RU2647751C1 - Rotary piston internal combustion engine - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to motor industry, particularly to rotor-piston internal combustion engines. Engine contains working cavities in which rotor 1 of the compressor in form of a disk is installed, in the groove of which spring-loaded damper 7 is installed, rotor 2 of a turbine in form of a bowl with a fixed bottom on shaft 3, inlet and outlet valve 12 and 13, combustion chamber 11. Jar has a thickening of a width equal to rotor width 1 on the inner surface of the jar above chamber 11 located in the widest part of operating ring 5 with the possibility of being connected to the working cavities of the compressor and turbine. Rotor 1 is made with thickening 9 along the outer diameter with circumference equal to half the circumference of rotor 1. Larger outer rotor diameter 1 is of the size that does not allow rotor 1 to contact the inner surface of ring 5. Rotor 2 is made with stepped thickening 10 along the inner diameter with a circumference of the step equal to half the circumference of rotor 1. Smaller internal rotor diameter 2 is of the size that does not allow rotor 2 to contact the outer surface of ring 5. Chamber 11 is made detachable from the working cavities.

EFFECT: invention is aimed at increasing the power and technical and economic performance indicator of an engine.

1 cl, 3 dwg

Description

The invention relates to engine building, in particular to rotary piston internal combustion engines.

The proposed rotary piston engine has the property of a gas turbine, as it is equipped with a compressor, a combustion chamber and a turbine, and according to the principle of operation, it is a piston internal combustion engine with four cycles of operation: inlet, compression, working stroke and exhaust.

Known rotary piston internal combustion engine, comprising a housing with working chambers formed by the working cavities, in which the rotating compressor rotor and turbine rotor are installed, made in the form of parallel disks mounted on the shaft, in one of which, in the compressor rotor, with a large diameter a radial groove with a depth gradually increasing from zero to the largest value on the first half of the circular arc of this disk and gradually decreasing from the largest value to zero on the second polo the fault of the circular arc of this disk. Another disk with a smaller diameter, the turbine rotor, is equipped with a protrusion having the ability to contact with the housing and a spring-loaded working flap. Between the rotors there is a combustion chamber made in the form of coaxial external, middle and internal cylinders installed in each other. The outer cylinder is divided by a plane passing through the axis of the shaft of the rotors and cylinders into half-cylinders, the first of which, which is the housing of the combustion chamber, is rigidly fixed in the engine housing, and the second of which, simultaneously being the piston, is located in the groove of the disk with a large diameter with the possibility of movement relative to the first half-cylinder until the inclined bottom of the second half-cylinder fits to the base of the radial groove of the disk. The middle cylinder and the rotatable inner cylinder are provided with windows for admitting the working mixture into the combustion chamber and bypass windows for discharging the burning working mixture. The spark plug is installed in the bottom of the inner cylinder, facing the turbine rotor. In this rotary piston engine, fuel is compressed in the compressor rotor, while the working mixture is moved to the combustion chamber, where the mixture burns. Thermal energy is transferred to the turbine rotor, where it is converted into mechanical (patent RU 2193676 C2, IPC ⁷ F02B 53/08).

The main disadvantage of this engine is its low durability due to the difficulty in ensuring the long-term operability of the elements of the combustion chamber, since its inner cylinder, subject to the influence of high temperatures, is made rotating, which can lead to jamming.

