RU2477375C2 - Method of piston engine cycling and piston engine - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: working medium is compressed in multistage compressor and cooled to initial compression temperature. Then, working medium is displaced into combustion chamber for heat to be fed thereto. Now, working medium is displaced into working cylinder to expanded therein with no heat losses to transfer expansion energy to engine shaft and multistage compressor drive. Note here that amount of heat fed is controlled by equalising working medium pressure increase with magnitude ε^k-1, where ε working medium expansion ratio and k is expansion adiabatic curve factor. Piston engine to this end comprises multistage compressor with cooling system, heat-isolated combustion chamber separated from working cylinder, and partially heat-isolated working cylinder with working piston arranged therein.

EFFECT: higher engine efficiency.

5 cl, 2 dwg

Description

The invention relates to power engineering, namely to engine building, and can be used to create reciprocating internal combustion engines.

The efficiency of a thermal (including piston) engine is determined by two factors: the efficiency of the developed theoretical cycle embedded in the method of converting thermal energy into mechanical energy, and the technical feasibility of creating an engine design, the real cycle of which is as close as possible to the theoretical cycle.

The well-known theoretical Wichart cycle [RZ “Internal combustion engines”, 1982, 4.39.10, p.31-37], which is a sequence of six thermodynamic processes: isothermal compression of the working fluid, isobaric supply to the working fluid of the recovered part of the heat, isobaric supply of the main part of the heat, adiabatic expansion of the working fluid to the original volume or more, isochoric removal of the recovered part of the heat from the working fluid and isobaric heat removal.

The disadvantages of this theoretical cycle are: firstly, large losses of high potential heat during isobaric supply of the main part of the heat (in a real engine in a cooled working cylinder), and secondly, the need to recover and remove heat not used in the cycle (in a real engine, this leads to design complexity and heat loss).

The aim of the invention is the implementation of the method of operation of a piston engine in such a cycle in which the equality of the thermodynamic parameters (temperature and pressure) of the working fluid at the beginning and at the end of the cycle is achieved, which eliminates the need for recovery of excess heat and heat removal at the end of the cycle.

To achieve this goal, as well as to eliminate these shortcomings of the Wishart cycle, the proposed method implements the Sladkevich cycle containing three thermodynamic processes (hereinafter referred to as C-3tp cycle): isothermal compression, isochoric heat supply and adiabatic expansion of the working fluid. And also the optimal amount of heat is supplied, satisfying the relation λ≤ε ^k-1 , where λ is the degree of increase in the pressure of the working fluid during heat supply, ε is the degree of expansion of the working fluid, k is the exponent of the expansion adiabat.

The thermodynamic cycle for an internal combustion engine is known from the prior art (patent RU 2167315 of 04.29.1999), in which clean air is compressed in the first cylinder, then it is transferred to the compressed air chamber and into the combustion chamber located in the upper part of the second cylinder, to the compressed the air in the combustion chamber is warm, then transferred to a second cylinder, in which it is expanded. The disadvantage of this cycle is the implementation of one-stage compression without the possibility of cooling the working fluid, which requires large amounts of energy for compression, which in turn reduces the efficiency of the engine.

There is also known a method of performing a cycle of a reciprocating internal combustion engine (patent RU 2075613 C1 of 03/28/1994), in which the working fluid is compressed in two stages at first with cooling, and then with the prevention of heat loss, and then heat is supplied to the working fluid inside the working cylinder of the engine and expanded with partial heat recovery. The disadvantage of this method is the need for heat recovery, which leads to inevitable heat loss and lower engine efficiency, as well as to complicate the design of the engine operating in this way.

Known internal combustion engine with a divided cycle (patent WO 82/01741 from 05/04/1981), containing a multi-stage compression cylinder and a working cylinder. In this engine, the compression of the working fluid is carried out simultaneously in all stages of the compression cylinder, and the heat supply and expansion of the working fluid are carried out in the working cylinder. The disadvantage of this engine is a decrease in efficiency due to the lack of the ability to effectively cool the working fluid when it is compressed and loss when heat is supplied to the cooled cylinder.

The technical result of the invention is to increase the efficiency of the piston engine.

