel mixture is sucked into the combustion chamber. During the compression stroke, the intake valves are closed, while the piston moves upward to compress the air-fuel mixture in the combustion chamber to a certain degree of compression, and at a given point in time, the mixture ignites, for example, using a spark plug connected to the cylinder, resulting in begins the expansion stroke, in which the piston moves down under the action of gases generated during the combustion of the mixture. At the end of the expansion stroke, the exhaust valves of this cylinder open and the piston begins to move upward in the cylinder to carry out the exhaust cycle, during which the piston pushes the exhaust gases from the combustion chamber of the cylinder through the exhaust valves, preparing the cylinder for the next four-stroke cycle of the engine. The piston stroke length is defined as the distance that the piston travels in the combustion chamber in each of the four clock strokes of the engine. In a traditional internal combustion engine, the piston stroke length is fixed and the same for all four clock cycles of the engine.

[0042] A feature of the present invention is to provide a variable piston stroke length. Since the teeth of the second gear 36 are formed on its inner surface, it rotates, moving relative to the first gear 32 (as in a planetary gear), in the same direction in which the crankshaft 16 rotates. The number of teeth of the first 32 and second 36 gears is selected so that a gear ratio of 1: 2 is ensured, as a result of which the support element 48 and, accordingly, its displaced part 44 (eccentric) with a maximum displacement of 46, is rotated half a revolution for each crankshaft revolution th shaft 16. Figures 5-8 show the corresponding kinematic schemes which are illustrated in separate strokes of the engine cycle.

[0043] In each of figures 5-8, schematically sequential positions of the piston 22 and the corresponding gear mechanical assembly of the present invention connecting the piston 22 through the connecting rod 24 with the crankshaft 16 are shown during the expansion stroke (stroke), the exhaust cycle, suction stroke and compression stroke. In each of figures 5-8, the corresponding measure is shown in the initial position, intermediate position and end position (indicated by the reference signs A, B, C ...), and the end position for each measure also represents the starting position of the next measure indicated by the same letter designation . Thus, the mechanical assembly in the expansion stroke (stroke) is shown schematically in FIG. 5 with the initial position of the piston 22 (usually indicated as “top dead center”), the indicated reference symbol A, the intermediate position indicated by the reference symbol B, and the end position, the indicated reference symbol C. The figure 6 illustrates the initial, intermediate and final positions of the mechanical assembly indicated by the reference symbols C, D and E, respectively, for the exhaust cycle, which follows an act of expansion. The figure 7 illustrates the initial, intermediate and final positions of the mechanical assembly indicated by the reference designations E, F and G, respectively, for the suction stroke that follows the exhaust stroke. The figure 8 illustrates the initial, intermediate and final position of the node indicated by the reference signs G, H and A, respectively, for the compression stroke, which follows the suction stroke.

[0044] In figures 5-8, the longitudinal central axis of the cylinder 14 of the engine housing 12, along which the reciprocating movement of the piston 22 is carried out, is indicated by a reference numeral 102 and the axis of rotation of the crankshaft 16 is indicated by a reference numeral 70. The connection point of the support member 48 and the connecting rod 24 coinciding with the axis 74 is indicated in the diagram by the reference designator 52, and the connection point offset from it of the support element 48 and the crankshaft 16, coinciding with the axis 72, is indicated in the diagram by the reference designation 54, and the distance between The joint offset point 52, 54 represents the maximum displacement 46. The crankshaft crank 16, indicated by 50, extends between the crankshaft axis 70 and the connection point 54 between the support member 48 and the crankshaft 16, and a variable length eccentric determined by the maximum displacement 46, passes between the connection point 52 between the connecting rod 24 and the support member 48 and the connection point 54 between the support element 48 and the crankshaft 16. During the rotation of the crankshaft around axis 70, the connection point 54 between the bearings m element and the crankshaft describes a circular path 56, which runs concentrically with the axis 70 of the crankshaft. Due to the distance between the axles 72 and 74, equal to the offset 46, the connection point 52 between the connecting rod and the eccentric of the support element 48 describes alternately two separate elliptical trajectories, an external elliptical trajectory 58 and an internal elliptical trajectory 60.

