ITMI20121819A1 - PUMPING UNIT FOR FUEL SUPPLEMENT, PREFERABLY GASOIL, TO AN INTERNAL COMBUSTION ENGINE - Google Patents

Description

DESCRIPTION

â € œPUMPING UNIT TO FEED FUEL,

PREFERABLY DIESEL, TO A COMBUSTION ENGINE

INTERNALâ €

The present invention relates to a pumping unit for feeding fuel, preferably diesel, to an internal combustion engine.

In particular, the present invention relates to a pumping unit of the type comprising a pump body; at least one cylinder formed in the pump body; and a piston having a narrow portion slidably engaged in the cylinder and an enlarged portion, which extends outside the cylinder, and is connected with the narrow portion at a shoulder perpendicular to a longitudinal axis of the cylinder itself.

The pumping unit also comprises first actuating means for moving the piston with a stroke of suction of the fuel into the cylinder; and second actuating means for moving the piston with a compression stroke of the fuel contained in the cylinder itself.

The second actuator means comprise a cam obtained on an external surface of a transmission shaft extending through the pump body transversely to the longitudinal axis of the cylinder; and a tappet, which is mounted between the cam and the piston, and is provided with a cam follower arranged in contact with the cam itself.

The cam follower protrudes outside a sleeve, which extends around the cylinder, is coupled in a sliding manner to the pump body, and has an internal annular flange, which protrudes radially from an internal surface of the sleeve to define a first portion adapted to receive and hold the tappet and a second portion by interference.

The first actuating means comprise an annular support element, which is inserted inside the second portion of the sleeve, extends around the restricted portion of the piston, and faces axially the flange of the sleeve and the shoulder of the piston; and a spring, which is mounted between the cylinder and the sleeve coaxially to the longitudinal axis of the cylinder, and is interposed between the pump body and the annular support element to axially block the annular support element against the flange and tappet against the cam.

Regarding the above, it should be noted that the enlarged portion of the piston is arranged between the tappet and the annular support element and has a height, measured parallel to the longitudinal axis of the cylinder, which is less than the height of the flange and, therefore, of the distance between the tappet and the annular support element, also measured parallel to the longitudinal axis of the cylinder.

Consequently, known pumping units of the type described above have some drawbacks mainly deriving from the fact that the piston impacts by inertia against the annular support element at the end of the compression stroke and against the tappet at the end of the intake stroke.

The impacts of the piston against the annular support element cause the stress and damage of the annular support element, while the impacts of the piston against the tappet cause unwanted acoustic phenomena.

The object of the present invention is to provide a pumping unit for feeding fuel, preferably diesel oil, to an internal combustion engine which is free from the drawbacks described above and which is simple and economical to implement.

According to the present invention, a pumping unit is provided to feed fuel, preferably diesel oil, to an internal combustion engine as claimed in the attached claims.

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

Figure 1 is a first schematic sectional view, with parts removed for clarity, of a preferred embodiment of the pumping unit of the present invention;

Figure 2 is a second schematic sectional view, with parts removed for clarity, of the pumping unit of Figure 1; And

figure 3 is a schematic sectional view of a detail of figures 1 and 2.

With reference to Figures 1 and 2, 1 indicates, as a whole, a pumping unit for supplying fuel, preferably diesel oil, to an internal combustion engine (not shown).

The pumping unit 1 comprises a pump body 2 provided with a central hole 3 having a determined longitudinal axis 4; a pumping unit 5 adapted to supply fuel to the aforementioned internal combustion engine (not illustrated); and a known and not illustrated pre-feeding pump adapted to feed fuel to the pumping unit 5 itself.

In the following discussion, the term â € œpump bodyâ € will be used to indicate the entire support structure of the pumping unit 1 regardless of the number of components that define it.

The pumping unit 5 comprises at least one cylinder 6, which is obtained in the pump body 2, has a longitudinal axis 7 substantially perpendicular to the axis 4, faces the hole 3, and cooperates with a fuel intake valve 8 inside the cylinder 6 and with a fuel delivery valve 9 to the internal combustion engine (not shown).

The cylinder 6 is engaged in a sliding manner by a piston 10, which is mounted coaxially to the axis 7, and comprises an enlarged portion 11 extending outside the cylinder 6 and a narrow portion 12, which extends to the Inside the cylinder 6, and is connected to the portion 11 in correspondence with an annular shoulder 13 substantially perpendicular and coaxial to the axis 7 itself.

The piston 10 is moved by an actuation device 14 along the cylinder 6 with a reciprocating rectilinear motion comprising an intake stroke for the fuel in the cylinder 6 and a compression stroke for the fuel contained inside the cylinder 6 itself.

The device 14 comprises a tubular sleeve 15, which is slidingly engaged inside a cylinder 16 formed in the pump body 2 coaxially to the axis 7, extends around the cylinder 6, and has an annular flange 17 internal, which protrudes radially from an internal surface of the sleeve 15, and divides the sleeve 15 itself into two cylindrical portions 18, 19, of which the portion 18 faces the hole 3.

The device 14 also has a tappet 20 comprising a substantially cylindrical coupling block 21, which is inserted inside the portion 18, is arranged in contact with the flange 17, and is blocked by interference to the € ™ inside of the portion 18 itself, and a tappet roller 22, which protrudes from the block 21 towards the hole 3, and is rotatably coupled to the block 21 to rotate, with respect to the block 21 itself, around its own axis 23 longitudinal substantially perpendicular to axis 7.