The closest to the claimed invention in technical essence and the achieved result (prototype) is a rotary piston internal combustion engine containing an engine casing with a working ring that is part of it, having cylindrical inner and outer surfaces, the axes of which are offset in opposite directions relative to the axis of rotation of the engine shaft by an amount that does not allow these surfaces to intersect, by working chambers formed by working cavities in which parallel to the motor shaft a rotating compressor rotor is installed, made in the form of a disk with a through radial rectangular groove formed from the axis of rotation of the motor shaft to the outer surface of this rotor along the width of the latter, in which a spring-loaded working shutter, made in the form of a sealing plate, with the possibility of reciprocating movement in the groove of the compressor rotor and the fit of its end to the inner cylindrical surface of the working ring with a width equal to the width of the compressor rotor, a rotating rotor tour bins, made in the form of a cup with a bottom rigidly fixed to the shaft, having a thickening in the direction of the axis of rotation of the motor shaft with a width equal to the width of the compressor rotor, on the side surface of the cup above the combustion chamber. The combustion chamber is located in the opening of the widest part of the working ring with the possibility of connection with the working cavities of the compressor and turbine through the inlet and outlet channels, respectively. The compressor rotor is integrated between the outer and inner side cheeks inside the working ring. The gas distribution mechanism, made in the form of a gas distribution cup and interacting with the combustion chamber, is built into the working ring. A shaft passing through the hole of the inner side cheek is rigidly attached to the bottom of the gas distribution cup on the turbine rotor side. The shaft, together with the gas distribution cup, can be rotated by a mechanical gearbox from the motor shaft. The side surface of the gas distribution cup is equipped with a bypass window, the configuration of which is similar to the configurations of the combustion chamber housing window for the inlet of the working mixture, the exhaust window of the combustion chamber housing for the burning working mixture, the window in the working ring for the working mixture inlet and the exhaust window in the working ring for the burning working mixture. The bypass window is installed with the possibility of combining with the named windows. A spark plug is installed in the body of the combustion chamber. The working cavities of the engine are formed by the side cheeks, the working ring and the rotors. Compression of the working mixture is carried out initially in the compressor rotor, followed by its movement into the combustion chamber, where the mixture is ignited by the spark plug and then enters the working chamber of the turbine rotor. The thermal energy received during fuel combustion is transferred to the turbine rotor, where it is converted into mechanical (patent RU 2351780 C1, IPC FO2B 53/08 (2006.01), FO2B 55/14 (2006.01), FO1C 1/32 (2006.01)).

However, the following can be noted as disadvantages of the above engine:

- power loss due to the presence of the gearbox, which drives the gas distribution mechanism;

- reduced technical and economic performance of the engine due to the difficulty of maintaining high pressure of the working mixture in the combustion chamber during compression, since the gas distribution mechanism is made rotating, and therefore has gaps through which the gas leak.

The technical problem, the solution of which is provided by the implementation of the invention, is to create a rotary piston internal combustion engine with increased power and technical and economic performance.

The solution to this technical problem is achieved by the fact that in a rotary piston internal combustion engine containing an engine casing with a working ring that is part of it, having cylindrical inner and outer surfaces, working chambers formed by working cavities in which a rotating compressor rotor is installed in parallel with the motor shaft made in the form of a disk, in the groove of which a spring-loaded working flap is installed, and a rotating turbine rotor, made in the form of a glass with a rigidly fixed on a bottom having a thickening in the direction of the axis of rotation of the engine shaft with a width equal to the width of the compressor rotor, on the inner surface of the cup above the combustion chamber, which is located in the hole of the widest part of the working ring with the possibility of connection with the working cavities of the compressor and turbine through the inlet and outlet channels, respectively , external and internal side cheeks, between which inside the working ring a compressor rotor is integrated, a gas distribution mechanism interacting with the combustion chamber and built in the working ring, the spark plug mounted in the combustion chamber, while the axis of the cylindrical inner surface of the working ring is shifted relative to the axis of rotation of the engine shaft by an amount that does not allow these surfaces to intersect, according to the invention, the compressor rotor is thickened along the outer diameter with a circle length, equal to half the circumference of the compressor rotor with smooth transitions from one outer diameter to another outer diameter, with a larger outer diameter of the compressor rotor the litter has a size that does not allow the compressor rotor to come into contact with the inner surface of the working ring, the turbine rotor is made with stepwise thickening along the inner diameter with a step circumference equal to half the circumference of the turbine rotor with smooth transitions from one inner diameter to another inner diameter, with a smaller inner the diameter of the turbine rotor has a size that does not allow the turbine rotor to come into contact with the outer surface of the working ring, the gas distribution mechanism is formed start and exhaust valves, made in the form of L-shaped spring-loaded plates embedded in the working ring near the combustion chamber, while the inlet valve facing the compressor rotor is located in front of the combustion chamber in the direction of rotation of the engine shaft with the possibility of reciprocating movement in the guide a groove made in the working ring, tightly pressed with its base, the tip of which is directed towards the direction of rotation of the compressor rotor, to the outer surface of the compressor rotor RA, and the location of this base, entering when closing the inlet channel due to the movement of the inlet valve by thickening the compressor rotor into a recess in the working ring, and the exhaust valve facing the turbine rotor is located behind the combustion chamber in the direction of rotation of the engine shaft with a reciprocating movement in the guide groove made in the working ring, tightly pressed with its base, the tip of which is directed in the direction of rotation of the turbine rotor, to the inner surface of the the turbine torus, and the location of this base, entering when closing the exhaust channel due to movement of the exhaust valve by thickening the turbine rotor into a recess in the working ring. The combustion chamber is made separate with the possibility of separation from the working cavities by the intake and exhaust valves.

