DE480580C - Charging method for internal combustion engines with a displacer seated on the working piston - Google Patents

Description

Loading method for internal combustion engines with one on the working piston seated displacer The subject of the invention is a charging method for prechamber internal combustion engines, those on the working piston have a displacement pin penetrating into the antechamber neck sits, in which furthermore the air in the part pinched off at the end of the piston stroke of the working cylinder is highly compressed and partly in the prechamber on the displacer pin is pushed along, partly through special bypass channels.

The essence of the invention is that a fuel-air mixture into one of the actual working cylinder and the antechamber or the displacer neck connected mixture chamber, i.e. arranged in a bypass to the antechamber neck is stored and part of the in the working cylinder at the end of the piston stroke Highly compressed and constricted air penetrates the mixture chamber, the fuel-air mixture swirled through and with it, after intimate mixing, passes over into the antechamber.

It is already known in internal combustion engines, the liquid To store fuel in a similar manner, in such a way that by the displacement effect the fuel is supplied and mixed with the combustion air. The supply of liquid fuel, as is known, by an injection pump happens, but complicates the necessary fine control of the fuel drop, its Size is relatively small and when idling z. B. a, 5 mm and at full load about q. mm in diameter.

Furthermore, there are also prechamber internal combustion engines with one on the piston crown seated displacer known, in which the liquid fuel directly is injected into the antechamber and in which part of the in the working cylinder at the end of the piston stroke highly compressed air through shunt channels in tangential Direction is pushed over into the antechamber, where the air is perpendicular in a plane executes a circular motion to the injected fuel and is intimately involved in the process mixed with him.

On the other hand, an advantage for the present procedure is to be cited, that fuel and air already as a mixture in the intended for the preliminary storage Enter space and gasification is, so to speak, second in compression Stage of the mixture formation process takes place. As a result of the introduction of the fuel-air mixture the working cylinder receives a greater kinetic energy useful for mixture formation fed. Finally, the fuel-air mixture introduction enables easy control even the smallest amounts of fuel. The drawing illustrates the subject matter of the invention, for example, namely: Fig. i shows a cylinder head in longitudinal section, Fig.2 in cross section, while Fig.3 to 5 different embodiments represent a mixture chamber schematically, the inlet and outlet channels have been moved to one level for a better overview.

In the exemplary embodiment, an excess of fuel is stored in the fuel-air mixture in the mixture chamber a, which concentrically surrounds the displacement neck b of the cylinder head c. The hot walls of the mixture chamber initiate the gasification of the fuel-air mixture. When the displacement pin f sitting on the working piston opens into the displacement neck b , the highly compressed air enclosed in the actual working cylinder d and constricted by the displacement pin f is more compressed than the air in the prechamber e. The tension striving for equilibrium now creates, with part of the constricted air in the annular gap remaining between the displacer pin f and the displacer neck b, a lively flow flowing into the antechamber e, while the other part of the air enters the mixture chamber a through channels h and the mixture is carried away with it through the channels i into the antechamber e. When the two streams meet, a lively turbulence arises, which propagates into the antechamber e and thus brings about a rapid and intimate mixing with the combustion air.

As a result of the tangential mixture supply through the valve h arises a circular movement in the annular chamber a. Until the displacement effect occurs the fuel-air mixture remains in the annular chamber, as this is up to the relevant point in time is in the pressure equalization.

The circular movement of the fuel-air mixture in the mixture chamber a can be accelerated if the supply channels h are arranged as shown in FIGS so that the air flowing through them is in cocurrent with the mixed flow runs in the annular chamber. In the embodiment of Fig. 4 and 5 on the other hand the channels h are directed so that the air flows opposite to the mixture flow run in the annular chamber. In this case there is a stronger vortex of the two means instead.

The outlet channels i can also be arranged so that they in the same or opposite sense to the direction of movement of the mixture flow are directed in the annular chamber. In the former case (see Fig. 2, 3 and 4) it is avoided that the upstream fuel-air mixture enters the antechamber e prematurely, to prevent pre-ignition. In the second case, shown in Figure 5, this is possible the counter-rotation of the channels i accelerated the fuel-air mixture Exit into the antechamber e.

Another control option is to adjust the mixture pump drive opposite the working piston, so that the pre-storage of the fuel-air mixture can take place in any degree of compression or in any piston position. Furthermore can z. B. in higher load cases of the engine by a certain overload of the Mixture chamber a part of the fuel-air mixture prematurely into the antechamber be urged to take advantage of a longer mixing time with the combustion air; the loading overhang reaching the antechamber can be dimensioned in such a way that Pre-ignition does not occur.

This charging method is not tied to any type of ignition, so it can for hot-head machines or machines with compression ignition (diesel machines) or Machines with 'spark ignition (electric spark plug) are used.

Claims (2)

PATENT CLAIMS: i. Loading method - for antechamber Brennkräfimäschinen, in which a displacement pin penetrating into the antechamber neck sits on the working piston, in which the air in the part of the working cylinder constricted at the end of the piston stroke is also highly compressed and in the pre-chamber partly along the displacement pin, partly through special shunt ducts are pushed over, characterized in that a fuel-air mixture is stored in a mixture chamber (t) connected to the actual working cylinder (d) and the prechamber (e) or the displacer neck (b) , i.e. in a shunt to the prechamber neck, and a Part of the air, which is highly compressed and constricted in the working cylinder at the end of the piston stroke, penetrates into the mixture chamber (a), swirls through the fuel-air mixture and, after being intimately mixed, passes with it into the antechamber (e). 2. Device for carrying out the method according to claim i, characterized in that that the mixture chamber (a) encloses the displacer neck in the form of an annular chamber, and that the inlet and outlet channels (h and 2 @, which the mixture chamber connect with the antechamber and the working cylinder, in the same or opposite Sense to the direction of movement of the mixed flow are directed in the annular chamber.