ITBO950477A1 - CARBURETOR FOR AN ENDOTHERMAL ENGINE. - Google Patents

Abstract

Carburettor (1) for an internal combustion engine (1a) and having a tank (3) suitable for receiving fuel (2) from an inlet (5) of the carburettor (1) and for feeding fuel (2) to an outlet (6 ) of the carburettor (1); the inlet (5) being engageable by a first pin (20) integral with a floating body (18) contained in the tray (3) and the outlet (6) being engageable by a second pin (24) operable through a first device (13) cam and rocker; a second cam and rocker device (14) being movable in phase with said first cam and rocker device (13) to move a second body (45) inside the tank (3) to obtain determined variations in the fuel level (2) inside the tray (3).

Description

DESCRIPTION

of the patent for industrial invention

The present invention relates to a carburetor for an internal combustion engine.

It is known that an endothermic engine works if fed with a mixture composed of air taken from the environment outside the engine, and fuel, in turn taken from a carburetor fed from a tank. The two components of the mixture mix together inside an intake duct shaped like a Venturi tube, which is arranged downstream of the engine, and ends with an air flow regulation valve featuring a throttle operated by the accelerator. . There is a pressure inside the intake duct, which is lower the more the throttle keeps the intake duct open. Therefore, the intake of fuel from the carburetor and the number of engine revolutions are the higher the more the intake duct is open. Furthermore, the head between the fuel contained inside the carburetor and the intake duct is the less the more the depression inside the intake duct is accentuated, and therefore the more the throttle valve is open.

To rapidly vary the operating conditions of the engine, some carburettors are equipped with a supercharging pump which is activated to reduce the head mentioned above in order to provide, up to the moment in which the new operating conditions reign, a fuel flow out of the carburetor of a higher value than that otherwise provided for the pressure difference alone.

The object of the present invention is to provide a carburetor for an internal combustion engine which allows the operating conditions of the engine to be varied rapidly without the need to use an additional pump and, therefore, is particularly simple and economical.

According to the present invention, a carburetor is provided for an internal combustion engine and comprises a tank arranged at the bottom and adapted to contain fuel; an inlet for feeding fuel to said tank, and an outlet for feeding fuel by suction outside the carburetor; said inlet and outlet being respectively engaged by a first and second substantially vertical pin, said first pin being integral with a vertically movable body and floating in the fuel contained in the tank; first actuation means arranged above said tray for axially moving said second pin; characterized in that it comprises a second body shaped in a determined manner, and guide means binding the said second body to move vertically inside the said tray; and second actuation means movable in phase with said first actuation means being provided to control the displacement of said second body inside the tank, in such a way as to cause determined variations in the level of the free surface of the fuel contained by the tank.

The invention will now be described with reference to the attached drawings, which illustrate some non-limiting examples of embodiment, in which:

Figure 1 is a cross section of a first preferred embodiment of a carburetor according to the present invention;

Figure 2 schematically illustrates a system in which the carburetor of Figure 1 is normally inserted;

Figure 3 is a side elevation view on an enlarged scale of a detail extracted from Figure 2; Figures 4 and 5 are side elevational views on an enlarged scale of some embodiments of the detail of Figure 3; And

Figure 6 illustrates, on an enlarged scale, a detail of a second preferred embodiment of a carburetor according to the present invention.

In Figure 1, the number 1 indicates, as a whole, a carburetor for a positive ignition engine (Figure 2) which can be fed with liquid fuel 2.

The carburetor 1 comprises a tank 3 arranged at the bottom, and adapted to receive the fuel 2 from a tank 4 through a substantially cylindrical inlet duct 5, which is substantially vertical and is arranged on the side of the tank 4 in figure 1. The carburetor 1 it is also provided with an outlet duct 6 which receives fuel 2 from the tank 3, and feeds it to a substantially horizontal outlet 8, which is arranged above, and at a determined distance from the bottom, of the tank 3. The carburetor 1 also comprises another duct 9 for the fuel 2 obtained in the bottom of the tank 3, to hydraulically connect the duct 6 with a cylinder 10, which is open upwards, and extends vertically from the bottom of the tank. 3.

