RU2407899C1 - Rotary piston ice - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: in proposed ICE, energy resulted from fuel combustion is converted into rotation of rotor-piston about stator. Six-stroke adiabatic engine features geometrical division of cycle into strokes for sections: section with suction-compression stroke, section with combustion-exhaust stroke and section with work-exhaust stroke. Rotor-piston is fitted on engine common shaft in each section, offset along rotation circle so that all strokes in a section occur at a time. Fuel mix suction channel is arranged in suction chamber. Engine waste gas exhaust channel is arranged in exhaust chamber. Engine common shaft runs in block bearings. Sections are made up of cylindrical stators with dividing webs arranged on sides of said stators, while side covers are fitted on outer sides. Revolving rotor-piston interacts, in rotation, with web walls and stator cylinder covers to form work chambers. Dividing web arranged in fuel mix combustion chamber incorporates compressed fuel mix feed valve to feed said mix into combustion chamber. Channel to feed exhaust gases into work chamber is arranged in dividing web. Threaded hole to receive spark plug is arranged in stator, nearby compressed fuel mix feed valve.

EFFECT: higher operating performances.

1 cl, 9 dwg

Description

The invention relates to the field of engineering, specifically to devices in which energy from the combustion of fuel is transmitted by performing work in the mechanical circular motion of the piston element of the rotor-piston relative to the stator and is intended for use as an engine in various industries.

Known designs of internal combustion engines with reciprocating motion of pistons of rectangular cross section [1], where the working space is formed by the walls of the stator and the surface of the pistons. These engines belong to devices in which the energy from the combustion of fuel is transmitted by performing work in the mechanical circular motion of the piston element of the rotor-piston relative to the stator and is intended for use as an engine in various industries. The main disadvantage of these engines is the occurrence of significant inertia forces from the reciprocating motion of the masses, large mechanical losses.

The closest prototype of the invention is a US patent [2]. A rotary piston internal combustion engine, in which energy from the combustion of fuel in it is transmitted by performing work in a circular mechanical movement of the rotor-piston relative to the stator. The engine device is a twelve-stroke rotary piston internal combustion engine, with six strokes in the compression stage by rotor-pistons in three cylinders with a sequential decrease in volume in them and six strokes in the combustion stage by rotor-pistons in three cylinders with a sequential increase in volume in them. Between the compression cylinders and the combustion cylinders there is a preliminary combustion chamber with a spark plug installed in it. The engine contains the main shaft of rotation of the rotors-pistons and a camshaft for rotating half-month valves. The shafts are connected by gears, the angle of rotation of each half-month valve is associated with the angle of rotation of the associated rotor-piston.

The engine has significant disadvantages. The design of the rotor-piston and the valve in the shape of a crescent does not allow creating a tight separation of the suction chamber with the compression chamber in one cylinder. From the compression chamber, the fuel mixture leaks into the suction chamber, so the compression process is performed on three cylinders. The design of the rotor-piston and the valve in the shape of a crescent does not allow creating a tight separation of the combustion chambers with the exhaust chamber. From the combustion chamber there is a gas leak in the combustion phase into the exhaust chamber, so the combustion process is performed on three cylinders. This leads to an increase in the effective area of the combustion chamber and a decrease in efficiency. A gas leak in the combustion phase makes it impossible to supply a compressed fuel mixture and ignition from the spark plug in the combustion chamber. For this reason, a preliminary combustion chamber with a spark plug installed in it has been created between the compression cylinders and the combustion cylinders. All this led to an increase in mechanical losses in a device with four extra cylinders, a preliminary combustion chamber, and design complications. Technical and economic parameters have deteriorated compared with the parameters of rotary internal combustion engines, for example, a Wankel engine.

When searching for a prototype, it was revealed that these types of engines are not produced and technical specifications are unknown. The closest technical solution, selected as a prototype, is a four-stroke Wankel rotary piston engine [3], which has suction, compression, combustion, exhaust chambers and which are formed as a result of the movement of the rotor-piston relative to the inner surface of the stator. The suction, compression, combustion, and exhaust chambers are each located in their sector around the circumference of the stator, and the same cycle periodically occurs in each chamber. The Wankel engine belongs to devices in which the energy from the combustion of fuel is transmitted by performing work in the mechanical circular motion of the piston element of the rotor-piston relative to the stator and is intended for use as an engine in various industries.

