RU64287U1 - WUA SINUSOID ROTOR ENGINE - Google Patents

Abstract

The utility model relates to mechanical engineering, in particular, to internal combustion engines (ICE) and machines containing a cylinder-piston group. In an engine with a sinusoidal rotor, comprising a housing in which cylinders are located, each having a combustion chamber with or without a spark plug and supply and discharge channels of working gases, pistons are installed in the cylinders, on the rods of which are mounted gears on rolling bearings that interact with the gear surface of a sinusoidal rotor mounted on the main shaft of the engine. The axis of the cylinders can be perpendicular or parallel to the axis of the sinusoidal rotor. In the first case, the gear surface may be located on the outside of the rotor or on the inside of the rotor. A sinusoidal rotor may have three or more upper and lower dead center points. Rolling bearings are mounted on the outer side surface of each piston with the possibility of preloading them against the inner surface of the cylinder. Moreover, the bearings are split and pressed to the inner surface of the cylinder by heat-expanding rods. The sinusoidal rotor has an annular protrusion, on the one side of which the indicated gear surface is located, and on the opposite side is a smooth surface that repeats the sinusoidal profile of the envelope of the gear surface, and the piston rod of each piston is connected to a roller interacting with this smooth surface and spring-loaded towards the stem to compress the rod piston to the rotor body. The technical result obtained from the implementation of the proposed solution is to reduce the lateral loads of the pistons on the cylinder walls, to reduce the friction coefficient, by reducing the number of sliding bearings, in increasing the number of piston working cycles per revolution of the main engine shaft and in increasing the reliability of the design.

Description

The utility model relates to mechanical engineering, in particular, to internal combustion engines (ICE) and machines containing a cylinder-piston group.

Widely known ICE with a crank mechanism (KShM).

Also known is a rotary internal combustion engine, comprising a housing mounted rotatably in the housing, rotors arranged in the rotor body, pistons provided with rods in the cylinders, a working fluid supply system, an ignition system and an exhaust system (French Patent No. 2126632 CL F01C 7/00, 1972).

Closest to the proposed one is a rotary internal combustion engine, made in the form of a housing inside which a rotating rotor is installed, in the body of the rotor in the radial direction there are cylinders with pistons, the fingers of which are fixed in a profiled groove made on the periphery of the stop, made in the form of an ellipse and installed inside the rotor. The housing is equipped with openings and channels for supplying and discharging working gas, as well as an ignition chamber with spark plugs (RF Patent No. 2044140. C1, F02B 55/00, publ. 1995).

The disadvantages of these known engines are:

a) not compensated for the magnitude and direction of the lateral loads of the pistons on the cylinder walls,

b) low reliability

c) a large number of bearings

d) a small number of piston strokes per revolution of the rotor or crankshaft of the crankshaft.

The technical problem, which PM is aimed at, is as follows: reducing the lateral loads of the pistons on the cylinder walls, reducing the friction coefficient, by reducing the number of sliding bearings, increasing the number of piston working strokes per revolution of the main shaft, eliminating KShM from the design and increasing reliability designs.

This problem is solved in that in an engine with a sinusoidal rotor containing a housing in which are cylinders having each combustion chamber with or without an ignition plug and supply and discharge channels of working gases, pistons are installed in the cylinders, on the rods of which gears are mounted on bearings rolling, which interact with the toothed surface of a sinusoidal rotor mounted on the main shaft of the engine.

The axis of the cylinders can be perpendicular or parallel to the axis of the sinusoidal rotor.

In the first case, the gear surface may be located on the outside of the rotor or on the inside of the rotor.

A sinusoidal rotor may have three or more upper and lower dead center points.

Rolling bearings are mounted on the outer side surface of each piston with the possibility of preloading them against the inner surface of the cylinder. Moreover, the bearings are split and pressed to the inner surface of the cylinder by heat-expanding rods.

The sinusoidal rotor has an annular protrusion, on the one side of which the specified gear surface is located, and on the opposite side is a smooth surface that repeats the sinusoidal profile of the envelope of the gear surface, and the piston rod of each piston is connected to a roller interacting with this smooth surface and spring-loaded to it and towards the stem to press the piston rod against the rotor body.

Figure 1, shows a diagram of a four-cylinder internal combustion engine with a sinusoidal rotor and external gear and smooth working surfaces, where

the pistons are located outside the rotor, and the axis of the pistons is perpendicular to the axis of rotation of the rotor, with four TDC and BDC, which allows each of the four cylinders to make two working strokes in one revolution of the rotor.

Figure 2 shows a diagram of a six-cylinder internal combustion engine with a sinusoidal rotor with internal gear and smooth working surfaces, where the pistons are located inside the hollow rotor, and the piston axis is perpendicular to the axis of rotation of the rotor, with six TDC and BDC, which allows each of the six cylinders for one revolution of the rotor make three working strokes.

Figure 3 shows a diagram of the interaction of the gear working surface of a sinusoidal rotor with a piston, in the case when the axis of the pistons are parallel to the axis of rotation of the rotor.

Figure 4 shows the piston with a fragment of the rod and two split stabilizing ball bearings.