The carburetor 1 also comprises a unit 11 for controlling the opening of the duct 5 for metering the flow of fuel 2 inside the tank 3 in an inversely proportional way to the level of the fuel 2 contained inside the tank 3 itself; and a group 12 for controlling the flow of the fuel 2 exiting the carburetor 1 through the duct 6.

The carburetor 1 also comprises two cam and rocker arm actuation devices 13 and 14 arranged above the tank 3, and a volumetric pumping unit 16, adapted to pump fuel 2 from the tank 3 to the duct 6 through the duct. 9. In particular, the device 13 and the device 14 can be operated in phase, and the device 14 is adapted to operate the pumping unit 16.

The unit 11 comprises an internally hollow toroidal body 18, which is coupled externally to the duct 6 in a freely sliding and angularly fixed manner, and carries, in correspondence with an outlet of the duct 5 facing downwards, a cylindrical pin 20 having a cross section whose diameter approximates in excess of the internal dimension of the duct 5, and ends upwards with a conical end portion 22, so that at a determined position of the fuel level 2 inside the tank 3, the inlet mouth of the duct 5 has a passage opening of predetermined dimensions. In particular, as the fuel level 2 inside the tank 3 drops, there is an increase in the fuel passage opening 2, in such a way as to quickly re-establish a certain fuel level 2 inside the tank 3.

In the same way, the control unit 12 comprises a pin 24 whose lateral surface has a slight taper so that a certain axial position inside the duct 6 corresponds to a passage opening for the fuel 2 from the tank 3 of determined amplitude, and, in any case, the light decreases with the lowering of the pin 24 itself.

The actuation device 13 comprises a pin 26 which is orthogonal to the longitudinal axis of the pin 24 and to which a rocker 28 is pivoted. The rocker arm 28 is connected to the needle 24 through the interposition of a rod 28a coaxial with the pin 24 and belonging to an elastic device 28b, which is able to rotate the rocker 28 in an anti-clockwise direction (figure 1) to bring the needle 24 back to a respective rest position, which corresponds to a minimum flow rate of fuel 2 through the duct 6 Furthermore, the rocker arm 28 is provided, in a substantially intermediate position between the pin 26 and a portion 29, with a tappet roller 30 parallel to the pin 26. The rocker arm 28 is movable with oscillatory motion under the thrust of a cylindrical body 31, which is arranged below the rocker arm 28, is pivoted in correspondence with an axis 32 parallel to the pin 26, and is rotatable around the axis 32 by an angle which approximates 180 ° by default. The body 31 is delimited laterally by a peripheral surface orthogonal to the pin 24, a lateral portion 33 of which (facing upwards in Figure 1), is shaped in such a way as to define a cam 34, which will be described in greater detail below. The body 31 is rotatable around the axis 32 under the thrust of a metal wire 31a and against the action of a known and not illustrated return spring. Naturally, the device 13 comprises, in addition to the pin 26, also the rocker arm 28, the cam 34 and the roller 30.

With reference to Figure 2, it should be noted that the wire 31a is operated together with a known and not illustrated tie rod which operates the throttle valve 32a of the carburetor 1 itself, to increase the air flow to a contracted section 32b of a duct 32c engine intake la.

The pumping unit 16 has a piston 35 which engages the hydraulic seal cylinder 10 and constitutes the lower part of a vertical rod 36, which, with one of its upper ends 38, crosses a separation wall 40 suitable for isolating an upper area of the carburetor 1 containing the devices 13 and 14 for actuation from a lower zone of the carburetor 1 itself. Therefore the cylinder 10 and the piston 35 define a guiding device which keeps the rod 36 constantly vertical.