[0045] As will be further understood from the description, if it were not for the mechanical gear assembly of the present invention, the connecting rod 25 would be connected to the crankshaft 16 at point 54, as in a conventional internal combustion engine. Instead, as shown in figure 5, the eccentric, characterized by a maximum displacement of 46, and the crank of the crankshaft, characterized by a displacement of 50 in the proposed gear assembly together effectively increase the stroke length of the piston 22 after ignition of the air-fuel mixture, when the piston 22 in the expansion stroke passes through the intermediate position B to the end position C. In particular, in the expansion stroke, the connection point 52 between the support member 48 and the connecting rod 24 passes along its external eccentric path 58, where the components of the gear assembly go through position B and then to position C, as shown in figure 5, the crankshaft 16 is rotated half a turn, while the length of the eccentric, characterized by a maximum displacement of 46, is folded with a length of 50 crank to increase the effective piston stroke length so that the expansion stroke ends with the maximum total effective crank length. The increase in the effective piston stroke length provides an increase in the work performed by the engine 10 in the expansion stroke. At this point in time, the exhaust cycle begins.

[0046] Figure 6 shows the positions C, D, and E of the piston in a subsequent exhaust cycle, at which the connection point 54 of the crankshaft 16 with the support member 48 extends near the connection point 52 of the eccentric support element 48 with the connecting rod when these points 52, 54 pass along their respective trajectories, so that at the end of the exhaust stroke, the relative position of points 52, 54 essentially changes to the opposite position from the initial position A in the expansion stroke (figure 5), resulting in a full piston stroke length in the exhaust stroke ska is essentially equal to the total length of the stroke of the piston in the expansion stroke. At the end of the stroke, the piston completely removes gaseous and other combustion products from the combustion chamber.

[0047] FIG. 7 illustrates a suction stroke in which the piston delivers air-fuel mixture into the cylinder starting from the end position E of the exhaust stroke in FIG. 6. In this part of the duty cycle, the connection point 52 of the eccentric of the support member 48 with the connecting rod describes its internal trajectory 60, as a result of which the effective piston stroke is gradually reduced as the assembly moves through position F to position G to complete the suction stroke, and the effective piston stroke is reduced to min minimal length equal to the length of the crank 50 minus the maximum displacement 46. During the transition from the rest position E to the target position G in Figure 7, the crankshaft is rotated by a half turn. As a result of the reduction in the effective piston stroke length in the suction stroke, the amount of work that the engine must perform when the piston is retracted to suck the air-fuel mixture into the combustion chamber 14 is accordingly reduced and the fuel consumption is proportionally reduced. The speed with which the piston 22 moves downward in the suction stroke is proportionally less than its speed in previous exhaust expansion and exhaust cycles.

[0048] Figure 8 illustrates the next compression stroke starting at position G (end of the suction stroke). When the node moves through the intermediate position H and returns to its initial position A to start the next expansion stroke, the connection point 52 of the eccentric of the element 48 with the connecting rod ends its movement along the internal path 60 and will again move along the external path 58.

[0049] The present invention provides several improvements over US Pat. No. 5,927,236. In accordance with one aspect of the present invention, the gear 30 is positioned so that the connection between the support member 48 of the second gear 36 and the connecting rod 24 forms the outer 58 and inner 60 elliptical trajectories traversed by the connection point 52 (i.e., the connecting rod axis 74 74 ), so that they intersect at a point lying on the axis 102 of the combustion chamber or directly near it, as a result of which the crank and the eccentric together create a positive torque on the crankshaft when the piston is located at top dead center. In particular, figures 5-8 illustrate an embodiment of the invention in which the intersection of the outer 58 and inner 60 elliptical trajectories is on the axis 102 of the cylinder / combustion chamber. In contrast to this embodiment, as shown in FIG. 9, in the preferred embodiment described in US Pat. No. 5,927,236, the intersection of the outer 58 and inner 60 trajectories is in front of the axis of the cylinder 102, ninety degrees ahead of you when viewed relative to the direction of rotation of the crankshaft.

[0050] The beneficial effect of the modified orientation of the mechanical assembly of the present invention is to provide an increased length of the crank arm acting on the piston at its top dead center, compared with the preferred embodiment of US Pat. No. 5,927,236, as shown for comparison in Figure 9, as a result, the crank arm and, accordingly, the crankshaft torque are proportionally increased in the entire four-stroke cycle of the engine. The increase in the crank arm is especially noticeable when compared with a conventional engine that does not use any variable piston stroke device, as illustrated in the graph of figure 11. Figure 11 shows a graph 104 of the dependence of the length of the crank arm, measured in millimeters, which is formed in a four-cylinder engine with a displacement of 1000 cubic meters. see when applying the present invention, from the angle of rotation of the crankshaft of the engine for four cycles of the duty cycle, and for comparison, a graph 106 of the length of the crank arm, which is formed in a four-cylinder engine with a displacement of 1000 cubic meters. see, in which the connecting rods are connected directly to the crankshaft without using any mechanical devices to change the length of the stroke of the piston.