In a Wankel engine, a triangular-shaped rotor-piston slides with the vertices of a triangle along the internal complex two-epitrochoid stator surface with significant friction, which reduces mechanical efficiency. To reduce friction and prevent seizures between rubbing surfaces, oil is added to the fuel, which forms harmful impurities in the combustion chamber that are emitted from the engine into the atmosphere. The engine has a large surface and an unfavorable, from the position of heat loss, shape of the combustion chamber, which is the reason for the relatively low indicator efficiency and high fuel consumption. The direction of movement of the surface, from the gas pressure on the rotor-piston, does not coincide with the tangent of the circumference of the rotation shaft. Low starting qualities, due to unstable operation of the engine at low revolutions of the rotation shaft, as a result of prolonged communication through the chamber of the suction channel and exhaust channel. Low number of cycles (cycles) per revolution of the engine [3].

To characterize the technical solution of the six-stroke rotary piston adiabatic internal combustion engine, in particular, the following features are used: rotary piston internal combustion engine, in which energy from the combustion of fuel is transferred therein by performing a circular mechanical movement of the rotor piston relative to the stator, different the fact that the engine design is a six-stroke rotary piston adiabatic internal combustion engine with a geometric division of the cycle into acts on sections, on a section with cycles of suction-compression, on a section with cycles of combustion-exhaust, on a section with cycles of recycling-exhaust, the rotor-piston in each section is mounted on a common shaft of rotation of the engine with a shift along the circumference of rotation so that all the cycles in the cycle occur simultaneously, the suction channel of the fuel mixture is formed in the suction chamber, and the exhaust gas discharge channel from the engine is made from the exhaust chamber, the common shaft of rotation of the engine rotors and pistons is mounted on thrust bearings, the sections consist of cyl of indigenous stators, on the sides of which dividing partitions are installed, and on the outside - side covers, in each section during rotation the rotor-piston interacts with the side walls of the partitions and covers in the stator cylinder and forms working chambers for its section, and in the compression chamber of the fuel mixture in the dividing wall with the combustion-exhaust section, a valve for supplying the compressed fuel mixture to the combustion chamber is formed, from the exhaust chamber in the dividing wall with the recovery-exhaust section, an inlet channel is made of clogged gases into the disposal chamber, in the stator, near the opening of the valve for supplying the compressed fuel mixture to the combustion chamber, a threaded hole is made for installing the spark plug.

In the example description of the invention, one of the means of implementing the invention is shown. The features that are described in the example description are summarized as follows.

The engine consists of a suction-compression section, a combustion-exhaust section, and a waste-exhaust section. The piston rotors in the sections are located on the common motor shaft and rotate synchronously with equal speeds. Sections consist of stators, the inner surface of which is ellipsoidal. Dividing partitions are installed between the stators, and side covers are installed on the outer sides, in which the bearings of the common motor rotation shaft are installed.

At one of the poles of the ellipse of each stator, rotors and pistons are mounted on a common motor shaft. On the radius of the disks under the force of the sliding springs and ellipsoidal surfaces of the stators, the pistons are displaced during the rotation of the common shaft, forming sections of the suction-compression chamber, sections of the combustion-exhaust chamber and sections of the disposal-exhaust chamber at the same time.

In the stator ellipsoid of the suction-compression section, in the direction of the small axis of the ellipse, a suction channel for the fuel mixture is located in the suction chamber, and at the opposite end of the small axis of the ellipse, in the separation wall with the combustion-exhaust section, there is a valve for supplying the compressed fuel mixture to the combustion chamber from compression chambers. In the combustion-exhaust section, on the opposite side from the fuel mixture supply valve, in the separation wall with the recovery-exhaust section, there is an exhaust gas inlet channel from the exhaust chamber to the chamber of the recovery-exhaust section. On the opposite side of the exhaust gas inlet channel in the stator of the recovery-exhaust section is an exhaust gas discharge channel from the exhaust chamber.

In the stator of the combustion-exhaust section, near the fuel mixture supply valve, a threaded hole is made for installing the spark plug. In the engine design, the cooler chamber in the suction-compression section is separated from the hotter section with combustion-exhaust chambers. This removes the contradiction when creating an adiabatic engine in one cylinder at the same time - colder for suction-compression and hotter for combustion-exhaust cycles. When dividing into sections, the heat transfer between the external medium and the gas in the combustion-exhaust section will be small compared with the change in the internal energy of the working fluid, which brings the engine closer to the adiabatic cycle. In the recovery-exhaust section, the energy of the exhaust gases from the combustion-exhaust section is used, which gives an additional increase in power and torque on the motor shaft. To cool the disks of the rotor-pistons, in all sections, a coolant supply line is made in the rotation shaft. In places where the rotor pistons are in contact with the mating surfaces, seals are made. The engine excludes the simultaneous overlap of the chamber of the channel of the intake of the fuel mixture and the channel of the exhaust gas, therefore, flashes and "pops" in these channels are excluded. The trajectory of the side surfaces of the pistons during gas pressure operation coincides with the tangent to the circumference of the rotation shaft and the flywheel, to which all the energy is transmitted. The combustion chamber has a wedge-shaped shape between the stator ellipsoid and the rotor-piston disk with a small surface area. Materials - steel, aluminum alloys, copper-graphite alloys, material with low thermal conductivity (ceramics) or material with low thermal conductivity for spraying on the working surfaces of the chambers.

