SU45562A1 - Injection carburetor for burning oil in boiler furnaces or for internal combustion engines - Google Patents

Description

The thermal or mechanical effect produced by burning a mixture of air or liquid fuel (for example, hydrocarbons) is maximum at a certain well-defined ratio of these two substances. This ratio should remain unchanged, regardless of the mode under which the carburetor is operating.

A carburetor satisfying this basic requirement is automatic. If the carburetor is to produce the optimum effect, then the mixture of air and liquid fuel should be as homogeneous as possible, in other words, all particles of both air and liquid fuel that make up the mixture should participate in the combustion process.

The present invention makes it possible to satisfy these two basic conditions necessary for the proper functioning of the engine.

The proposed injection carburetor for burning oil in boiler furnaces or for internal combustion engines with heating of combustible liquid consists of a suction pipe, inside which the transverse part is located, with a diffuser placed along the axis, to which a combustible liquid is fed through diametrically located nozzles and air.

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At a distance from this diffuser, a second diffuser is located along the pipe axis, having a truncated cone shape and provided with fins on its outer surface adjacent to the inner surface of the third diffuser entrance cone and forming helical channels for passing part of the air to swirl the mixture.

Near the narrowing of the third diffuser, an annular passage is provided in the suction pipe, through which fluid flows from the feed tank, so that this fluid, which then enters the tank at a constant level, is gradually heated to a temperature that allows direct application of the fluid.

The suction pipe is provided with openings for the intake of additional air, which passes through the annular space between the inner wall of the pipe and the outer wall of the third diffuser, after which this air is displaced with the combustible mixture from air and fuel.

In FIG. 1 shows a schematic vertical longitudinal section of an injection carburetor for internal combustion engines;

-fig 2 is a cross-section along AB in FIG. one; FIG. 3 is the same in another form of Execution; FIG. 4-side view of the second

diffuser ..

The tank, in one way or another, is connected to the suction pipe B, containing the carburetor. Through the pipe b, the air is directed in the direction indicated by the arrows, which serves to suck, spray and burn the liquid fuel contained in the tank a at a constant level.

Inside the pipe b there is a transverse part c, the axis of which, passing along the direction of the line AB, coincides with one of the diameters of the pipe b.

The transverse part c is provided with three holes — one hole is transverse and has an axis that coincides with the axis XX of the suction pipe b, the other two holes are longitudinal: and lie one on the extension of the other along the line AB. On the axis of the cross hole is a diffuser d. A small tube with nozzle e is located inside one of the axial orifices of the transverse part c, one end of which communicates with the diffuser d and the other end passes through the wall of the pipe b.

The second diametrically disposed opening is provided with a small tube with a nozzle /, one end of which is immersed in liquid fuel located in the vessel a with a constant level, and the other end of the pipe ends inside the diffuser d.

At a sufficient distance from the diffuser (and on the extension of its axis, there is a second diffuser g (shown separately in Fig. 4) inserted into the converging part of the third diffuser I. This second diffuser has an external shape of a truncated cone, the larger base of which is entrance to the diffuser.

The lateral outer surface of the diffuser g is provided with screw ribs A whose edges rest on the inner surface of the entrance cone of the third diffuser i, the outer surface of which is cylindrical and in contact with the walls of the pipe b. The diffuser i is provided at its periphery with a sharpening that forms the annular space k.

The air required for burning the fuel moves inside the pipe b in the directions indicated by the arrows. A portion of the air, as seen in FIG. 1, passes through the diffuser d, while its remainder is divided into two streams. One of these flows moves through the central opening of the diffuser g, and the other through the screw channels / formed by the fins / g, the outer surface of the wall of the diffuser g and the inner surface of the entrance cone of the diffuser i.

The air passing both through the diffuser d and through the diffuser g serves for three processes: sucking the fuel from the reservoir and through the nozzle /, spraying this fuel during a sharp collision, preferably at a right angle, air jets and fuel, and sucking some the amount of outside air under atmospheric pressure through the nozzle e into the diffuser d.

