RU2746820C2 - Method for internal combustion engine operation - Google Patents

Abstract

FIELD: internal combustion engines.

SUBSTANCE: invention can be used in internal combustion engines. The method of operation of the internal combustion engine is that the preliminary prepared compressed fuel mixture is sucked through the intake valve (12) into the over-piston space of the working cylinder (8) by lowering the piston (24) from the position that is as close as possible to the cylinder cover. The fuel mixture is ignited with a plug (16) located in the cylinder cover. The resulting combustion products are expanded due to the continued lowering of the piston (24), with the transfer of work to the output shaft (14). The ignition of the fuel mixture is carried out at the very beginning of the process of sucking it into the cylinder (8), placing the plug (16) in the flow of the fuel mixture leaving the intake valve (12). The intake valve (12) is left open during the combustion process. The intake valve (12) is closed at the time of lowering the piston (24) by an amount equal to the full stroke of the piston divided by the specified degree of adiabatic expansion in the operating cycle of the engine.

EFFECT: more complete expansion of the combustion products.

3 cl, 3 dwg

Description

The invention relates to engine building and can be used to improve piston internal combustion engines intended for land transport and small aircraft.

In terms of weight and dimensions, the indicated application is most suitable for reciprocating internal combustion engines (hereinafter ICE) operating according to the Otto cycle (see for example: DM SHIFRIN Thermal engines. Part 1. State publishing house of machine-building literature. M., 1962, p. 100-222). Ideally, the working process of such engines consists in preliminary preparation of a compressed air-fuel mixture, which is placed in a closed chamber, in which the mixture is ignited, keeping the volume practically constant during the entire combustion time, and then the resulting combustion products expand, increasing the volume of the chamber by moving the piston. and transfer the work of the piston to the output shaft of the engine. Thus, ideally, the Otto thermodynamic cycle is realized, which consists of successively performed processes: adiabatic compression, isochoric combustion and adiabatic expansion.

Most often, compression, combustion and expansion are performed in the same cylinder. Structurally, this seems to be the simplest solution. However, it is complicated by the problem of organizing gas exchange, because of which it is necessary to allocate half of the working time of the piston for inlet and outlet (4-stroke cycle), or use a not completely reversible one, i.e. rather dissipative, cylinder purging operation at bottom dead center (2-stroke cycle). If we use different cylinders for compression and expansion, or different cavities of one cylinder, then it is possible to correctly carry out the entire cycle in one revolution of the crankshaft. This is used in various so-called split-cycle engine implementations.

The most famous representative of this design is the Carmelo Scuderi engine (USA) (see RF patent No. 2286470, 2002-2006, Fig. 7). In fact, it implements the same method of operation indicated above as in conventional engines operating according to the Otto cycle (for some parametric deviations, the rationality of which is in conflict with scientific ideas). However, formally, the engine diagram presented in this patent is more suitable than others for analyzing the disadvantages of the ICE operation method according to the Otto cycle, since this scheme contains all the structural elements necessary for the implementation of the proposed method of operation of the internal combustion engine, which differs from the Otto cycle, and there are also two essential features necessary for the proposed method, consisting in the separation of the compression and expansion processes, as well as the fact that the piston, in the moment of the beginning of the suction of the combustible mixture is as close as possible to the cylinder cover.

Let us consider the disadvantages of the method of operating an internal combustion engine according to the Otto cycle using the engine described in the aforementioned RF patent and presented, with insignificant abbreviations, in FIG. 1 of this application.

Implemented in the known engine, the closest to the proposed one, the known method of operation consists in the fact that the pre-prepared compressed combustible mixture located in a special storage chamber 1 is sucked through the inlet valve 2 by the power piston 3 into the working cylinder 4. Moreover, it is essential that in the considered prototype, at the beginning of suction, the power piston 3 is as close as possible to the cylinder cover 5. After a certain volume of the combustible mixture is sucked into the combustion chamber 6, the inlet valve 2 is closed and the combustible mixture is ignited with a spark plug 7, thus producing. the process of isochoric heat supply, i.e. at constant volume. Then the piston 3 is lowered, producing an adiabatic expansion of the combustion products with the transfer of the work of the piston 3 to the engine output shaft. Part of this work is used for the subsequent adiabatic compression of air (or the combustible mixture - it does not matter) used in the following engine cycles. Thus, with the exception of the above-mentioned, which is not of fundamental importance, the permutation of the compression and expansion processes, we have the Otto cycle. In the patent under consideration, emphasis is placed on the importance of the process of delaying the ignition timing by 30-60 degrees of crankshaft rotation after top dead center. But this is an unconditional drawback (which, however, is not of fundamental importance for a comparative analysis of the methods in essence). The phase shift of a separate compressor piston, which is the main (according to Scuderi) distinctive feature of its technical solution, is also insignificant. Between the compressor and the working cylinder 4 there is a storage chamber 1 (in fact, a receiver), the volume of which can (and should, as is done in the subsequent patents of Scuderi) be increased indefinitely.