To characterize the technical results in the use of a six-stroke rotary piston adiabatic internal combustion engine, in particular, the following signs of improving the quality of technical and economic parameters of the engine by:

- increase in efficiency, power and torque on the motor shaft, due to the use of exhaust gas in the recovery-exhaust section;

- reduction of heat losses and losses from exhaust gas, due to the geometric separation of the cycle in the design into cycles of the colder section of the intake-compression and into cycles in the hot section of the combustion-exhaust, as well as cycles in the section of utilization and exhaust. In this case, the energy consumption for compression in the colder chamber is reduced, the heat loss in the hotter chamber of the combustion-exhaust section is also reduced. Reduced losses in the disposal section;

- reduce heat loss and increase efficiency by creating a close to adiabatic cycle by manufacturing a combustion-exhaust section and a recycling-exhaust section from a material with low thermal conductivity. Reducing noise from exhaust gases through the use of a recycling-exhaust section;

- stable operation of the engine at low speeds, the absence of "pops" and reverse flashes in the suction channel, due to the absence of a simultaneous shutdown of the suction channel and the exhaust gas channel by the camera.

A rotary piston internal combustion engine, in which energy from the combustion of fuel is transferred therein by performing work in the circular mechanical movement of the rotor-piston relative to the stator, characterized in that the engine design is a six-stroke rotary piston adiabatic internal combustion engine with a geometric division of the cycle into cycles in sections, in a section with suction-compression strokes, in a section with combustion-exhaust strokes, in a section with recycling-exhaust strokes, a rotor-piston in each section closed it is heated on a common shaft of rotation of the engine with a shift along the circumference of rotation in such a way that all cycles in the cycle occur simultaneously, a suction channel of the fuel mixture is formed in the suction chamber, and a channel for exhausting exhaust gases from the engine is made from the exhaust chamber, a common shaft of rotation of the engine rotors and pistons mounted on thrust bearings, the sections consist of cylindrical stators, on the sides of which dividing partitions are installed, and on the outside there are side covers, in each section when rotating the rotor-piston acts with the side walls of the partitions and covers in the stator cylinder and forms working chambers for its section, and a valve for supplying the compressed fuel mixture to the combustion chamber is formed in the compression chamber of the fuel mixture in the separation partition with the combustion-exhaust section, from the exhaust chamber in the separation partition with the section of exhaust-exhaust gas, an exhaust gas inlet channel is made in the disposal chamber, in the stator, near the opening of the valve for supplying the compressed fuel mixture to the combustion chamber, a threaded hole for installing light chi ignition.

Particular signs: the conversion of the internal combustion engine to an external combustion engine is carried out by installing a nozzle burner above the combustion-exhaust section, and the exhaust channel is connected by a pipe through the cooling radiator to the suction channel, and gas is pumped into the pipeline and the engine under pressure; creation of a multi-fuel engine with automatic adjustment of the compression ratio, by creating an automatic adjustment device on the rotation shaft between the suction-compression section and the combustion-exhaust section; diesel option - installation of a high pressure nozzle instead of the spark plug.

The invention is illustrated by graphic images.

Figure 1 and figure 2. General view of the engine.

Figure 3. The engine of FIG. 2 is a section along "AA".

Figure 4 and figure 5. General view of the rotor-piston assembly.

6. The engine of FIG. 2 is a cut but “BB”.

7. The engine of FIG. 1 is a section along "BB".

Fig. 8. The engine of FIG. 1 is a section along "G-G".

Fig.9. The engine of FIG. 1 is a section along "DD".

An example of a specific implementation of a rotary piston engine.

A general view of the internal combustion engine is shown in FIG. 1 and FIG. 2, on which a rotation shaft 1, fastening bolts 2, a left side cover 3, a suction-compression section 4, a combustion-exhaust section 5, a disposal-exhausting section 6, right are located side cover 7, separation partition 8, separation partition 9, engine flywheel 10. In a general view of FIG. 2, a cut line along “A-A”, a cut line along “BB”, and FIG. 1 — a cut line “BB”, a cut line “GG”, a cut line “D” -D ".

In Fig.3 shows a view of the engine along the cutting line "aa" of Fig.2 of the suction-compression section 4, which consists of a rotor-piston 11, a stator 12, a right side cover 7 with a sliding bearing 13, a dividing wall 8 with a sliding bearing 14, gaskets 15, sliding spring 16 and piston 17.