The flange 17 supports an annular element 24, which extends around the restricted portion 12 of the piston 10, is inserted inside the portion 19 of the sleeve 15 coaxially to the axis 7, and has an external perimeter edge facing axially to the flange 17 and an internal perimeter edge facing axially to the shoulder 13.

The device 14 also comprises a first compression spring 25, which is mounted between the cylinder 6 and the sleeve 15 coaxially to the axis 7, and is interposed between the pump body 2 and the element 24 to moving, and normally maintaining, the element 24 in contact with the flange 17 and the roller 22 in contact with a cam 26 obtained on an external surface of an intermediate portion of a transmission shaft 27 mounted through the hole 3 to rotate, with respect to pump body 2, around axis 4.

With regard to the above, it should be noted that the enlarged portion 11 of the piston 10 has a height, measured parallel to the axis 7, that is less than the height of the flange 17 and, therefore, the distance between the block 21 and the Element 24 also measured parallel to axis 7 (figure 3).

Finally, the device 14 comprises a second compression spring 28, which is mounted inside the cylinder 6 coaxially to the axis 7, and is interposed between the pump body 2 and the piston 10 to maintain the piston 10 in contact with block 21.

According to some variants not illustrated:

the spring 25 is eliminated and the piston 10 is moved with its suction stroke solely under the thrust of the spring 28;

the spring 28 is mounted outside the cylinder 6, between the pump body 2 and the piston 10, and in contact with the enlarged portion 11 of the piston 10 itself; And

element 24 is eliminated and spring 25 is mounted directly in contact with flange 17 or block 21.

Since the piston 10 is always kept in contact with the tappet 20, the pumping unit 1 has some advantages.

In the first place, the spring 28 prevents the piston 10 from striking against the element 24 at the end of the compression phase and against the tappet 20 at the end of the intake phase, thus avoiding damage to the element 24 in the first case and the onset of unwanted acoustic phenomena in the second case.

Secondly, since the compression stroke of the piston 10 coincides perfectly with the stroke of the tappet 20 under the thrust of the cam 26, the pumping unit 1 has a relatively high efficiency.

Finally, since the enlarged portion 11 is not disposed in contact with the element 24 and that the piston 10 is moved with its suction stroke only under the thrust of the spring 28, the element 24 can be eliminated with consequent reduction in the number of components and, therefore, in the costs of the pumping unit 1.

Claims (1)

CLAIMS 1.- Pumping unit to feed fuel, preferably diesel, to an internal combustion engine, the pumping unit comprising a pump body (2); at least one cylinder (6) having a longitudinal axis (7); a piston (10) slidably engaged in the cylinder (6); first actuator means (24, 25, 28) for moving the piston (10) with a stroke of suction of the fuel in the cylinder (6); and second actuator means (20, 26) for moving the piston (10) with a compression stroke of the fuel contained in the cylinder (6) itself, the second actuator means (20, 26) comprising a cam (26) mounted to rotate around to a rotation axis (4) transversal to said longitudinal axis (7), and a tappet (20) engaged in the cam (26) to move the piston (10) with its compression stroke; and being characterized in that the first actuator means (24, 25, 28) comprise a first spring (28) interposed between the pump body (2) and the piston (10) to keep the piston (10) in contact with the tappet ( 20). 2.- Pumping unit according to claim 1, wherein the first spring (28) is arranged in contact with the piston (10). 3.- Pumping unit according to claim 1 or 2, wherein the piston (10) comprises a narrow portion (12) slidingly engaged in the cylinder (6), an enlarged portion (11) extending outside the cylinder (6), and a shoulder (13) to connect the narrow portion (12) and the enlarged portion (11) together. 4.- Pumping unit according to claim 3, wherein the first spring (28) is mounted inside the cylinder (6) in contact with the restricted portion (12). 5.- Pumping unit according to Claim 3, wherein the first spring (28) is mounted outside the cylinder (6) in contact with the enlarged portion (11). 6.- Pumping unit according to any one of the preceding claims, in which the first actuator means (24, 25, 28) further comprise a second spring (25) interposed between the pump body (2) and the tappet (20) to keep the tappet (20) in contact with the cam (26). 7.- Pumping unit according to Claim 6, wherein the second spring (25) is mounted outside the cylinder (6) and in contact with the tappet (20). 8.- Pumping unit according to claim 6 and further comprising a sleeve (15), which extends around the piston (10) coaxially to the said longitudinal axis (7), is coupled in a sliding manner to the pump body ( 2), is axially fixedly engaged by the tappet (20), and has a flange (17) projecting radially towards the inside of the sleeve (15) itself. 9.- Pumping unit according to Claim 8, wherein the second spring (25) is mounted outside the cylinder (6) and in contact with the flange (17). 10.- Pumping unit according to Claim 8 and further comprising an annular element (24) extending around the restricted portion (12); the second spring (25) being interposed between the pump body (2) and the annular element (24) to keep the annular element (24) in contact with the flange (17). 11.- Pumping unit according to claim 10, wherein the second spring (25) is mounted outside the cylinder (6) and in contact with the annular element (24). 12.- Pumping unit according to claim 1 or 6, wherein each said spring (25, 28) is a compression spring wound helically around and along said longitudinal axis (7).