Further, as is usually done in applications for an invention, it would be argued to point out the disadvantages of the known method, the elimination of which is the purpose of the claimed invention. However, we can only eliminate what the laws of nature allow us. But usually it is not known a priori what disadvantages can be eliminated by the invention and what advantages will be obtained. Therefore, first it is better to consider the new technical solution, and then see how it is better than the old one. The identified advantages and will be considered as the "object" of the invention.

The proposed method of operation of the internal combustion engine, which consists in the fact that a pre-prepared compressed combustible mixture is sucked through the inlet valve into the above-piston space of the working cylinder by lowering the piston from the position as close as possible to the cylinder cover. The difference from the prototype discussed above is that the combustible mixture is ignited at the very beginning of the suction process, placing the spark plug in the path of the combustible mixture flow coming from the inlet valve. In this case, the above-piston space of the working cylinder is filled not with a combustible mixture, but with a flame, that is, with hot gases in the combustion stage. In this case, combustion occurs at constant pressure, i.e. isobaric, which is ensured by the open inlet valve, which maintains the communication of the working cylinder with a large-volume receiver, in which the pre-compressed combustible mixture is located. Combustion propagation through the inlet valve is avoided because the flow rate in the inlet valve slit is usually much higher than the flame propagation rate (if at all, the flame is able to propagate through the gap). In addition, a flame retardant metal mesh (as in the Devi miner's lamp) can always be placed in the intake duct. After a certain amount of hot gas has been sucked into the cylinder, which at this point in time is already the product of an almost complete combustion process, the inlet valve is closed, i.e. produce the so-called. h. "Cutoff of the intake", as in a steam engine, and produce an adiabatic expansion of the combustion products. In this case, the intake cutoff moment is determined from the condition of obtaining a given expansion coefficient of the combustion products, i.e. obtaining a complete or almost complete expansion.

The proposed ICE operation method, as well as the split-cycle engine operation method taken as a prototype, can provide:

a) complete expansion of combustion products and, therefore, allows you to get rid of the exhaust silencer.

b) as in the prototype, the process of starting the engine is facilitated, because at start-up, the pressure in the receiver is zero and the start-up begins with a zero compression ratio, i.e. without push.

c) as in the prototype, a two-stroke cycle is ensured without the use of irreversible highly dissipative blowing processes.

However, in comparison with the prototype, there are the following additional advantages due to the transition from isochoric combustion to isobaric:

1. The conditions for the occurrence of detonation combustion are eliminated, since, in contrast to combustion in a closed chamber, there is no increase in pressure with a corresponding increase in the compression temperature of the residual portions of the combustible mixture. There is no combustible mixture in the combustion chamber at all, because the already practically burnt substance is admitted into the cylinder, and it is not subjected to further compression. Thus, the engine becomes almost all-fuel, so that you can forget about what the "octane number" is. The only requirement for fuel quality is its volatility. This reduces the cost of motor fuel and increases its available resources.

2. In connection with the elimination of the high-temperature peak pressure of the indicator diagram, the effects of the so-called. "Hardening" of products, dissociation, as well as nitrogen oxides in the exhaust gases. So high emission requirements can be met without the need for expensive catalytic converters.

3. Cutting off a sharp peak of pressure and replacing it with a long plateau on the PV diagram additionally (compared to the above correct transition to two-stroke) reduces the uneven torque on the shaft, which is a source of strong vibrations in the transmission.

4. The ignition system is simplified, because A high-voltage spark plug can, and even should, be replaced with a glow plug without requiring any additional measures to synchronize its operation (for example, in the form of selecting the glow strength of the plug or selecting the degree of its protrusion into the combustion chamber). In this case, the candle will consume only low-voltage power, and only at start-up or with a strong decrease in load, maintaining the glow in cruising mode due to hot gases. It also improves the reliability of cruise operation, which is very important for an aircraft engine, most of whose failures are associated with the electrical ignition system.