In the middle part of FIG. 3, a combustion-exhaust section 5 is shown, which consists of a rotor-piston 18, a stator 19, a dividing wall 9 with a sliding bearing 20, a dividing wall 8, a sliding spring 21, a piston 22, and seals 23.

On the left side of FIG. 3, a disposal-exhausting section 6 is shown, which consists of a rotor-piston 24, a stator 25, a piston 26, a left side cover 3 with a sliding bearing 27, a dividing wall 9, seals 28, a sliding spring 29.

It should be noted that the inner surface of the stators 12, 19, 25 is made in the form of an ellipsoid, in the poles of which rotor-pistons are installed. So in section 4, the center of the rotor-piston 11 is aligned with the upper pole of the ellipse of the stator 12 of figure 3 and rotates around it in a circle. In section 5, the center of the rotor-piston 18 is aligned with the lower pole of the ellipse of the stator 19 of FIG. 3 and rotates around it in a circle. In section 6, the center of the rotor-piston 24 is aligned with the upper pole of the ellipse of the stator 25 and rotates around it in a circle. All rotor pistons 11, 18, 24 are rigidly fixed to the shaft 1 and rotate synchronously with the same speed. The geometric volume of the combustion chamber (expansion) in section 5 is increased compared with the geometric volume of the compression chamber in section 4, by increasing the size of the major axis of the ellipse in the stator 19. This leads to the use of gas pressure at the end of the stroke.

Ensuring the uniformity of the engine and the mutual balance of inertia is ensured as follows. The ellipsoid surfaces along which the pistons move in the stator of section 5 are circumferentially shifted 180 ° with respect to the ellipsoid surface along which the pistons move in sections 4 and 6. Pistons in sections 4, 5 and 6 move synchronously with the same speed of rotation. Therefore, the inertial forces in section 5 are compensated by the total inertia generated in sections 4 and 6. Full compensation is achieved when the inertia forces in section 5 are equal to the total inertia in sections 4 and 6 and are selected by the mass of pistons during engine design.

Figures 4 and 5 show a graphical representation of the rotor-piston 18 located in the combustion-exhaust section 5. All piston rotors 11, 18, 24 are similar in design. The rotor-piston 18 consists of a disk 30, in which the pistons 22 are shifted along the radii under the action of the sliding spring 21 and the inner ellipsoid surface of the stator.

On both sides of the disk 30 there are elements of the spline connectors 31 and 32. The spline connector 31 is connected to the spline connector of the rotor-piston 11 located in the suction-compression section 4, and the spline connector 32 is connected to the spline connector of the rotor-piston 24 in the disposal section 6 release. These splined connectors form a common shaft 1 of rotation in the engine of figure 1 and have the same design.

4 and 5, the slotted connector of the rotor-piston 24 of the disposal-exhaust section 6 with slots 34, which is similar to the slotted connector 31, is inserted into the sleeve with the slots 35. Between the slotted connector 32 of the disk 30 of the rotor-piston 18 and the slotted connector 34 belonging to the rotor - a piston of 24 sections 6 of utilization-release; an oil seal 36 is installed.

Slotted connectors between the rotor-pistons 18 and 11 allow you to set the plane of the piston 22 of section 5 with the plane of the piston 17 of section 4, bringing them together or removing them from each other, thereby increasing or decreasing the compression ratio. And adjusting the splines of the connector between the rotors-pistons 18 and 24 by rearranging the splines allows you to create the best option for supplying exhaust gas to the disposal-exhaust section 6. Pistons 22, 17 and 26 are made of heat-resistant antifriction material, for example, of copper-graphite composition.

On the front side of the pistons are installed labyrinth seals [4]. On the disk 30 of the rotor-piston 18, as well as the disks of the rotor-pistons 11 and 24, seals 23 are installed with springing. To establish the optimal temperature regime of the rotor-pistons 11, 18, 24 in the shaft of rotation 1, through all spline connections and disks of the rotor-pistons passes the line 37 with coolant, cooling them in series (not shown).

Figure 6 shows a section "BB":

section 4, consisting of a rotor-piston 11, a stator 12, a right side cover 7 with a sliding bearing 13, a dividing wall 8 with a sliding bearing 14, a piston 17, a sliding spring 16, a rotation shaft 1. A suction channel 38 is made in the stator 12. A valve 39 for supplying a compressed fuel mixture to the combustion chamber of section 5 is formed in the dividing wall 8. The valve consists of an opening in the dividing wall 8, a volumetric sample 40 of metal in the rotor-piston disk 11, and also a volumetric sample 41 of metal in the disk 30 of the rotor-piston 18 in the combustion exhaust section 5 and the openings 42 between them;

section 5, consisting of a rotor-piston 18, a stator 19, a dividing wall 9 with a sliding bearing 20, a sliding spring 21, pistons 22. In the stator 19, near the hole 42, a hole 43 is made with a thread for installing a spark plug or high-pressure nozzle. In the dividing partition 9, a channel 44 of the exhaust gas inlet to the disposal-exhaust section 6 from the combustion-exhaust section 5 is made;

section 6, consisting of a rotor-piston 24, a stator 25, a partition wall 9 with a sliding bearing 20, pistons 26 and a sliding spring 29, a cover 3 with sliding bearings 27. An exhaust gas channel 45 is made in the stator 25 of section 6.