The increase in power of the proposed rotary piston internal combustion engine due to increased efficiency due to the fact that the gas distribution mechanism is based on the intake and exhaust valves, which are disconnected, if necessary, from the working cavities by a separate combustion chamber, made in the form of L-shaped spring-loaded plates built into the working ring near the combustion chamber, which leads to the absence of the need to use a gearbox.

Improving the technical and economic performance of the proposed rotary piston internal combustion engine is provided by the introduction of the intake and exhaust valves of the gas distribution mechanism, moving reciprocally in the working ring, performing the functions of both the dampers, and the intake and exhaust valves, which simplifies the design of the gas distribution mechanism and preserves compression in the combustion chamber at the required level.

The invention is illustrated by drawings, where in FIG. 1 shows a General view of the proposed rotary piston internal combustion engine; in FIG. 2 is a section along line AA of FIG. one; in FIG. 3 is an enlarged view of the combustion chamber, a section along line AA of FIG. one.

The basis of the proposed rotary piston internal combustion engine are two rotors: compressor rotor 1 and turbine rotor 2 located in parallel, mounted on one shaft 3 of the engine at a fixed distance from each other and rotating together with the shaft 3 in the housing 4 (see Fig. 1 ) The compressor rotor 1 is made in the form of a circular disk and is integrated in the working ring 5 with the possibility of rotation inside the latter.

The working ring 5, which is part of the engine housing 4, has two working cylindrical surfaces, namely, the inner, facing the rotor 1, and the outer, facing the rotor 2. The axis of the cylindrical inner surface of the working ring 5 is shifted relative to the axis of rotation of the motor shaft 3 by the value ΔH, not allowing the inner surface of the working ring 5 to intersect with the outer surface of the rotor 1 of the compressor (see Fig. 2). The width of the working ring 5 is equal to the width of the rotor 1 of the compressor.

In the compressor rotor 1, a rectangular groove 6 is made over the axis of rotation of the motor shaft 3, extending to the outer surface of the compressor rotor 1 and with a width equal to the width of the compressor rotor 1.

In the groove 6 there is a working shutter 7, consisting of one or several plates, with the possibility of reciprocating movement in the groove 6. The end of the shutter 7 under the action of the springs 8 has the ability to fit snugly against the cylindrical inner surface of the working ring 5.

The compressor rotor 1 is made with a thickening 9 along the outer diameter with a width equal to the width of the rotor 1 and a circumference equal to half the circumference of the compressor rotor 1, and has smooth transitions from one outer diameter to another outer diameter, and the larger outer diameter of the compressor rotor 1 has the size that does not allow the rotor 1 of the compressor in contact with the inner surface of the working ring 5.

The rotor 2 of the turbine is made in the form of a glass, the bottom of which is rigidly fixed to the shaft 3 of the engine (see Fig. 1). On the side surface of the glass, a diametrical thickening is made in the direction of the axis of rotation of the engine shaft 3, located above the cylindrical outer surface of the working ring 5 with a width equal to the width of the compressor rotor. The turbine rotor 2 is made with a stepwise thickening 10 along the inner diameter with a step circumference equal to half the circumference of the turbine rotor 2 with smooth transitions from one inner diameter to another inner diameter, the smaller inner diameter of the turbine rotor 2 having a size that does not allow the turbine rotor 2 contact with the outer surface of the working ring 5 (see Fig. 2).