The specified technical result is achieved by the fact that in the cycle C-3tp of the reciprocating engine, the working fluid is first compressed in a multi-stage compressor, while cooling to the temperature at which compression began. Then the working fluid is moved to the combustion chamber, where heat is maintained while maintaining volume. And then the working fluid is moved to the working cylinder, where it is expanded to prevent heat loss, transferring the expansion energy to the working shaft of the engine and to the drive of the multi-stage compressor. The amount of heat supplied to the combustion chamber is controlled by equalizing the degree of increase in the pressure of the working fluid in the combustion chamber and the value ε ^k-1 , where ε is the degree of expansion of the working fluid in the working cylinder, and k is the exponent of the expansion adiabat.

The proposed method of operation of a piston engine allows you to create the necessary conditions for the implementation of a cycle close to the cycle S-3TP. Compression of the working fluid in a multistage compressor with simultaneous intensive cooling allows a compression process close to isothermal, and thereby reduce the cost of compression work. The supply of heat in a thermally insulated chamber of constant volume can significantly reduce the loss of high potential heat when it is supplied. Limiting the amount of fuel supplied in the combustion chamber in accordance with the value of ε ^k-1 allows not to remove heat at the end of the cycle and not to recover it. Thermal insulation of the working cylinder and piston head of the working cylinder allows the expansion process to be close to adiabatic and to reduce heat loss during expansion of the working fluid.

The specified technical result is achieved by the fact that the piston engine contains a multi-stage compressor, a combustion chamber, a working cylinder and a backup cylinder, separated by controlled valves. In a multi-stage compressor, at least two cooled cylinders are installed with paired double-acting cooled cooled pistons. Cooled cylinders are closed with covers with the possibility of moving the working fluid from the above-piston space of the cylinders to the under-piston space and moving the working fluid between the cylinders. The combustion chamber contains a body insulated with a ceramic layer, a nozzle for supplying fuel, a spark plug. A piston is installed in the working cylinder, combined by a crankshaft with twin compressor pistons. The inner surface of the working cylinder is up to 1/2 of the piston stroke from the top dead center, as well as the inner surface of the cover of the working cylinder and the piston head of the working cylinder are insulated with a ceramic layer. The compressor output is connected to the input of the combustion chamber and the backup cylinder, and the output of the combustion chamber is connected by a thermally insulated pipe to the input of the working cylinder.

Figure 1 presents a diagram in the coordinates (P, V) of a theoretically calculated cycle C-3tp of a piston engine with the following parameter values: the degree of pressure increase λ = 2.107, the degree of expansion ε = 12; compression polytropic coefficient n = 1.1 (close to isotherm); expansion adiabatic coefficient k = 1.4. In the diagram, curve 1-2 represents the compression process, segment 2-3 represents the heat supply process, curve 3-4 represents the expansion process. In this case, the thermal efficiency of the cycle is 0.932, which, taking into account thermal and mechanical losses in a real engine, allows to obtain an effective efficiency of the order of 0.6.

Figure 2 presents a possible implementation of the design of a piston engine operating according to the proposed method.

The engine contains a multi-stage compressor A, a combustion chamber B and a working cylinder C. Compressor A consists of two cylinders 2, 3, and the diameter of cylinder 3 is less than the diameter of cylinder 2. Cylinders 2, 3 are installed in the cooled case 4 and are closed with covers 5, 6 on top and lids 7, 8 from the bottom. The caps 5, 6, 7, 8 are equipped with automatic valves 9, and the cap 5 is connected to the cap 7, the cap 6 is connected to the cap 8, and the cap 7 is connected to the cap 6 bypass tubes 10. In the cylinders 2, 3 are installed pistons paired with a common crank pin 11, 12 double-acting with tubular rods of different diameters. An inlet pipe 13 with an automatic valve 14 is installed on the cover 5 of the cylinder 2. A pipe 15 is connected to the cover 8 through the automatic valve 9, which exhausts compressed air from compressor A and leads it to the backup cylinder 16 through the controlled valve 17 and to the combustion chamber B through the controlled valve 18. The combustion chamber B is installed above the working cylinder C, connected to it through a controlled valve 19 with a thermally insulated pipe 20 and consists of a housing 21, thermally insulated from the inside with a ceramic layer 22, an inlet controlled valve Ana 18, nozzles 23 for supplying fuel and a spark plug 24. A working cylinder C, in which a piston 26 with a head 32 insulated with a ceramic layer is installed, is insulated from the inside in its upper part to 1/2 of the piston stroke with a ceramic layer 25. A cylinder C is installed heat-insulated ceramic layer 28 cover 27 with controlled inlet valve 19, exhaust valve 30 and with exhaust pipe 31. The working piston 26 and the paired pistons 11,12 of the compressor A are connected to a common crankshaft 34 through the connecting rods 32 and 33.