In Fig. 7 of the section "BB" of the suction-compression section 4 of the engine of Fig. 1, the stator 12, the rotor-piston 11, the piston 17, the seals 15, the sliding spring 16, the disk 46 of the rotor-piston 11, a 40 v sample a disk 46, a suction channel 38, a suction chamber 47, and a compression chamber 48.

If you rotate the shaft 1 with the rotor-piston 11 in the stator 12 clockwise, then the piston 17 when moving along the ellipsoid surface of the stator 12 for each revolution twice sucks the fuel mixture into the chamber 47 through the suction channel 38, and compresses this mixture twice in the chamber 48, and through the opening 42 of the valve 39 in the separation wall 8 of FIG. 6, the compressed mixture enters the combustion-exhaust section 5.

On Fig section "GG" section of the combustion-exhaust of the engine of figure 1 shows: stator 19, rotor-piston 18, piston 22, seal 23, sliding spring 21, disk 30, volumetric sampling 41 in the disk 30, camera 49 exhaust, opening 42, valve 39 for supplying compressed fuel mixture from section 4 to section 5, a combustion chamber 50, a threaded hole 43 for a spark plug or high-pressure nozzle, and an exhaust gas inlet channel 44 to section 6.

In Fig.9 of the section "DD" of section 6 of the exhaust-exhaust engine of Fig.1 shows: stator 25, rotor-piston 24, piston 26, sliding spring 29, seals 28, disk 46, exhaust gas inlet channel 44, in the separation the partition 9 of FIG. 6, the exhaust gas utilization chamber 51, the exhaust gas exhaust chamber 52 and the exhaust gas passage 45.

Description of the main processes in a six-stroke adiabatic engine.

We do, conditionally, the rotation of the shaft 1 clockwise, but before that we consider the position of the rotor-piston 11 of section 4 of Fig. 7 with the position of the rotor-piston 18 of section 5 of Fig. 8. Figure 7 shows that the piston 17 squeezed the air in the chamber 48, and a bulk sample 40 of metal in the disk 46 of the rotor-piston 11 is located above the hole 42 of the valve 39. The piston 17 squeezed the air in front of itself, and behind it, clockwise rotation chamber 47 under the influence of rarefaction through the channel 38 of the intake air entered.

At the time of rotation of the shaft 1 clockwise, we consider the position of the rotor-piston 18 of section 5 of Fig. 8. Fig. 8 shows that the piston 22 between the disk 30 of the rotor-piston 18 and the stator 19 formed a combustion chamber 50. Since the sample 41 in the metal of the disk 30 is located above the opening 42 of the valve 39, the compressed air from the chamber 48 of Fig. 7 entered chamber 50 of Fig. 8. In the data of FIGS. 7 and 8, compressed air in the same proportion is located in chambers 48 and 50. This is done for a better understanding of the process.

In fact, the distribution of the amount of air (mixture) is determined by the position of the opening 42 of the valve 39 in the separation wall 8. A further rotation of the shaft 1 clockwise shows that the combustion chamber 50 of FIG. 8 increases in volume when the piston 22 rotates, and the air is displaced from the chamber 49 the exhaust gas inlet channel 44 of FIGS. 6 and 8 to the disposal-exhaust section 6. Since the sample 41 in the disk 30 of the rotor-piston 18 of Fig. 8 and the sample 40 in the disk 46 of the rotor-piston 11 of Fig.7 moved from the hole 42, the valve 39 was closed until the next rotation of the shaft 1 by 180 °. If fuel combustion occurred in the chamber 50, then the gas pressure from the combustion would not have spread to the chamber 48 of FIG. 7. In this case, the position of the piston 26 in Fig. 9 is shown at the moment of air inlet from section 5 of Fig. 8 through the exhaust gas inlet channel 44 of Fig. 6 into section 6 of Fig. 9. Air enters the recovery chamber 51, and the piston 26 moves clockwise and displaces air from the chamber 52 through the exhaust gas passage 45 into the atmosphere.