In the working ring 5, in the place of the highest height of the ring, between the rotors 1 and 2 there is a combustion chamber 11 with an intake valve 12 and an exhaust valve 13 adjacent to it, forming a gas distribution mechanism. Thus, the inlet valve 12 and the exhaust valve 13 are integrated into the working ring 5 near the combustion chamber 11. The intake valve 12 is turned towards the compressor rotor 1, and the exhaust valve 13 is turned towards the turbine rotor 2.

The compressor rotor 1, the thickening of the rotor 2 and the working ring 5 are located between two working side cheeks: outer 14 and inner 15, tightened by bolts 16 and which together with the working ring 5 are the basis of the motor housing 4 (see Fig. 1).

In these cheeks 14 and 15, the shaft 3 of the engine is mounted on the bearings 17. Thus, the compressor rotor 1, built inside the working ring 5 between the outer 14 and the inner 15 side cheeks, has the ability to rotate in the cavity formed by the cylindrical inner surface of the working ring 5 and the outer 14 and inner 15 side cheeks; the rotor 2 with a bulge 10 located above the outer surface of the working ring 5, has the possibility of rotation in the cavity formed by the cylindrical outer surface of the working ring 5 and the outer 14 and inner 15 side cheeks.

The combustion chamber 11 has an inlet channel 18 and an exhaust channel 19, overlapped by the inlet valve 12 and the exhaust valve 13 (see Fig. 3). Thus, the inlet channel 18 and the exhaust channel 19 are made in the working ring 5 and are intended for the inlet of the working mixture into the combustion chamber 11 and the release of the burning working mixture from the combustion chamber 11.

The inlet valve 12 is made in the form of a L-shaped plate with a spring 20 and is located in front of the combustion chamber 11 in the direction of rotation of the engine shaft 3 with the possibility of reciprocating movement in the guide groove 21, made in the working ring 5, tightly pressed due to the spring 20 with its base , the tip of which is directed towards the direction of rotation of the compressor rotor 1, to the outer surface of the compressor rotor 1, and the location of this base entering when closing the inlet channel 18 by moving the inlet valve and 12 by thickening 9 of the compressor rotor 1 into a recess in the working ring 5.

The exhaust valve 13 is made in the form of a L-shaped plate with a spring 22 and is located behind the combustion chamber 11 in the direction of rotation of the engine shaft 3 with the possibility of reciprocating movement in the guide groove 23, made in the working ring 5, tightly pressed due to the spring 22 with its base , the tip of which is directed in the direction of rotation of the turbine rotor 2, to the inner surface of the turbine rotor 2, and the location of this base entering when closing the exhaust channel 19 by moving the outlet valve 13 thickening We have 10 rotors 2 of the turbine in the recess in the working ring 5.

Thus, in the recesses in the working ring 5 for valves 12 and 13, when moving the latter, the bases of the valves 12 and 13 are tightly closed, closing the inlet channel 18 and the outlet channel 19.

The inlet valve 12 and the exhaust valve 13 respectively have protrusions 24 and 25 for additional locking of the combustion chamber 11.

The working cavities of the engine are formed by the outer 14 and inner 15 side cheeks, the working ring 5, the compressor rotor 1 and the turbine rotor 2 (see Fig. 1).

The combustion chamber 11 is made separate with the possibility of separation from the working cavities by the inlet valve 12 and the exhaust valve 13.

The working chamber of the compressor rotor 1, formed by the outer surface of the rotor 1, the cylindrical inner surface of the working ring 5, the outer 14 and the inner 15 side cheeks, is divided by the working flap 7 and the inlet valve 12 into the inlet chamber 26 and the compression chamber 27 (see Fig. 2) .

The working chamber of the rotor 2 of the turbine, formed by the outer cylindrical surface of the working ring 5, the cylindrical inner surface of the thickening of the rotor 2, the outer 14 and the inner 15 side cheeks, is divided by an exhaust valve 13 into a working chamber 28 and an exhaust chamber 29.