5. The weight of the structure of the cylinder-piston group and the crank mechanism is reduced, because it is proportional to the product of the peak cycle pressure and the volume swept by the piston, i.e. is proportional to the so-called overall area of the indicator PV diagram of the cycle, which, as will be proved below, is less for an isobaric cycle with full expansion than for an isochoric cycle with full expansion.

6. The restrictions on the maximum number of revolutions on the part of the quality of combustion processes are removed, since Ignition of the combustible mixture is carried out by direct contact of each element of the volume of the combustible mixture with the glow plug during its passage through the inlet channel in which the plug is installed. Thus, the speed-limited process of spontaneous flame propagation through the volume of the combustion chamber is eliminated.

As a possible embodiment of the proposed method, it is proposed to use the sub-piston space of the working cylinder instead of a separate compressor cylinder.

It is proposed to regulate engine power, as a possible option, by changing the intake cut-off phase, acting on the intake valve control system. In this case, it is proposed to maintain the optimal pressure of the working cycle by changing the so-called "harmful volume" of the space of the compressor performing preliminary compression (in particular, the sub-piston space of the working cylinder, if it is used as a compressor).

The invention is illustrated by the following description of examples of implementation of the method and three figures.

FIG. 1 shows a fragment of a schematic diagram of a known split-cycle engine.

FIG. 2 shows a diagram of the engine, optimized in relation to the implementation of the proposed method.

FIG. 3 shows, for comparison, in a common coordinate system superimposed on one another PV diagrams of ICE operation according to the proposed method and according to the method taken as a prototype.

A split-cycle engine optimized for the implementation of the proposed method comprises a cylinder 8, the above-piston space of which is used as an expansion mechanism, and the sub-piston space as a compressor. There is a receiver 9 connected by means of an automatic pressure valve 10 to the piston space. Also connected to the sub-piston space is a chamber 11 of an adjustable volume, which serves to change the volume of the harmful space of the compressor in order to regulate the pressure of the engine operating cycle. The receiver 9 is also connected to the over-piston space of the cylinder 8 by means of an intake valve 12 controlled by a cam 13 attached to the engine crank 14. Moreover, the cam 13 is made two-dimensional, i.e. multitrack, which allows you to quickly control the intake cutoff moment, thus changing. engine power. A glow plug 16 is installed in the combustion chamber 15 of the engine. It is located in the inlet channel 17 under the inlet valve 12 directly at the entrance to the cavity of the combustion chamber 15. The plug 16 has a glow body made of high-temperature ceramics, and is equipped with an electric heating conductor and a temperature sensor, for example, silicon carbide having electrical leads located in the cold zone of the glowing body. The electrical leads of the plug 16 are connected to a low-voltage power source and to an automatic temperature controller. The exhaust valve 18 is controlled by a cam 19 attached to the crankshaft 14. The receiver 9 is in communication with the mixture preparation system 20. In a particular embodiment, it consists of a continuous liquid fuel injector 21, i. E. not synchronized, action, and a chamber with an evaporating nozzle 22, made, for example, of mineral wool, fixed between two metal grids 23, also performing the function of a flame-barring filter. The piston 24 is connected to the crankshaft by means of a rod and a connecting rod with a crosshead guide mechanism.

This engine operates in accordance with the proposed method as follows.

To start, rotate the crankshaft 14. In this case, the excess pressure in the receiver 9 is initially equal to zero, so a lot of effort is not required to start. In this case, almost the entire stroke of the piston 24 is accompanied by the process of air injection into the receiver 9. In this case, the selection of air (or the combustible mixture) from the receiver 9 through the inlet valve 12 corresponds to a small part of the piston stroke, so the pressure in the receiver rises rapidly. With an increase in pressure, the density of the gaseous substance taken into the cylinder increases, and at a certain pressure, a balance is established between the intake and flow rate, corresponding to the operating pressure of the cycle. If in this case the fuel injector 21 works, then, evaporating on the large surface of the nozzle 22, the fuel is mixed with air from the receiver, and the combustible mixture is sucked into the combustion chamber 15. Passing in the inlet 17 past the glowing plug 16, the combustible mixture ignites, and into the chamber combustion enters already in the form of a combustion torch sucked in by the piston 24. In this case, the pressure in the combustion chamber 15 remains practically constant, since it is stabilized due to the relatively large volume of the receiver 9, with which the combustion chamber communicates through the open intake valve 12 during combustion.