[0051] Graph 106 shows that conventional engines are characterized by a significant amount of negative torque acting on the crankshaft in the compression stroke, approaching the expansion stroke, which usually requires an ignition spark to be provided in the combustion chamber about thirty-five degrees to the top dead point. In such an engine, the piston must do a negative job to overcome the negative torque that will remain in effect until the zero point at top dead center is reached, and there will be no significant positive torque up to about sixty degrees after the top dead center. This is the main reason why traditional internal combustion engines are not able to run at idle speeds that would be below 800 rpm. On the contrary, using the device of the present invention, in which the intersection of the outer 58 and inner 60 elliptical trajectories described by the connection point 52 (axis 74 for the connecting rod 24) lies on the axis 102 of the combustion chamber or is located directly next to it, the increased crank arm provides positive torque the moment that increases from the position of the piston at thirty-five degrees ahead of the top dead center to this very point and sixteen degrees after it, and the torque created by the engine The field in which the present invention is used is more than twice the torque of a conventional engine.

[0052] As shown in FIG. 10, alternative embodiments of the present invention are possible in which the intersection of the outer 58 and inner 60 elliptical trajectories is within about twenty-five degrees from the axis of the combustion chamber. In particular, figure 10 shows an alternative embodiment in which the mechanical assembly of the present invention is configured such that the intersection of the outer 58 and inner 60 elliptical trajectories is at a point located at a predetermined angular distance not exceeding approximately twenty-five degrees in front of the camera axis combustion when viewed in the direction of rotation of the crankshaft. The designation A ″ in figure 10 indicates the position of the piston and other associated mechanical components of the present invention in the initial position of the expansion stroke, that is, at top dead center, and as you can see, the proposed device still provides a significantly increased crank arm acting on the piston in this position, compared with the device according to US patent No. 5,927,236. In addition, an additional advantage of the mechanism proposed in the present invention is that the position of the piston at the end of the exhaust cycle and at the beginning of the suction stroke will be at a predetermined distance below the top dead center, as indicated by the designation E ′ in figure 10. Thus , the specified orientation of the mechanism allows you to stay in the combustion chamber for a given volume of exhaust gases at the beginning of the suction stroke, which, in turn, reduces the level of emissions of harmful substances from the engine.

[0053] It has also been found that a predetermined change in the ratio of the length of the eccentric to the length 50 of the crank provides a working volume in the combustion chamber at the end of the suction stroke and thus the corresponding compression ratio can be selectively changed. For example, it is contemplated that the length of the eccentric may vary from at least about 20% to about 100% of the length of the crank. Such changes can be made by changing the sizes and offsets from the center of the outer 40 and inner 42 of the supporting surfaces of the support element 48 to obtain different specified lengths 50 of the crank and 46 of the eccentric. Figure 12 illustrates the relative changes and relative differences obtained for the different sizes and shapes of the outer 58 and inner 60 elliptical trajectories described by the connection point 52 (i.e., axis 74 for the connecting rod 24) when changing the ratio of the length of the eccentric to the length of the crank in steps of 20% . The table in figure 13 contains comparative data for the corresponding variables, the values of which are affected by such changes. The data shown in the table of figure 13, obtained for an engine with a displacement of 1000 cubic meters. cm, that is, with a fixed suction stroke of 1000 cubic meters. cm and with a fixed compression ratio of 10: 1 for an engine with spark ignition or with a fixed compression ratio of 15: 1 for an engine in which the mixture ignites as a result of compression. In general, according to the data in the table, it can be concluded that an increase in the ratio of the length of the eccentric to the length of the crank provides a significant improvement in the characteristics of fuel consumption (miles / gallon) and torque compared to conventional engines with a working volume of 1000 cubic meters. see. For example, when the ratio of the length of the eccentric to the length of the crank is about 70% in such an engine with a displacement of 1000 cubic meters. cm volume of 1739 cubic meters is provided. cm in the expansion stroke and an expansion ratio of 16.7: 1 is achieved with a compression ratio of 10: 1. In fact, such an engine with a displacement of 1000 cubic meters. cm, which uses the present invention, will provide torque and power output like a conventional engine with a displacement of 1739 cubic meters. cm, however, it will consume the same amount of fuel as a conventional engine with a displacement of 1000 cubic meters. cm.

