RU2136919C1 - Method for supercharging internal- combustion engine - Google Patents

Abstract

FIELD: mechanical engineering; engine manufacture. SUBSTANCE: method involves two-stage variation in volume of cavity connected to its intake manifold at rate proportional to engine speed; minimal volume of cavity is adjusted with admission valve held open for time Δt = (1,0-0,7)t_o, where t_o is time interval within which cylinder intake element is held open. EFFECT: improved efficiency of engine supercharging. 2 cl, 5 dwg

Description

 The invention relates to mechanical engineering, namely to engine building and can be used in intake systems of internal combustion engines equipped with volumetric resonators.

 A method of pressurizing an internal combustion engine is known from the prior art (see French Patent No. 2378183, CL F 02 B 27/00, 1978), comprising exciting harmonic oscillations in a pressurization system of an internal combustion engine.

 A disadvantage of the known method of boosting an internal combustion engine is that it does not provide high boost efficiency, since the oscillations are harmonic, and the pressure change in the intake manifold of the engine is not strictly harmonic.

 There is also known a method of pressurizing an internal combustion engine (see USSR author's certificate N 498407, class F 02 M 35/10, 1976), taken as a prototype and including a two-stage change in the volume of the resonator connected to its intake manifold.

 The disadvantage of this method is that it does not provide high boost efficiency, since it does not create periodic inharmonic oscillations in the intake system of the internal combustion engine, similar to those generated by the engine itself.

 The present invention is aimed at solving the technical problem of increasing the efficiency of pressurization of an internal combustion engine by providing periodic nonharmonic oscillations in the intake manifold of the engine, similar to those generated by the engine itself.

The problem is solved in that in a method of pressurizing an internal combustion engine, comprising a two-stage change in the volume of the resonator connected to its intake manifold, according to the invention, the volume of the resonator changes with a frequency proportional to the number of revolutions of the internal combustion engine, and the minimum value of the volume of the resonator is set when the intake is open the cylinder body for the time Δt = (1.0-0.7) t _o , where t ₀ is the time interval during which the inlet organ of the cylinder is open.

 It is preferable that the stepwise change in the volume of the resonator is carried out at times corresponding to the pressure in the intake manifold equal to the average pressure during a full revolution of the engine crankshaft.

 The advantage of the proposed method over the known one lies in the fact that there is a change in the natural frequency of oscillations of the intake system simultaneously with the onset of various phases of a non-harmonic, periodic change in pressure in the intake system, which leads to an increase in the efficiency of pressurization of the internal combustion engine.

 Indeed, with the cylinder inlet body open, there is a significant change in the pressure in the intake manifold generated by the engine itself over a fairly short period of time. It is in this time interval, according to the proposed method, that the minimum volume of the resonator is set, which corresponds to a high natural frequency of oscillations of the intake system of the engine.

 On the contrary, with the cylinder inlet body closed, the pressure in the intake manifold changes slightly over a fairly long period of time. In this time interval, according to the proposed method, sets the maximum volume of the resonator. In other words, the corresponding natural vibration frequency of the intake system is reduced.

 The present invention is illustrated by specific examples, which, however, are not the only possible, but clearly demonstrate the ability to achieve the above set of essential features of the desired technical result.

 In FIG. 1 schematically shows a boost system of an internal combustion engine; figure 2 and 3 depict embodiments of the resonator; 4 is a view along aa of FIG. 3; figure 5 shows the time dependence of the pressure in the intake manifold.

 The pressurization system of the internal combustion engine 1 for the implementation of the proposed method comprises (Fig. 1) an intake manifold 2 with a throttle 3, a resonator 4 connected to the intake manifold 2 through a channel 5. Inside the resonator 4, a partition 6 with an opening 7 and a separator cavity 4 is installed into two cavities 8 and 9. In addition, the pressurization system comprises an actuator 10 and a locking element 11 for closing and opening the opening 7.

 According to another embodiment, the locking element is made in the form of a rotary damper 12 (FIG. 2) installed in the connecting channel 13 between the cavities 8 and 9 of the resonator 4. In this embodiment, the partition 6 is solid.

 The locking element can be made in the form of a rotating spool 14 with a sector hole 15 (Fig.3 and 4). In this case, a sector hole 16 is also made in the partition 6. The spool 14 is preferably driven from the crankshaft of the engine 1, moreover, for a two-stroke engine, the spool speed is equal to the rotational speed of the engine crankshaft, and for a four-stroke one it is half the last.