It should be noted that the pumping unit 16 also comprises a chamber 42 defined by a lower face of the piston 35 and by the lateral and lower walls of the cylinder 10, and that the chamber 42 is fed by the fuel 2 during the stroke towards the of the piston 35, through a suction hole 44 made in the duct 9 in a substantially intermediate position between the cylinder 10 and the duct 6. Furthermore, the rod 36 is provided below the wall 40 and in a raised position with respect to an upper edge of the tray 3, of a cylindrical body 45 better visible in Figure 3, having a longitudinal axis and two faces substantially transverse to the longitudinal axis itself. The body 45 is integral with the rod 36, therefore it is guided vertically by the cylinder 10 and by the piston 35, and its function will be better clarified later on.

It should also be noted that the duct 9 ends on the side of the duct 6 with a cylindrical portion 46 facing and open upwards, which embraces an inlet 6a of the duct 6 itself, isolating an annular portion 48 which, in the case in question, is engaged by an annular gasket 50 of the "o-ring" type, through which the ducts 6 and 9 are connected together in a hydraulic seal.

The rod 36 ends above the wall 40 with an appendage 52, and the device 14 comprises an orthogonal tappet roller 54 to the rod 36 and supported by the appendix 52, and a rocker arm 55 integral with the cylindrical body 31 which, therefore , is movable with an oscillatory motion around the axis 32. The roller 54 is freely rotatable around its own longitudinal axis and is tangent below the body 31 at a respective lateral portion 56 opposite the portion 33 and shaped in such a way as to define a cam 58.

The use of the carburetor will now be described with reference to Figures 1 and 2 and starting from an operating condition in which the engine operates in steady state conditions, and generates a depression of a determined value between the contracted section 32b and the interior. carburetor 1.

At this point, if a user of the engine wants to increase the number of revolutions, he acts on the accelerator to rotate an impeller 60 called "throttle" and, in this way, open the intake duct 32c more. At the same time the thread 31a is pulled in such a way as to rotate the body 31 in an anti-clockwise direction in Figure 1 up to a determined angular position. The body 31, and in particular the cam 34, causes the roller 30 to rotate clockwise around the pin 26, so that the pin 24 is raised from the rocker arm 28 to further open the duct 6. Furthermore, the rod 36 is pushed towards the down from the cam 58 against the thrust of a spring 60a which is contained inside the body 10 between the bottom of the tray 3 and the face of the piston 35 facing downwards. Consequently, the rod 36 moves downwards causing the body 45 to immerse itself inside the fuel 2 contained in the tank 3. Therefore, the head of the fuel 2 with respect to the mouth 8 is reduced very rapidly thanks to the principle of communicating vessels, and for the thrust that the fuel 2 contained inside the chamber 42 and inside the duct 9 receives from the piston 35.

The maintenance of the body 31 and of the rod 36 in their respective last occupied positions, has as a consequence the establishment of new operating conditions, which depend on the greater recall of fuel 2 caused by the lowering of the body 18 and, of course, by the descent of the needle 20, and by a larger opening of the duct 5.

If the user of the engine wants to reduce the number of revolutions, he acts on the accelerator to bring it to the previous position. This operation causes the partial closure of the intake duct 32c, but, what is more important, brings the body 45 upwards, and the rocker arm 28, rotating clockwise, tends to close the duct 6 more. Therefore, the piston 35 is raised , and the flow of fuel 2 towards the port 8 is reduced very rapidly. In fact in this case the device 14 raises the rod 36, so that the body 45 and the piston 35 return to their respective positions previously occupied.

Thanks to the principle of communicating vessels and to the suction of the fuel 2 contained in the duct 6 and in the tank 3 through the hole 44 by the piston 35, the flow rate through the mouth 8 drops considerably and in a very short time, and this thanks to the use of tools without fast moving parts and therefore with a low risk of breakage. From what has been described above it is easy to deduce that in the deceleration phase the quantity of fuel 2 that is introduced into the duct 32c is particularly small, so that the fuel consumption 2 is limited to the quantity sufficient to keep the engine in motion la, and with the consumption also significantly decreases the emissions of exhaust gases, which are notoriously polluting.