Let's consider this process in more detail, since it is key in the operation of the engine according to the proposed method.

Before the start of the opening of the intake valve 12, there are combustion products from the previous cycle in the intake pipe 17 and in the above-piston slot (i.e., in the minimum volume of the combustion chamber 15) that cannot be burned. Then the valve 12 is smoothly opened, and, practically simultaneously, the piston 24 begins to lower. At the same time, a front of a relatively dense combustible mixture begins to propagate along the channel 17, which penetrates into the hotter and less dense residual combustion products. When the front of the combustible mixture touches the hot zone of the plug 16, the mixture ignites. In this case, the flame at the first moment begins to spread back to the valve 12. As a result, the total volume of gases under the valve increases. The piston 24, being near top dead center, moves slowly and may not compensate for the indicated increase in volume. This will result in a slight surge in inlet pressure and a pause in the suction process until the descending piston compensates for the increase in volume. The amount of volume increase is determined by the expansion coefficient of the volume of the combustible mixture located in the space between the spark plugs 16 and the valve 12, and is relatively small. However, a slight backflow of the combustible mixture through the valve into the mixing chamber 20 may occur. This will somewhat deplete the mixture above the valve 12. But soon the process of suction of the combustible mixture will continue and a stationary process of overflow of the combustible mixture through channel 17 past the glowing plug 16 will be established, accompanied by continuous ignition of the mixture flow entering the above-piston space of the combustion chamber 15. In this case, the speed of the combustible mixture the mixture in channel 17 does not exceed several tens of meters per second, because the speed of the piston at the beginning of its movement from the upper dead center is small. Therefore, the glow plug temperature required for stable ignition of the flow will be about 1200-1400 degrees, celsius (see the book. S. KUMAGAI, "Combustion", M. Ed. Chemistry, 1979, pp. 68-74.) The required surface area in this case, the candles are 1 cm square, and the power of the starting electric heating of the candles is about 30 watts.

At a later stage of the intake of the combustible mixture, when the piston speed increases, the above condition of stable ignition at high engine speeds may be violated. However, in this case, the combustible mixture will already be poured into a sufficiently large volume of hot gas accumulated in the combustion chamber 15 and will ignite from it.

At the right moment, determined by the controlled two-dimensional cam 13, the intake valve 12 closes, and the process of expansion of combustion products begins. In this case, combustion can be considered almost complete, which is facilitated by strong turbulization of the combustion flame during the intake process, as well as the direct contact of the spark plug 16 with each element of the volume of the combustible mixture during its passage through the intake channel 17.

After the piston reaches the bottom dead center, the cam 19 opens the exhaust valve 18 and the piston 24, during its upward return stroke, pushes the combustion products into the atmosphere. In this case, the expansion coefficient, determined by the intake cut-off moment, can be chosen such that the expansion is complete or almost complete in order to ensure quiet exhaust. At the same time, in contrast to engines operating according to the Otto cycle, a large expansion coefficient is not required, because peak pressure is many times lower (about 10 atm). So the combustion chamber remains, on average, thick enough to provide acceptably low heat transfer to the walls.

The engine power can be controlled by a coordinated change in the intake cut-off moment and the total sub-piston (so-called harmful) volume of the compressor cavity. In this case, the intake cutoff is changed by moving the cam follower to another track of the two-dimensional cam 13. If the intake cutoff is performed earlier, the volume of gas taken off during the cycle will decrease and the pressure in the receiver will increase. This can be compensated for by reducing the compressor discharge volume, which strongly depends on the volume of the harmful space, which in this engine is controlled by the chamber 11, by moving the control piston 25 located in it. An increase in the “harmful” compressor volume leads, as is known, to a decrease in the discharge volume into the receiver - up to the complete cessation of injection, if the pressure in the receiver exceeds the compression ratio of the piston.

In conclusion, let us consider what caused the possibility of reducing the specific mass of the cylinder-piston group and the crank mechanism when working according to the proposed method.