[0054] Thus, it will be clear to those skilled in the art that the present invention can find the widest application. In addition to the options discussed in the present description, specialists in this field of technology after reading the present invention will be apparent many of their modifications and other options, as well as many changes and equivalents of these options without going beyond the essence and scope of the present invention. Accordingly, while the present invention has been considered in the present description in relation to a preferred embodiment, it should be understood that the description is only an illustration of the invention and the considered embodiment is provided only for a complete disclosure of the invention. The above description should not be construed as limiting the scope of the present invention or otherwise excluding any other variations, modifications, enhancements or equivalents. The present invention is limited only by the attached claims and their equivalents.

Claims (1)

An internal combustion engine comprising:
an engine housing forming a plurality of cylindrical combustion chambers, each of which defines an axis of the combustion chamber;
a crankshaft installed in the engine casing for rotation about the axis of the crankshaft extending in the transverse direction relative to the combustion chambers;
a piston mounted inside each combustion chamber for reciprocating movement along the axis of the combustion chamber,
moreover, the internal combustion engine can operate in a four-cycle cycle in which the piston reciprocates inside the combustion chamber: in the suction stroke in the first direction, in the compression stroke in the second direction, in the expansion stroke in the first direction and in the exhaust cycle gases in the second direction, and the position of the piston at the end of the compression stroke and at the beginning of the expansion stroke is defined as top dead center, the position of the piston at the end of the expansion stroke and at the beginning of the exhaust cycle It is defined as the lower dead point;
a connecting rod connected to the piston with the possibility of rotation relative to it;
a mechanical assembly connecting the connecting rod to the crankshaft for rotation to convert the reciprocating motion of the piston into rotational motion of the crankshaft, the mechanical assembly comprising:
the first gear mounted in the motor housing without rotation, which contains:
a cylindrical body with a drive gear having teeth formed over a surface of the cylindrical body facing outward in the radial direction; and
a second gear engaged with the first gear and containing:
an annular housing with a crown gear having teeth formed on a surface of the annular housing facing inward in the radial direction, the cylindrical housing of the first gear being included inside the annular housing to engage the teeth of the pinion gear with the teeth of the crown gear, and
a support portion extending outward from the crown gear portion with a first support surface formed on the outer surface of the support portion, and
a second supporting surface formed on the inner surface of the supporting part, the connecting rod mounted on the first supporting surface and the crankshaft installed inside the second supporting surface for rotating the second gear with the crankshaft, the connecting rod rotating on the first supporting surface and the second supporting surface rotating on the crankshaft shaft
moreover, the gear ratio of the driving gear of the first gear and the crown gear of the second gear is 2: 1, so that the second gear makes one revolution for every two revolutions of the crankshaft,
the second supporting surface is offset from the axis of the crankshaft to move in a circular path around the axis of the crankshaft to provide a crank of the crankshaft, the length of which is constant in the four-cycle cycle of the engine,
the first and second bearing surfaces are at a certain offset distance from each other, so that the first supporting surface moves alternately along the internal and external elliptical trajectories around the crankshaft to provide an eccentric on the crankshaft, the length of which changes in a four-stroke cycle of the engine,
moreover, the rotation of the second gear wheel together with the crankshaft ensures the formation of a composite crank equivalent to the vector sum of the crank and the eccentric, which constantly changes in the four-stroke cycle of the engine, as a result of which the length of the reciprocating piston in this cycle changes,
characterized in that in order to improve its performance, the dimensions and shapes of the first and second supporting surfaces of the second gear wheel are selectively set as follows:
cam length is in the range from 20% to 100% of the crank length,
the cam is oriented at top dead center as a whole at an angle of 90 degrees to the crank,
the crank is oriented at top dead center at a certain angle in front of the axis of the combustion chamber,
the crank and the eccentric together provide positive torque on the crankshaft from about 20 degrees to the end of the compression stroke and then going through the top dead center in the expansion stroke,
at the end of the expansion stroke, the crank and the eccentric pass along the same line,
combined with the axis of the combustion chamber, and the cam moves outward from the crank to form a composite crank of the greatest length in a four-stroke cycle of the engine,
at the end of the suction stroke, the crank and the eccentric follow a single line aligned with the axis of the combustion chamber, and the cam moves inward, overlapping the crank to form a composite crank of minimum length in a four-stroke cycle of the engine,
the piston strokes in the suction and compression strokes in the four-stroke cycle of the internal combustion engine are shorter than the piston strokes in the expansion and exhaust strokes, and
a substantially constant compression ratio is maintained throughout the four-stroke cycle of the internal combustion engine.

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