With further rotation, the piston 17 of the rotor-piston 11 of FIG. 7 intersects the suction channel 38, and the function of the suction chamber 47 changes to the function of the compression chamber 48, and since valve 39 is closed, compression occurs in the chamber 48. And after a certain angle of rotation of the piston 17 will take the position indicated in Fig.7. In this rotation, the piston 22 of FIG. 8 displaces air from the exhaust chamber 49 through the exhaust gas inlet channel 44 of FIG. 6 into the recovery chamber 51 of section 6 of FIG. 9 and forms a combustion chamber 50, wherein the valve 39 opens and compressed air flows from the chamber 48, the compression of FIG. 7 into the combustion chamber 50 of FIG. It should be noted that the valve 39 opens at the position of the pistons indicated in FIG. 7 and FIG. 8; in the rest of the rotation, it is closed by means of rotor-piston disks. For more confident sealing of the valve 39 from the breakthrough of hot gases, it is possible to install a plate or other additional valve in the hole 42 of the valve 39.

The six-stroke rotary piston adiabatic engine in dynamic mode.

Carburetor version of the engine.

To do this, we increase the compression chamber 48 of Fig. 7 so that the compression ratio corresponds to the carburetor mode of the engine. We rearrange the spline connector between the disks 46 of the rotor-piston 11 of section 4 of Fig. 7 and the disk 30 of the rotor-piston 18 of section 5 of Fig. 8 so that the relative position of the piston 17 of Fig. 7 and the piston 22 of Fig. 8 is increased. With this action, we increase the volume of the compression chamber 48 of FIG. 7, and the compression ratio will correspond to the operation of the carburetor engine. In the threaded hole 43 of Fig. 8, we install a spark plug and install a carburetor at the input of the suction channel 38 of Fig. 7. It should be noted that all the piston rotors in sections 4, 5, 6 work simultaneously synchronously with the same speeds and the cycles of the suction, compression, combustion, exhaust, disposal, exhaust cycles occur simultaneously in the engine.

The first cycle of the engine.

In the initial position, the elements of the rotor-pistons are shown in FIGS. 7, 8, 9. The piston 17 of FIG. 7 is at one end in front of the suction channel 38, and the second end is in front of the opening 42 of the valve 39 of FIGS. 6 and 7, which is open in the initial position . Since the sample 40 of the metal in the disk 46 of the rotor-piston 11 is located above the hole 42 of the valve 39, as well as the sample 41 of the metal in the disk 30 of the rotor-piston 18 of FIG. 8 is located above the hole 42 of the valve 39, therefore, the compression chamber 48 of FIG. 7 through the hole 42 of the valve 39 communicates with the chamber 50 of Fig. 8.

1st cycle of fuel intake in section 4.

We make the rotation of the shaft 1 180 ° under the action of an external force in a clockwise direction. The piston 17 of FIG. 7 crosses the suction channel 38 of FIG. 7, and with further movement between the suction channel 38 and the piston 17, a vacuum occurs, the fuel mixture enters the chamber 47 of FIG. 7, while the sample 40 of the metal in the disk 46 of the rotor-piston 11 is displaced from the hole 42 of the valve 39 of FIG. 7, as well as the metal sample 41 in the disk 30 of the rotor-piston 18 of FIG. 8 is shifted from the hole 42 of the valve 39 and the valve is closed.

2nd cycle of fuel compression in section 4.

At this very time, when the piston 17 of Fig. 7 is rotated, the fuel mixture, in this case air, is compressed in the chamber 48 of Fig. 7, since the valve 39 is closed, the suction chamber 47 in front of the piston was transformed into a compression chamber.

3rd cycle of fuel combustion in section 5.

In the chamber 50 of FIG. 8, there is compressed air, and when the shaft 1 rotates with the disk 30 of the rotor-piston 18 of FIG. 8, the chamber 50 increases when the fuel is conditionally burned.

The 4th exhaust gas exhaust cycle in section 5. In this case, the piston 22 of FIG. 8 of the rotor-piston 18 pushes out of the chamber 49, clockwise, conditionally, the exhaust gas through the exhaust gas inlet channel 44 of FIG. 6 in the dividing wall 9 in recycling chamber 51 of section 6 of FIGS. 9 and 6.

The 5th cycle of exhaust gas utilization in section 6. When the shaft 1 is rotated, the piston 26 of Fig. 9 of the rotor-piston 24 is shifted clockwise and receives air through the exhaust gas inlet channel 44 in the separation wall 9 from section 5.

6th cycle of exhaust gas from section 6 to the atmosphere.

With this rotation of the shaft 1, the piston 26 of FIG. 9 conditionally pushes the exhaust gas through the exhaust gas passage 45 from the chamber 52 of FIGS. 9 and 6 into the atmosphere.

Since all the rotor pistons have a symmetry of 180 °, after turning the shaft 1 through 180 °, the rotor pistons fixed to it have taken the position indicated in Fig. 7, Fig. 8, Fig. 9.

The second cycle of the engine.