The mass of these mechanisms changes in proportion to the product of the maximum pressure in the operating cycle of the engine and the volume swept by the piston. On the PV diagram of the engine, this is represented by the area of a rectangle circumscribed around the workflow indicator diagram (also called the overall area of the PV diagram).

FIG. 3 PV diagram of the engine operation according to the proposed method, i.e. constant pressure combustion (shaded areas "a" and "d") is aligned with the Otto cycle diagram, in which the area "b" is added to these areas, corresponding to the pressure peak during isochoric combustion occurring at constant volume. By scaling, the indicated diagrams in the lower parts are aligned, which does not affect the result of comparing the specific weights of the engines. Let us consider the coefficients of the increase in the mass "Km" and the indicator work "Кр" during the transition from the isobaric cycle to the isochoric one. Those. Let us determine how much the overall area S of the diagrams and the indicator area of the diagrams increase in this case and determine which of the areas increases more in relative value.

FIG. 3, uppercase Russian letters denote the vertices of the considered rectangles, and Latin areas - the shaded areas of the indicator diagrams.

(a is the area equal to the area of the ZhBGN rectangle)

Kp = b / (a + d).

Comparison is determined by the ratio of the found values

Km / Kp = (b + c) (a + d) / (ab).

Obviously, the resulting ratio is greater than one, since the factors a and b in the numerator are increased by some values of d and c, and in the denominator these increments are absent (note that all calculations are carried out in positive numbers).

The latter means that during the transition from the proposed method of operation of the internal combustion engine to the well-known Otto cycle, the specific gravity of the structure of the main power parts of the engine increases.

However, the result of the above proof also follows from the simple concept of the compactness of the PV diagram of the operating cycle, which noticeably decreases with the appearance of a sharp peak in the pressure increase in the cylinder during isochoric combustion. In this case, it is necessary to repeatedly, and far from proportional to the additional work, increase the strength, and therefore the mass of all parts of the crank mechanism. In this reasoning, for simplicity, the volumes of the engine are assumed to be unchanged, since pressure and volume have almost the same effect on the specific gravity of the engine. The optimization changes are minor compared to the effects discussed here.

The efficiency of the engine when operating according to the proposed method does not change significantly, because it is mainly determined by the coefficient of adiabatic expansion, which in the proposed method, due to a decrease in the upper pressure of the cycle, does not change significantly, although we achieve full expansion. The increase in the expansion coefficient, as in a conventional ICE, is limited by an increase in heat loss to the wall when the combustion chamber acquires a slit-like shape. The fact that in the proposed method at the beginning of the suction process, the combustion chamber is slit-like, is compensated by a possible reduction in the combustion time, tk. the process of spontaneous propagation of the combustion front over the volume of the combustion chamber is excluded. The combustible mixture is ignited forcibly by direct contact of the glow plug with each element of its volume as it passes by the plug in the intake channel. This significantly increases the efficiency of combustion and the maximum possible engine speed, which is usually limited by the quality of combustion more than by the strength of the mechanism. Increasing speed is another possibility of further reducing the specific gravity of internal combustion engines when working according to the proposed method, which is extremely necessary for the possibility of their widespread use in small aircraft, since gas turbine engines in the low power range are not inefficient, and their cost is too high for widespread use.

Claims (3)

1. A method of operation of an internal combustion engine, consisting in the fact that a pre-prepared compressed fuel mixture is sucked through the inlet valve into the above-piston space of the working cylinder by lowering the piston from a position as close as possible to the cylinder cover, igniting the combustible mixture using a candle located in the cylinder cover , and then expand the resulting combustion products, due to the continued lowering of the piston, with the transfer of work to the output shaft, characterized in that the ignition of the combustible mixture is carried out at the very beginning of the process of sucking it into the cylinder, placing the candle in the flow of the combustible mixture leaving the inlet valve, and the inlet valve is left open during combustion, closing it at the moment of lowering the piston by an amount equal to the full stroke of the piston divided by a given degree of adiabatic expansion in the engine operating cycle. 2. The method of operation of the internal combustion engine according to claim 1, characterized in that a sealed sub-piston space of the working cylinder is used as the compressor cylinder. 3. The method of operation of the internal combustion engine according to claim 1, characterized in that the engine power is controlled by changing the intake cut-off phase, acting on the intake valve control system, and the optimal pressure of the working cycle is maintained by a coordinated change in the minimum volume of the compressor cavity of the cylinder between the piston and the discharge valve compressor.

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