UA151742U - Piston heat engine with induction heating of the inlet air - Google Patents

Abstract

A reciprocating heat engine with induction heating of the inlet air is claimed, in one of the cylinders of which air is injected from the environment, compressed and supplied through the inlet valve and the connecting channel to the outer chamber, into which fuel, for example, ethyl alcohol, is supplied through the injectors, and the process of combustion of fuel for heating the compressed air is carried out. The processes of expansion of the combustion products and their subsequent removal from the working cylinders to the environment are carried out in accordance with their operation procedure, which is connected to the working cylinders by channels and inlet valves. The maximum pressure of fuel combustion products in the outer chamber is maintained at 3-5 MPa, and the maximum temperature of compressed air is not more than 1500 K, due to the amount of fuel injected into the outer chamber and the duration of opening the inlet valves of the working cylinders, for example, electromagnetically operated valves, which open at 5-10 degrees of crankshaft rotation to the upper dead center of the working cylinder pistons, and close, depending on the engine operating mode, at 5-40 degrees of crankshaft rotation beyond the upper dead center of the working cylinder pistons. To heat the compressed air, an inductive coil is used, which is installed on the side of the inlet channel of the working cylinders.

Description

A useful model belongs to the field of mechanical engineering, namely to reciprocating heat engines with a split four-stroke or two-stroke cycle.

Known piston four-stroke or two-stroke heat engines having at least two cylinders, a common combustion chamber, in which the intake and compression strokes, the fuel combustion process in the combustion chamber, the expansion and release strokes of combustion products are carried out (|1-7|. The general disadvantages of known piston four-stroke or two-stroke heat engines, in which the work cycle is carried out in at least two cylinders, there is insufficient efficiency of converting the heat of fuel combustion into the mechanical work of gases and increased emissions with exhaust gases of toxic chemical compounds due to the limited duration of the combustion process and high values of pressure and temperature of combustion products.

The closest analog is a reciprocating heat engine, in one of whose cylinders the process of air intake from the environment, its compression and supply of compressed air through the exhaust valve and the connecting channel to the combustion chamber is carried out, into which fuel, for example, ethyl alcohol, is fed through nozzles. the fuel combustion process is carried out in the external combustion chamber (for heating the compressed air), which is connected by channels and inlet valves to the working cylinders, and the maximum pressure of the fuel combustion products in the external combustion chamber is maintained at the level of 3-5 MPa, and the maximum temperature of the compressed air no more than 1500 K, due to the amount of fuel injected into the external combustion chamber and the duration of the opening of the intake valves of the working cylinders, for example, valves with an electromagnetic drive. Reduction of air pressure fluctuations in the working cylinders during the cycle (one revolution of the crankshaft) is achieved with the help of a compressed air chamber installed, for example, between the air compression cylinder and the working cylinders.

Compressed air from the compressed air chamber is supplied to the working cylinders through intake valves, for example, with an electromagnetic drive, which open in 5-10 degrees of crankshaft rotation to the top dead center of the pistons of the working cylinders, and close, depending on the engine operation mode, in 5-40 degrees of crankshaft rotation after the top dead center of the pistons of the working cylinders (7|.

The main disadvantages of the nearest analog, as well as previous analogs, are the insufficient efficiency of converting the heat of fuel combustion into the mechanical work of gases and increased

Emissions with exhaust gases of toxic chemical compounds caused by the fuel combustion process.

The purpose of the proposed useful model is to improve the piston engine with a split two-stroke cycle in order to increase the efficiency of using the energy of compressed air and the heat supplied to it in the mechanical operation of gases and the absence of emissions with exhaust gases of toxic chemical compounds.

The task is solved by implementing a two-stroke cycle and installing induction coils for induction heating of air in the inlet channel of the working cylinders.

For example, in three cylinders, one of which is used as a compressor, and the other two as working cylinders, in which the processes of expanding compressed air and removing it to the environment are carried out, and heating is carried out with the help of induction coils located outside the compressor and working cylinders on the inlet channel , while limiting the maximum pressure of the compressed air in the working cylinders to 3-5 MPa, and the maximum temperature of the compressed air no more than 1500 K. The reduction of air pressure fluctuations in the working cylinders during the cycle (one revolution of the crankshaft) is achieved with the help of a compressed air chamber installed , for example, between the air compression cylinder and the external induction heating chamber. Compressed air from the external chamber of induction heating is supplied to the working cylinders through intake valves, for example, with an electromagnetic drive, which open in 5-10 degrees of rotation of the crankshaft to the top dead center of the pistons of the working cylinders, and close, depending on the engine operating mode, in 5-40 degrees of rotation of the crankshaft after the top dead center of the pistons of the working cylinders. Air is removed from the working cylinders through the exhaust valves during 80-120 degrees of crankshaft rotation when the pistons of the working cylinders are moved from the bottom dead center to the top dead center. After closing the exhaust valves during 60-100 degrees of crankshaft rotation, the remaining air is compressed to the top dead center of the pistons of the working cylinders to reduce energy losses at the intake valves. Reduction of heat loss from the surfaces of the compressed air channels, the compressed air chamber, the external chamber and the channels connecting the external chamber with the working cylinders is achieved by the use of thermal insulation of these surfaces or the latest construction materials.