The operation of a piston engine according to the method of the invention is as follows. When the crankshaft 34 is rotated, the working piston 26 and the paired pistons 11, 12 of the compressor A move in opposite directions (in FIG. 2, the piston 26 moves up and the pistons 11, 12 down). Moreover, in the volume of the cylinder 2 above the piston 11, air is drawn in through the nozzle 13 and the automatic valve 14, and in the sub-piston volume of the cylinder 2, the second stage of air compression is performed with its simultaneous movement through the bypass cooled tube 10 with automatic valves 9 into the over-piston space of the cylinder 3, where the third stage of compression is carried out. At this time, the fourth stage of air compression is carried out in the piston volume of the cylinder 12 and it is forced into the combustion chamber B or into the reserve cylinder 16 through the tube 15 with an automatic valve 9, depending on the position of the controlled valves 17 and 18. At this time, the working piston 26 ends the displacement exhaust gas from cylinder C through the controlled valve 30 and exhaust pipe 31. At the same time, compressed air is supplied to the combustion chamber through the controlled valve 18 and, when the piston 26 approaches the top dead center, the top liv through the nozzle 23, which is mixed with air and ignited by the spark plug 24 when starting the engine and from the hot walls of the combustion chamber when the engine is running. The fuel combustion process occurs when the valves 18 and 19 are closed. When the piston 26 approaches the top dead center, the valve 31 closes and the valve 19 opens and the working fluid from the combustion chamber B begins to flow into the working cylinder C and the piston stroke 26 starts to take place. B compressor A at this moment in the above-piston space of cylinders 2, 3, the process of compression of the first and third stages begins with the simultaneous movement of air through the bypass cooled tubes 10 with automatic valves 9 into the under-piston space of qi lindrov 2 and 3 respectively. Further, with each revolution of the crankshaft, the cycle repeats.

An analysis of the known technical solutions in this area did not reveal ways of implementing a cycle of piston engines and piston engines themselves with the above set of distinctive features.

Claims (5)

1. A method of implementing a piston engine cycle, characterized in that the working fluid is compressed in a multi-stage compressor, while cooling to the temperature at which the compression began, then it is transferred to the combustion chamber, where heat is maintained to the working fluid while maintaining volume, and then it is transferred to the working cylinder, where the working fluid is expanded to prevent heat loss, transferring the expansion energy to the working shaft of the engine and to the drive of the multi-stage compressor, while the amount of heat supplied to the combustion chamber is controlled, equalizing the degree of increase in the pressure of the working fluid in the combustion chamber and the quantity ε ^k-1 , where ε is the degree of expansion of the working fluid in the working cylinder, ak is the exponent of the expansion adiabat. 2. A piston engine including a multi-stage compressor, a combustion chamber, a working cylinder, a crankshaft and a backup cylinder, characterized in that at least two cooled cylinders are installed in the multi-stage compressor with paired double-acting cooled pistons, the cooled cylinders are closed caps with the ability to move the working fluid from the above-piston space of the cylinders to the under-piston space and move the working fluid between the cylinders, a backup cylinder with is ignored by a controlled valve, a combustion chamber containing a thermally insulated body is equipped with a nozzle for supplying fuel, spark plugs and controlled valves for supplying and discharging a working fluid, a piston is installed in the working cylinder, combined by a crankshaft with paired compressor pistons, the inner surface of the working cylinder, the inner surface the working cylinder covers and the piston head of the working cylinder are thermally insulated, while the compressor output is connected to the input of the combustion chamber and the backup llonom and combustor outlet is connected to the input of a thermally insulated pipe working cylinder. 3. The piston engine according to claim 2, characterized in that automatic valves with bypass tubes attached to them for moving the working fluid are installed in the cylinder covers of the multistage compressor. 4. The piston engine according to claim 2, characterized in that the paired pistons of the multi-stage compressor are equipped with tubular cooled rods. 5. The piston engine according to claim 2, characterized in that the inner surface of the working cylinder is up to 1/2 of the piston stroke from the top dead center, the piston head of the working cylinder and the inner surface of the combustion chamber are coated with a heat-insulating ceramic layer.

Images