Under the action of external force on the shaft 1, we rotate it clockwise 180 ° (360 ° from the initial position) at which the engine elements are located, as indicated in Fig. 7, Fig. 8, Fig. 9, as before the first cycle. And six working cycles occur in the same way as in the first cycle. Except that in the chamber 48 of FIG. 7, the fuel-gas mixture is compressed, and after compression, the opening 42 of the valve 39 opens, since the sample 40 of metal in the disk 46 of the rotor-piston 11 has risen above the opening 42 of the valve 39 of FIG. 6. 7. So the metal sample 41 of the disk 30 of the rotor-piston 18 stood above the hole 42 of the valve 39 of FIG. 6, and the compressed fuel gas mixture entered the combustion chamber 50 of FIG. 8. The engine elements have taken the position indicated in FIGS. 7, 8, 9.

The third cycle of the engine.

Under the action of external force, we make a further rotation of the shaft 1 clockwise. In this case, the piston 17 of the disk 46 of the rotor-piston 11 of FIG. 7 intersects the suction channel 38 of FIG. 7, and the sample 40 in the metal of the disk 46 of the rotor-piston 11 and the sample 41 in the metal of the disk 30 of the rotor-piston 18 are displaced from the opening 42 of the valve 39 and lock him up. In the spark plug installed in the hole 43 of FIG. 8, a spark jumps in and ignites the fuel-gas mixture in the chamber 50 of FIG. 8. The pressure from the burnt gas mixture rotates the piston 22 of FIG. 8 clockwise 180 ° (540 ° from the starting position), transmitting energy through the rotation shaft 1 to the flywheel 10 of FIG. 1. At the same time, all the rotor pistons make the same rotation through 180 ° (540 ° from the initial value). The fuel-gas mixture is sucked into the chamber 47 of FIG. 7 by turning the piston 17, and before the piston, the fuel-gas mixture is compressed in the compression chamber 48 of FIG. 7.

When the piston 22 of Fig. 8 is rotated clockwise, the air that is pushed out in the chamber 49 is discharged through the exhaust gas inlet channel 44 in the separation wall 9 of Fig. 6 into the recycling chamber 51 of section 6, Figs. 9, 6, in which the piston 26 rotates pushes through the exhaust gas channel 45 the air in chamber 52 of FIG. 6, 9. After turning the shaft 1 through 180 ° (540 ° from the starting position), all engine elements have taken the position indicated in FIGS. 7, 8, 9. When this, in the chamber 48 of Fig. 7, an opening 42 is opened in the valve 39, and the compressed fuel-gas cm Referring through opening 42 enters chamber 50 in Figure 8.

The fourth cycle of the engine.

Due to the energy stored in the flywheel 10 of FIG. 1, all of the piston rotors 11, 18 and 24 make a simultaneous clockwise rotation and go “dead center” when the piston 17 of FIG. 7 crosses the gas mixture suction channel 38. The valve 39 of FIGS. 6, 8 closes, as the samples 40 and 41 of metal in the disks come off the hole 42. At this moment, a spark jumps in the spark plug installed in the hole 43, and the incoming gas mixture in the chamber 50 of FIG. 8 ignites, the burning gas mixture creates pressure on the piston 22 of Fig. 8 and rotates it clockwise 180 ° (720 ° from the initial value), gives up and stores energy in the flywheel 10 of Fig. 1. In this case, all the rotor pistons of the engine make a simultaneous rotation of 180 ° (720 ° from the starting position). The gas mixture again enters the chamber 47 of FIG. 7 through the suction channel 38 by turning the piston 17 of FIG. 7, and before the piston, the previously received gas mixture is compressed in the chamber 48 of FIG. 7. The piston 22 of FIG. 8, through the opening of the exhaust gas channel 44 of FIGS. 8 and 6, pushes the previously burned gas mixture with a rather high temperature and pressure into the disposal chamber 51 of FIG. 9 of section 6. Behind the piston 26 of FIG. 9, the previously burned gas the mixture continues to expand, lowering the temperature, creating pressure on the piston 26, which increases the clockwise rotation moment, transferring energy through the shaft 1 to the flywheel 10 of FIG. 1. Before the piston 26 of FIG. 9, the previously received mixture is discharged from the chamber 52 through the exhaust gas channel 45 of FIGS. 9, 6.

The engine elements occupied the position indicated in Figs. 7, 8, 9, and then the process is repeated. The engine switched to active mode in dynamics. The initial countdown from the positions of the elements indicated in Figures 7, 8, 9 when considering the operation of the engine, taken conditionally. This counting can be carried out from another reference point of rotation of the shaft 1.

Diesel engine cycle option.