In the outer side cheek 14, an inlet channel 30 is provided for connecting the inlet chamber 26 to the inlet path of the working mixture inlet system and an outlet channel 31 for connecting the working cavity of the outlet chamber 29 with the atmosphere (see Figs. 2, 3). In the outer side cheek 14 there is a cone-shaped recess, and in the working ring 5 there is an opening for installing the spark plug 32.

In addition, the drawing further indicates:

- a circular line with an arrow in FIG. 2 - the direction of rotation of the rotors 1,2;

- zigzag lines with arrows in FIG. 2 and 3 - the direction of movement of the working mixture;

- dashed lines in FIG. 3 - an inlet channel for connecting the inlet chamber to the inlet tract of the working mixture inlet system, and an outlet channel for connecting the working cavity of the exhaust chamber to the atmosphere.

A rotary piston internal combustion engine operates as follows.

For the reference point, we take the position of the compressor rotor 1 when the end face of its working flap 7 is located in the center of the inlet channel 18 (see Fig. 2, 3). The rotation of the rotors 1, 2 occurs clockwise from the side of the spark plug 32 (see Fig. 1, 2). As a working mixture, a mixture consisting of fuel vapor and air is used.

Consider the initially complete engine duty cycle from the intake stroke to the exhaust stroke, occurring with the first charge of the working mixture.

1 cycle - inlet - occurs at the angle of rotation of the shaft 3 of the engine from 0 ° to 360 °. When the rotor 1 of the compressor rotates behind the working shutter 7, a vacuum is created, and a portion of the working mixture flows through the channel 30 into the inlet chamber 26 (see Figs. 2, 3). At this moment, at the angle of rotation of the shaft 3 of the engine from 0 to 180 °, the inlet valve 12 is open, since a bulge 9 along the outer diameter of the rotor 1 is not located under the inlet valve 12, and at the angle of rotation of the shaft of the engine 3 from 180 to 360 °, the inlet valve 12 closed, since the thickening 9 of the compressor rotor 1 is located under the inlet valve 12. In both cases, under the action of the spring 20, the base of the inlet valve 12 is pressed firmly against the outer surface of the compressor rotor 1, creating a tightness of the inlet chamber 26.

2 cycle - compression - occurs at the angle of rotation of the shaft 3 of the engine from 360 ° to 700-720 °. At an angle of rotation of the shaft 3 of the engine from 360 ° to 520-540 ° (depending on the angle of installation of the gas distribution phases), the working mixture is preliminarily compressed in the compression chamber 27 until the inlet valve 12 opens, since the bulge 9 at this moment is not located under the inlet valve 12. After opening the intake valve 12, the pre-compressed mixture in the chamber 27 enters the combustion chamber 11 and then is compressed in the combustion chamber 11 up to 700-720 ° rotation of the engine shaft 3, that is, until the intake valve 12 closes the intake channel 18 due to on Egan thickening 9 at the base of the air intake valve 12. At this point the working mixture would be compressed in the combustion chamber 11.

3 cycle - working stroke - occurs at the angle of rotation of the shaft 3 of the engine from 720 ° to 900-920 °. In this case, when the angle of rotation of the shaft 3 of the engine is equal to 700-720 °, ignition of the working mixture in the combustion chamber 11 occurs due to the spark jumping in the spark plug 32 (see Fig. 1). At this point, the intake valve 12 and the exhaust valve 13 are closed (see Fig. 2).

Since the combustion chamber 11 at this moment has no connection with the compression chamber 27 and the working chamber 28, the combustion of the working mixture can also be detonation, that is, have the character of an explosion.

When the maximum pressure in the combustion chamber 11 from the combustion of the working mixture is reached or somewhat earlier, the exhaust valve 13 opens due to the fact that the thickening 10 of the rotor 2 at that time will no longer be located above the exhaust valve 13 (see Fig. 2, 3) . When the exhaust valve 13 is opened, the burnt working mixture under high pressure enters the working chamber 28 and, acting on the end face of the protrusion of the thickening stage 10 of the turbine rotor 2, makes the rotor 2 rotate and create torque on the motor shaft 3.