Naturally, the shape of the profile of the cams 34 and 58 conditions the law with which the rod 36 moves along the vertical, and the law of rotation of the rocker arm 28. Therefore, the modification of the external surface of the body 31 allows to vary the response in acceleration and deceleration of the engine la.

The same thing can be obtained much more simply by varying the lateral profile of the body 45, for example by making it a truncated cone as in Figures 4 and 5. It is clear that the two faces of the body 45 have different extensions; in particular, in Figure 4, the face of greater extension is arranged below the remaining face, to cause a gradual reduction of the fuel head 2. While the body 45 of Figure 5, which is overturned with respect to the body 45 of Figure 4, causes a very abrupt reduction of the sash with a subsequent gradual achievement of the new operating conditions. Naturally, the combination of the two shapes of the body 45 of Figures 4 and 5 can give rise to particularly advantageous laws of the variation of the sash, according to the fields of use of the motor la.

Finally, it is clear that modifications and variations can be made to the carburetor 1 described and illustrated here without thereby departing from the protective scope of the present invention.

For example, to simplify the construction and assembly of the carburetor 1, the hole 42 and the gasket 50 could be eliminated, in such a way as to leave the annular portion 48 the function of communication between the duct 9 and the tank 3, originally performed by the hole 44. Or, in the case in which it is desired to reduce the amount of energy necessary to feed the fuel 2 to the chamber 42, the gasket 50 could be eliminated leaving the hole 44.

In order to simplify the carburetor 1 as much as possible, it is possible to modify the carburetor 1 itself according to what is illustrated in figure 6, which relates to a carburetor 61, the component parts of which will be indicated, where possible, with the same reference numbers which distinguish the corresponding parts of the carburetor 1 itself.

In particular, the carburetor 61 differs from the carburetor 1 in that it lacks the connection duct 9 between the cylinder 10 and the duct 6, therefore the cylinder 10 of the carburetor 61 is closed at the bottom, and communicates with the float chamber 3 through a duct 62 obtained inside the piston 35.

Claims (1)