To do this, it is necessary to increase the compression ratio by re-splining the spline connectors between the rotor-piston 11 and the rotor-piston 18. In this case, the planes of the piston 17 of FIG. 7 will approach the piston 22 of FIG. 8 and the compression chamber will decrease. A nozzle of high pressure is installed in the hole 43 of FIG. All processes during engine start-up and operation are similar to those described during the carburetor cycle of the engine, except when a spark jumps in the spark plug, at this moment the high-pressure nozzle must inject fuel into the chamber 50 of Fig. 8.

Adiabatic cycle of a six-stroke engine.

The idea of an adiabatic engine cycle is not new. Many firms have tried to create an adiabatic engine. The greatest success in adiabatic engine development was achieved by Cummix USA. The prototype was created on the basis of a six-cylinder diesel engine [3]. But the test results are not shown. Only the expected results are given. Obviously, the project received negative results. To obtain an adiabatic cycle, it is necessary that the temperature of the cylinder walls is equal to the temperature of the gaseous medium, and this is unrealistic. They took the cylinder head without cooling as a basis to bring the temperature of the burning gas medium closer to the temperature of the head. This requirement will bring the engine closer to the adiabatic cycle. But for real engine operation, it is necessary that compression occurs in a cold cylinder, with less loss of compression energy, and combustion occurs in a hot cylinder, so that the burning gas mixture does not give thermal energy to the cylinder walls. It is impossible to do this in one cylinder due to conflicting requirements for the cylinder to be cold during compression and hot during combustion. This contradiction makes it impossible to create an adiabatic cycle in the version of the manufactured engines. This path is dead end.

The authors of the invention gave their own version of the engine design, in which these contradictions are removed. The function of one cylinder was divided into the functions of two cylinders. This is the suction-compression section (cylinder) - the cold section and the combustion-exhaust section - the hot section (cylinder). This removes the contradiction. So in the cold section, compression losses are reduced, and in the hot section, losses due to fuel combustion will also be reduced. Even in the normal temperature regime of the carburetor engine in the present invention will be expressed, to some extent, the adiabatic cycle of operation.

For a more pronounced adiabatic cycle of work in the present invention, the suction-compression section must be made of aluminum alloy, and the combustion-exhaust section and the disposal-exhaust section must be made of ceramic, which has very low thermal conductivity. In this case, the heat exchange between the external environment and the gas in section 5 combustion exhaust compared with a change in the internal energy of the working fluid will be so small that it can be neglected. Therefore, heat loss during engine operation will be significantly reduced.

Currently, an engine is being developed in Tolyatti, in which the piston group is based on the material used on the outer skin of the surface of the Buran spacecraft. This material can be used in the present invention. This makes it possible to create an adiabatic cycle in the engine without the use of high temperatures in the suction-compression section and the recycling-discharge section in both the carburetor and diesel versions of the engine.

Information sources

1. "Marine rotary engines." B.I. Akatov, V. B. Bolotov, ed. Leningrad, "Shipbuilding", 1967, pp. 27-29.

2. Patent US 2447929 A, F02B 53/00, 1948.

3. "Modern economical car." J. Matskerle, ed. M .: "Engineering", 1987, pp. 119-120, 150-154, 216-219.

4. "Seals and sealing technology." Handbook edited by A. I. Golubev and L. A. Kondakov, M.: "Mechanical Engineering", 1986, pp. 375-388.

Claims (1)

A rotary piston internal combustion engine, in which energy from the combustion of fuel is transferred therein by performing work in the circular mechanical movement of the rotor-piston relative to the stator, characterized in that the engine design is a six-stroke rotary piston adiabatic internal combustion engine with a geometric division of the cycle into cycles in sections, in a section with suction-compression strokes, in a section with combustion-exhaust strokes, in a section with recycling-exhaust strokes, a rotor-piston in each section closed it is heated on a common shaft of rotation of the engine with a shift along the circumference of rotation in such a way that all cycles in the cycle occur simultaneously, a channel for suction of the fuel mixture is formed in the suction chamber, and a channel for exhausting exhaust gases from the engine is made from the exhaust chamber, a common shaft of rotation of the engine rotors and pistons mounted on thrust bearings, the sections consist of cylindrical stators, on the sides of which dividing partitions are installed, and on the outside there are side covers, in each section when rotating the rotor-piston acts with the side walls of the partitions and covers in the stator cylinder and forms working chambers for its section, and a valve for supplying the compressed fuel mixture to the combustion chamber is formed in the compression chamber of the fuel mixture in the separation partition with the combustion-exhaust section, from the exhaust chamber in the separation partition with the section of exhaust-exhaust gas, an exhaust gas inlet channel is made in the disposal chamber, in the stator, near the opening of the valve for supplying the compressed fuel mixture to the combustion chamber, a threaded hole for installing light chi ignition.

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