At an angle of rotation of the shaft 3 of the engine from about 900 to 920 °, the process of purging the combustion chamber 11 occurs, since at this time the inlet valve 12 and the exhaust valve 13 are open. At an angle of rotation of the shaft 3 of the engine from 920 to 1080 °, the exhaust gases move around the circumference with the possible simultaneous release of them into the atmosphere.

4 cycle - release - occurs when the shaft 3 of the engine rotates from 1080 ° to 1260 ÷ 1440 °. In this case, the exhaust gases from the exhaust chamber 29 through the exhaust channel 31 are discharged into the atmosphere (see Fig. 3).

Thus, when the angle of rotation of the shaft 3 of the engine is equal to 1440 °, the exhaustion process ends, and therefore, the complete duty cycle that occurs in this rotary piston engine with the first charge of the working mixture ends.

With constant engine operation, the following occurs. When the rotors rotate from 0 ° to 360 ° in the working cavity of the rotor 1 (see Fig. 2, 3), the working mixture is compressed in the compression chamber 27, and then in the combustion chamber 11 and the working mixture is inlet into the inlet chamber 26, and the working cavity of the rotor 2 is simultaneously a working stroke in the chamber of the stroke 28 and the exhaust gas from the exhaust chamber 29. Thus, the full cycle of the engine is performed at an angle of rotation of the shaft 3 of the engine equal to 360 °.

The use of the invention improves the efficiency of the engine by changing the design of the compressor and turbine rotors, changing the design of the gas distribution mechanism.

Claims (1)

A rotary piston internal combustion engine comprising an engine casing with a working ring which is part of it, having cylindrical inner and outer surfaces, working chambers formed by working cavities in which a rotating compressor rotor is installed parallel to the engine shaft in the form of a disk in the groove of which a spring-loaded working valve is installed, and a rotating turbine rotor, made in the form of a cup with a bottom rigidly fixed to the shaft, having a thickening in the direction of the rotation axis the engine shaft with a width equal to the width of the compressor rotor, on the inner surface of the cup above the combustion chamber, which is located in the widest part of the working ring with the possibility of connection with the working cavities of the compressor and turbine through the inlet and outlet channels, respectively, of the outer and inner side cheeks, between which inside the working ring is integrated with the compressor rotor, a gas distribution mechanism that interacts with the combustion chamber and is built into the working ring, the spark plug mounted in the chamber combustion, while the axis of the cylindrical inner surface of the working ring is shifted relative to the axis of rotation of the motor shaft by an amount that does not allow these surfaces to intersect, characterized in that the compressor rotor is thickened along the outer diameter with a circumference equal to half the circumference of the compressor rotor with smooth transitions from one outer diameter to another outer diameter, the larger outer diameter of the compressor rotor being sized to prevent the compressor rotor from touching with the inner surface of the working ring, the turbine rotor is made with stepwise thickening along the inner diameter with a step circumference equal to half the circumference of the turbine rotor with smooth transitions from one inner diameter to another inner diameter, and the smaller inner diameter of the turbine rotor has a size that does not allow the rotor the turbines are in contact with the outer surface of the working ring, the gas distribution mechanism is formed by inlet and outlet valves made in the form of L-shaped sub supper plates embedded in the working ring near the combustion chamber, while the inlet valve facing the compressor rotor is located in front of the combustion chamber in the direction of rotation of the engine shaft with the possibility of reciprocating movement in the guide groove made in the working ring, tightly pressed by its base , the tip of which is directed towards the direction of rotation of the compressor rotor, to the outer surface of the compressor rotor, and the location of this base, included when closing the inlet channel due to the movement of the inlet valve by thickening the compressor rotor into a recess in the working ring, and the exhaust valve facing the turbine rotor is located behind the combustion chamber in the direction of rotation of the engine shaft with the possibility of reciprocating movement in the guide groove made in the working ring, dense pressing with its base, the tip of which is directed in the direction of rotation of the turbine rotor, to the inner surface of the turbine rotor, and the location of this base, which comes in when closing the exhaust channel by moving the exhaust valve by thickening the turbine rotor into a recess in the working ring, and the combustion chamber is made separate with the possibility of disconnecting the intake and exhaust valves from the working cavities.

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