The stream of air sucked from the atmosphere into the diffuser d through the nozzle, as if squeezes or chokes the air stream passing through the diffuser d, and causes in it the formation of some pressure with the opposite sign.

This braking or squeezing caused by the action of atmospheric air sucked through nozzle e is proportional to the mode changes experienced by the air passing through pipe b, and has a corresponding effect on the fuel intake sucked from tank a with a constant level through the nozzle /.

Thus, the flow of fuel is subject to automatic braking, which, as already mentioned, gradually increases with increasing air velocity through the pipe b and, therefore, through the diffuser d.

The described device thus makes it possible to carry out the first of the above conditions for the automatic operation of the machine, i.e., maintaining a constant relationship between air and fuel, regardless of the mode at which the burner operates with preheating of the liquid fuel.

The second condition is necessary for maximum hardware efficiency.

it is satisfied that air and fuel are mixed as described above, i.e., so that all particles of both air and the atomized fuel are involved in the combustion process. The part of the air that flows through the pipe b, in the direction indicated by the arrows, and which does not pass through the diffuser g, is best to deviate from the direct path and force it to pass through the channels /, and the air, under the action of the screw-shaped channels, acquires The movement is helicoidal and centrifugal relative to the axis XX. Under the action of curved ribs / g located between the diffuser g and the inlet cone of the diffuser /, the air passing through the channels / formed by these ribs acquires and maintains a vortex motion around and along the axis XX. This air meets at a certain angle the flow of an air mixture with the atomized fuel coming out of the exit cone of the diffuser g, as a result of which the entire mixture swirls and the sprayed fuel evenly distributes under its own mass, in the exit cone of the third diffuser g and evenly mixes inside it outlet cone with air coming from the channels.

In the embodiment shown in FIG. 3, a device is provided in which the fuel that is sucked through the nozzle / from the vessel a with a constant level no longer enters the diffuser d through a single hole diametrically opposite the end of the nozzle e, but passes through a semicircular groove t located around the diffuser d . Fuel is now drawn in from this groove, t, through two or more openings of gas, with the help of air passing through a diffuser; These openings n are located in the wall of the diffuser d and establish communication between the groove m and the inside of the diffuser, as a result of which the fuel can be sprayed, as has already been described above.

When the carburetor is working, the necessary preheating of the fuel is achieved as follows. Liquid fuel flows from the reservoir, not shown in the drawing and located higher than the carburetor. The fuel enters through the pipeline about into the space p, where it is partially connected with the heat generated in the ignition chamber, namely through the walls of the diffuser i and through the annular space r.

The fuel, heated to the proper degree, flows from the space p through the channel S into the vessel a with a constant level.

The walls of the suction pipe b are provided with windows t leading to the annular space k formed by sharpening on the third diffuser L The mixture flow, which is in the burning state and leaving the diffuser g, sucks through the windows t some additional atmospheric air that passes through the annular space g and is attached to the combustible mixture.

Opening more or fewer windows t or adjusting their cross-section using any suitable device, you can control the air flow from windows t and control the preheating of the fuel circulating in the space p.

Air can be supplied to pipe b under pressure or mixed with any suitable substance using any suitable mechanical device. Similarly, it is possible to introduce into the diffuser d not air moving through pipe b, but any substance (air, vapors or the like) under the necessary pressure through additional wiring, which allows, if necessary, to enhance the absorption or spraying of the liquid fuel. .

The subject matter of the invention.

Claims (3)

1. An injecting carburetor for burning oil in boiler furnaces or for internal combustion engines with heating of a combustible liquid, characterized in that three diffusers d, g and i are successively positioned along the axis of the suction pipe, through a transversely arranged nozzle of combustible liquid and through the diametrically opposed located air nozzle e. 2. The form of the carburetor Claim 1, characterized in that the second diffuser g, inserted into the converging part of the third diffuser i, is provided on its outer surface with fins forming helical channels / for passing part of the air in order to swirl the mixture. 3. The embodiment of the carburetor according to claim 1, characterized in that the third diffuser i is provided with sharpening, forming an annular space, communicating through the window t with the outside atmosphere for admission through the annular space r of additional air. fng 4 / B fig.E fig.Z