Figure 5 shows a section aa of figure 4: the cross section of the piston rod without fragments of the piston body.

In Fig.6 shows a section bB of Fig.1: the cross section of the connection of the piston rod with the gear and the rotor using a spring-loaded spherical roller, which interact with the gear and smooth surfaces of the sinusoidal rotor.

Table 1 shows the cycle of the four-cylinder internal combustion engine for one revolution of the sinusoidal rotor, where: RT - working cycle, SB - discharge of exhaust gases, PD - air or air-fuel mixture, SJ - compression.

Table 2 shows the operation cycle of a six-cylinder internal combustion engine per revolution of a sinusoidal rotor.

A sinusoidal rotor in this application is understood to mean such a rotor, the working surface of which (in this case, the surface enveloping the teeth on the working gear surface of the rotor) in a section perpendicular to the axis of the rotor has a convex-concave line in the form of a sinusoid, the middle line of which is curved around the circumference.

The WUA sinusoidal rotor engine (FIGS. 1, 2) comprises a housing 1, in the body of which cylinders 2 with pistons 3 are radially arranged, on the rods 4 of which gears 5 rotate on rolling bearings, are mounted on the pistons body 3, stabilizing split ball bearings 6 are located, which are pressed to the cylinders 2 by heat-expanding rods 7. Also on the body of the pistons 3 are compression rings 8 and a little-removable ring 9. The body of the piston 3 has an internal cavity. Through holes 10 in the body of the piston 3 and holes 11 in the body of the rod 4, the body of the piston 3 is cooled and the mirror of the cylinder 2 is lubricated with vapor-droplet grease 12. The piston rod 4 has a reinforced polyhedral lower part 13, as well as two flanges 14 fixed in the body piston 3. Flanges 14 have circumferential openings 15, which serve to better connect the piston 3 to the rod 4. On the main shaft 20 of the engine, a rotor 16 is fixed, which has a gear 17 and smooth working surfaces 18 having a profile in the form of a sinusoid 19. 4 stem connection the piston 3 with the body of the sinusoidal rotor 16 is carried out by a springy plate 21, which is mounted on a reinforced lower part 13 of the rod 4 and has two axles 22 on which the gear 5 rotates along the gear surface 17, and a spherical roller 23 on rolling bearings having a smooth surface 24, pressing the rod 4 against the body of the rotor 16, working on the smooth surface 18 of the rotor 16, the profile of which in axial section repeats the profile of the roller 23. The sinusoidal rotor 16 has top 25 (TDC) and bottom 26 (BDC) dead points. The cylinders 2 have a combustion chamber with channels 27 for supplying and discharging working gases.

The engine operates as follows: the operating cycle starts below TDC 25 of the sinusoidal rotor 16 and ends at BDC 26, where the discharge of exhaust gases through channels 27 begins until the next TDC. Then, until the next BDC, air or air-fuel mixture is supplied through channels 27 to the BDC. In the subsequent movement to TDC, a compression stroke occurs. In the combustion chamber of cylinder 2 occurs

ignition of the fuel mixture, the working gas pushes the piston 3 in the direction of the rotor 3, but since its rod 4 with gear 5 cannot move in this direction due to the profile of the sinusoidal rotor 16, the rod 4 by means of gear 5 moves along the gear surface 17, rotating the rotor 16, located on the main shaft 20. Thus, each piston 3. Thus, the working cycle occurs alternately in each cylinder 2. The number of working cycles of each piston 3 for one revolution of the rotor 16 depends on the total number of TDC and BDC of the sinusoidal rotor 16, which confirms given by tables 1 and 2.

Claims (9)

1. An engine with a sinusoidal rotor, comprising a housing in which cylinders are located, each having a combustion chamber and channels for supplying and discharging working gases, pistons are installed in the cylinders, the rods of which have gears mounted on rolling bearings, which interact with the gear surface of the sinusoidal rotor fixed on the main motor shaft. 2. The engine according to claim 1, characterized in that the axis of the cylinders are perpendicular to the axis of the sinusoidal rotor. 3. The engine according to claim 2, characterized in that the gear surface is located on the outside of the rotor. 4. The engine according to claim 2, characterized in that the gear surface is located on the inside of the rotor. 5. The engine according to claim 1, characterized in that the axis of the cylinders are parallel to the axis of the sinusoidal rotor. 6. The engine according to claim 1, characterized in that the sinusoidal rotor has three or more upper and lower dead points. 7. The engine according to claim 1, characterized in that on the external lateral surface of each piston installed rolling bearings with the possibility of their preload to the inner surface of the cylinder. 8. The engine according to claim 7, characterized in that the bearings are split and pressed against the inner surface of the cylinder by heat-expanding rods. 9. The engine according to claim 1, characterized in that the sinusoidal rotor has an annular protrusion, on the one side of which the specified gear surface is located, and on the opposite side is a smooth surface that repeats the sinusoidal profile of the envelope of the gear surface, and the piston rod of each piston is connected to a roller interacting with this smooth surface and spring-loaded towards it and toward the stem.