The functional purpose of the set of declared features is the efficiency of using the energy of compressed air and the heat supplied to it due to induction heating in the mechanical operation of gases and the absence of emissions of toxic chemical compounds with exhaust gases.

In fig. 1 shows, as an example, a general view of a reciprocating heat engine with a split two-stroke duty cycle and with induction heating of the inlet air and three cylinders, one of which is used as a compressor.

In fig. 2 shows the pressure change diagram in the superpiston cavity of the compressor cylinder.

In fig. C shows the pressure change diagram in the superpiston cavity of the working cylinders.

A reciprocating heat engine with induction heating of the air in the inlet channel (see Fig. 1), contains a compressor cylinder 1 with inlet 2 and outlet valves, an inlet channel 4, at the entrance of which an air filter 5 is installed, a compressed air chamber 6, connected by a channel 7 with the compressor cylinder 1, and channel 8 through the external induction heating chamber 9, around which the induction coil 10 is located and connected through channel 11 with channels 12 and 13 through inlet channels 14 and 15, for example with electric drives, with working cylinders 16 and 17, which have exhaust valves 18 and 19, for example with a cam drive, through which the exhaust air from the working cylinders 16 and 17 is diverted to the exhaust channels 20 and 21, which are connected to the exhaust manifolds 22 and 23. The piston 24 of the compressor cylinder and the pistons 25 and 26 working cylinders are connected to a common crankshaft 30 by connecting rods 27, 28 and 29.

The geometric degree of expansion of the compressed air in the working cylinders is calculated by the formula b-Mtakh/Mtip. For example, when the stroke of the pistons in the working cylinders 16 and 17 is 5-100 mm and the over-piston gap when the pistons are positioned at the top dead center D-:2-5 mm, the geometric degree of expansion of the compressed air is 6-20-50.

The device works as follows.

During the intake stroke in the compressor cylinder 1, air from the environment through the air filter 5, channel 4 and the intake valve 2, for example a plate valve, enters the superpiston cavity of the compressor cylinder 1 (curve 4-1 in Fig. 2), and during the return movement of the piston 24 air compression is carried out from the bottom dead center to the top (curve 1-2 in Fig. 2).

At the end of the discharge stroke, compressed air up to 3-5 MPa is supplied through the discharge valve C and channel 7 to reduce the pressure fluctuations of the compressed air to the compressed air chamber 6 (curve 2-3 in Fig. 2), connected by channel 8 through the external chamber of the induction heating 9,

Around which the induction coil 10 is located, and the channel 11 connecting the external induction heating chamber 9 with channels 12 and 13 to the working cylinders 1, 16 and 17, into which compressed air is supplied and heated by the induction coil 10 at a given maximum heating temperature. Heated air through the connecting channels 12 and 13, intake valves 14 and 15, for example with an electromagnetic drive, is supplied alternately to the working cylinders 16 and 17. The intake valves open after 5-10 degrees of rotation common to all cylinders of the crankshaft 30 to the upper of the dead center of the pistons 25 and 26 of the working cylinders 16 and 17, and close depending on the mode of operation for 5-40 degrees of rotation of the crankshaft 30 behind the top dead center of the pistons 25 and 26 (diagram section a-m, Fig. 3). The expansion of the heated compressed air in the working cylinders 16 and 17 is carried out by moving the pistons 25 and 26 in the working cylinders 16 and 17 to their bottom dead center (curve y-ie in Fig. 3). On the expansion stroke of the compressed air in the working cylinders 16 and 17 when the pistons 25 and 26 of the working cylinders are in the position of 0-40 degrees of rotation of the crankshaft 30 to the bottom dead center (diagram section a-m Fig. 3) (according to the order of operation) open, for example, using a cam mechanism, exhaust valves 18 and 19.