 The method of boosting an internal combustion engine is as follows (for example, a four-stroke engine).

 In the phase of the inlet of the internal combustion engine 1, the pressure in the intake manifold 2 decreases. Under the action of the discharge, gas flows not only from under the throttle valve 3, but also through channel 5 from the entire volume of the resonator 4, the volume of which is maximum at this moment: hole 7 is open , the shutter 12 is open, the holes 15 and 16 coincide, i.e. there is an increase in the filling of the engine cylinder.

за период Т (фиг.5) изменения объема резонатора 4 наступает фаза "быстрого" изменения давления во впускном коллекторе 2. В этот момент на исполнительный механизм 10 поступает сигнал на закрытие отверстия 7 (фиг.1) или на поворот заслонки 12. Иными словами устанавливается минимальный объем резонатора 4, соответствующий объему полости 8, а следовательно системе наддува будет соответствовать наибольшая собственная частота колебаний.At the point in time (Fig. 5), the pressure in the intake manifold reaches

during the period T (FIG. 5) of the change in the volume of the resonator 4, the phase of the “rapid” change in pressure in the intake manifold 2 occurs. At this moment, the actuator 10 receives a signal to close the hole 7 (Fig. 1) or to turn the shutter 12. In other words the minimum volume of the resonator 4 is set, corresponding to the volume of the cavity 8, and therefore the highest natural frequency of oscillations will correspond to the boost system.

С этого момента начинается фаза "медленного" изменения давления во впускном коллекторе 2. Этой фазе должна соответствовать более низкая частота собственных колебаний системы по сравнению с фазой "быстрого" изменения давления во впускном коллекторе 2. В результате на исполнительный механизм 10 поступает сигнал, по которому отверстие 7 (фиг. 1) или заслонка 12 (фиг. 2) открываются или отверстие 16 совпадает с отверстием 15 (фиг. 4), а следовательно рабочий объем резонатора 4 ступенчато увеличивается до величины, равной сумме объемов полостей 8 и 9.After passing the bottom dead center (bhp) during the backflow, the pressure in the intake manifold rises and reaches a value

From this moment, the phase of the "slow" pressure change in the intake manifold 2 begins. This phase should correspond to a lower natural frequency of the system compared to the phase of the "fast" pressure change in the intake manifold 2. As a result, a signal is transmitted to the actuator 10, according to which the hole 7 (Fig. 1) or the shutter 12 (Fig. 2) open or the hole 16 coincides with the hole 15 (Fig. 4), and therefore the working volume of the resonator 4 increases stepwise to a value equal to the sum of the volumes of the cavities 8 and 9.

 The phase of "slow" pressure changes in the intake manifold 2 ends after passing the top dead center (bmw) before suction.

- объем резонатора 4 минимален (равен объему полости 8), а при p большим

- объем резонатора 4 - максимален и равен сумме объемов полостей 8 и 9.Thus, when the pressure in the intake manifold 2 is less

- the volume of the resonator 4 is minimal (equal to the volume of the cavity 8), and when p is large

- the volume of the resonator 4 is maximum and equal to the sum of the volumes of the cavities 8 and 9.

It was experimentally established that the duration Δt of closing the hole 7 (overlapping by the shutter 12 of the cross section of the connecting channel 13 or the mismatch of the holes 15 and 16) should be (l, 0 ... 0.7) t ₀ ; where t ₀ is the time interval during which the inlet organ of the cylinder is open.

- показание датчика с большой инерционностью, с моментами ступенчатого изменения объема резонатора 4.The engine is configured as follows. A pressure sensor with a high inertia (2-5) T and a pressure sensor with a low inertia are connected to the intake manifold. Set Δt = t _o and produce a change in Δt until the moments of the pressure sensor coincide with a low inertia of the value

- reading of the sensor with high inertia, with moments of stepwise change in the volume of the resonator 4.

Claims (2)

1. A method of pressurizing a piston engine, for example, an internal combustion engine, comprising a two-stage change in the volume of the resonator connected to its intake manifold, characterized in that the volume of the resonator is changed with a frequency proportional to the number of revolutions of the internal combustion engine, and the minimum value of the volume of the resonator is set when the intake is open the cylinder body for the time Δt = (1.0-0.7) t _o , where t ₀ is the time interval during which the inlet cylinder body is open.  2. The method according to p. 1, characterized in that the stepwise change in the volume of the resonator is carried out at time points corresponding to the pressure in the intake manifold equal to the average pressure for the period of change in the volume of the resonator.

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