R I V E N D I C A Z I O N I 1.- Carburetor (1) (61) for an internal combustion engine (la) and comprising a tank (3) arranged below and able to contain fuel (2); an inlet (5) for feeding fuel (2) to said tank (3), and an outlet (6) for feeding fuel (2) by suction out of the carburetor (1) (61); said inlet (5) and outlet (6) being respectively engaged by a first and second pin (20, 24) substantially vertical, said first pin (20) being integral with a body (18) movable vertically and floating in the fuel (2) contained in the tank (3); first actuation means (14) arranged above said tray (3) for axially moving said second pin (24); characterized in that it comprises a second body (45) shaped in a determined way, and guide means (10, 35) binding the said second body (45) to move vertically inside the said tray (3); and second actuation means (14) movable in phase with said first actuation means (13) being provided to control the displacement of said second body (45) inside the tray (3), in such a way as to cause certain variations the fuel level (2) contained in the tank (3). 2.- Carburetor according to Claim 1, characterized in that said second body (45) is partially contained inside the chamber (3). 3.- Carburetor according to claim 1 or 2, characterized in that said second body (45) has a vertical axis and two faces which delimit it transversely. 4.- Carburetor according to Claim 3, characterized in that said second body (45) has a substantially cylindrical shape. 5.- Carburetor according to Claim 3, characterized in that said second body (45) has a substantially conical shape; the two said faces presenting different extensions. 6.- Carburetor according to Claim 5, characterized in that one of the two faces having greater extension is arranged below. 7.- Carburetor according to Claim 6, characterized in that one of the two faces having greater extension is arranged above. 8.- Carburetor according to Claim 8, characterized in that it comprises a connection duct (9) arranged between said tank (3) and said outlet (6) and a pumping unit (16) for pumping fuel (2 ) through the said connection duct (9) towards the said outlet (6) of the carburetor (1). 9.- Carburetor according to any one of the preceding claims, characterized in that said guide means (10, 35) comprise a tubular body (10), integral with the tank (3) and hydraulically connected to said connection duct ( 9) from the opposite band to said output (6); a hydraulic piston (35) being housed inside said tubular body (10), and axially movable under the thrust of said second actuation means (14). 10.- Carburetor according to Claim 9, characterized in that said pumping unit (16) is contained inside the tank (3). 11.- Carburetor according to Claim 9 or 10, characterized in that said pumping group (16) is a volumetric pumping group. 12.- Carburetor according to the claim characterized by the fact that the said pumping unit (16) comprises the said tubular body (10) integral with the tank (3) and connected in a watertight manner with the said connection duct (9) from the band opposite to said outlet conduit (6); said hydraulic piston (35) being housed inside said tubular body (10), and axially movable under the thrust of said second actuation means (14) and against the thrust of a spring (60a). 13.- Carburetor according to Claim 12, characterized in that the said spring (60a) is contained inside the said tubular body (10). 14.- Carburetor according to Claim 12, characterized in that said first and second actuation means (13, 14) are cam and rocker arm devices. 15.- Carburetor according to any one of the preceding claims, characterized in that it comprises a cylindrical body (31) having a longitudinal peripheral surface orthogonal to said second pin (24); said cylindrical body (31) being freely rotatable by an angle approximately 180 ° downwards around its own longitudinal axis (32); the said peripheral surface presenting first and second (33, 56) portions of substantially identical angular extensions, each of which being shaped in a determined way, to define a first and a second cam (34, 58). 16.- Carburetor according to Claim 15, characterized by the fact that said second actuation means (14) comprise a first rocker arm (26) movable with oscillatory motion around a respective axis parallel to and arranged above said cylindrical body (31); a rod (36) coaxial to said piston (35) and connected to it, and a tappet roller (54) parallel to said longitudinal axis (32) and pivoted to said rod (36) in a position below said cylindrical body ( 31), in such a way as to be tangent to said second cam (58). 17. Carburetor according to any one of the preceding claims, characterized in that said first actuation means (13) comprise a pin (26) orthogonal to said second pin (24) and a second rocker arm (28) pivoted to said pin ( 26), and movable with oscillatory motion around said pin (26); a further rod (28a) coaxial with the said second pin (24) and connected to it, and a further tappet roller (30) parallel to the said pin (26) and pivoted to the said further rod (28a) in a position above the said cylindrical body (31), so as to be tangent to said first cam (34). 18. Carburetor according to claim 12, characterized in that it comprises hydraulic communication means (44) (48) for connecting said connection duct (9) and said tank (3). 19.- Carburetor according to claim 18, characterized in that said hydraulic communication means (44) comprise a hole (44) made in said connection duct (9). 20.- Carburetor according to claim 19, characterized in that said connection duct (9) and said outlet duct (6) communicate with each other through respective end portions (46, 6a) parallel and transversely facing each other. 21. Carburetor according to claim 20, characterized in that said respective end portions (46, 6a) define an annular portion (48) between them. 22.- Carburetor according to claim 21, characterized in that the said annular portion (48) is engaged by a hydraulic seal (50) to connect the said end portions (46, 6a) in a watertight manner; said communication means (44) comprising a hole (44) made in said connection duct (9). 23. Carburetor according to claim 22, characterized in that said communication means (48) further comprise said annular portion (48). 24. Carburetor according to claim 21, characterized in that said communication means (48) are defined by said annular portion (48). 25.- Carburetor for an internal combustion engine, as described and illustrated with reference to the attached figures.