The exhaust air from the working cylinders 16 and 17 is removed (curve e-e"' in Fig. 3) during 80-120 degrees of rotation of the crankshaft 30 when moving the pistons 25 and 26 from the bottom dead center to the top through the exhaust valves 18 and 19, exhaust channels 20 and 21 to the exhaust manifolds 22 and 23. When the pistons 25 and 26 are positioned in the working cylinders 16 and 17 for 60-100 degrees of rotation of the crankshaft 30 to their top dead center, the exhaust valves 18 and 19 close, the air remaining in the piston the cavities of the working cylinders 16 and 17 are compressed during 60-100 degrees of rotation of the crankshaft (Fig. 3).

Thus, the two-stroke cycle is carried out in this case in three cylinders, one of which is a compressor, for one revolution of the crankshaft.

The effectiveness of the practical use of the proposed piston heat engine with induction heating of the inlet channel air is evaluated by a simplified cycle diagram.

A simplified diagram of the cycle of this engine can be represented by an open thermodynamic cycle with a variable mass of the working body, in which heat is supplied with the working body to the working cylinders at constant values of pressure p and temperature Ti and is removed from the working cylinders with the working body at constant values of pressure p and temperature of the working body body T". The working body in the thermodynamic cycle is an ideal gas, the heat capacity of which does not depend on temperature. The thermodynamic efficiency of the cycle is calculated according to the formula: n 1 9-09, 3-65 4 MS. (57) in Vol

And o, o, o, M.S, (- 7) t - 7 where GI is the mechanical work of gases in the cycle;

CO) - the heat supplied with the working body;

СО" - heat removed with the working body;

Sr - specific mass heat capacity of the working fluid at constant pressure;

M - mass of the working body;

It is the ambient temperature;

Those are the temperature of the working fluid entering the piston cavity of the working cylinders;

Ta is the temperature of the working fluid removed from the piston cavity of the working cylinders;

Me - the volume of the compression chamber of the cylinder;

We are the working volume of the cylinder.

At the value of To-ZO0OK (27 "C); T1-1500K; T2-400K, the thermodynamic efficiency of the cycle is 0.92. With an increase in the temperature of the working fluid removed from the working cylinders

T2, the thermodynamic efficiency will decrease. The thermodynamic efficiency of internal combustion engines does not exceed pi dvz - 0.70.

The use of a heat engine with induction heating of the air of the inlet channel, for example, as a power plant of a car allows to reduce fuel consumption by 100 percent, reduce emissions of toxic chemical compounds with exhaust gases by 100 percent without using additional systems for their neutralization, and also significantly reduces the intensity of sound radiation. Electric energy can be consumed, for example, from batteries or solar batteries.

SOURCES OF INFORMATION: 1. Author. St. USSR 5)) 80445 JSC, cl. 4bag, 109 (MKY RO28B 11/00), 11/30/1948. 2. Author St. USSR 5) 128231, cl. 4bag, 109 (MKY eO28B 11/00), 11/30/1959. 3. Application of France EV 2172505, MKY РО2В8 15/00, РО2В 17/00, 028 75/00, 09/28/1973.

From 4. US application 5 3880126 A, MKY RO28B 33/22, 04/29/1975. 5. Application of France Mo 2319769, MKY GO28 75/12, 1977. 6. US patent Mo 8006656, MKY RO28 25/00, 2009. 7. Patent of Ukraine Mo 106558, IPC 7 GO28 47/00, E0O2B 33, 2014.

Claims (1)

USEFUL MODEL FORMULA A reciprocating heat engine with induction heating of the air of the inlet channel, in one of the cylinders of which air is admitted from the environment, its compression and supply of compressed air through the inlet valve and the connecting channel to the external chamber, into which fuel is supplied through the nozzles, for example, ethyl alcohol, and the process of burning fuel to heat compressed air is carried out, and the processes of expansion of combustion products and their subsequent removal from the working cylinders into the environment are carried out in accordance with the order of their operation, which is connected by channels and inlet valves with the working cylinders, and the maximum the pressure of fuel combustion products in the outer chamber is maintained at 3-5 MPa, and the maximum temperature of the compressed air is no more than 1500 K, due to the amount of fuel injected into the outer chamber and the duration of the opening of the intake valves of the working cylinders, for example, valves with an electromagnetic drive, which open after 5-10 degrees of rotation of the crankshaft to the top dead center of the pistons of the working cylinders, and closes depending on the engine operation mode 5-40 degrees of crankshaft rotation behind the top dead center of the pistons of the working cylinders, which differs in that an inductive coil is used to heat the compressed air, which is installed on the side of the inlet channel of the working cylinders.