WO2012080334A1

WO2012080334A1 - Pump unit for feeding fuel, preferably diesel fuel, from a storage tank to an internal combustion engine

Info

Publication number: WO2012080334A1
Application number: PCT/EP2011/072757
Authority: WO
Inventors: Salvatore Palmisano; Daniele De Gennaro; Nello Medoro
Original assignee: Robert Bosch Gmbh
Priority date: 2010-12-16
Filing date: 2011-12-14
Publication date: 2012-06-21
Also published as: IT1403264B1; CN103261683A; CN103261683B; RU2013132614A; JP2014503737A; ITMI20102310A1; KR20130141594A; EP2652328B1; EP2652328A1

Abstract

A pump unit for feeding fuel, preferably diesel fuel, to an internal combustion engine (3) is provided with a hydraulic circuit (14) having a first line (15) for connecting together a fuel storage tank (2) and a pre-feed pump (7), a second line (16) for connecting together the pre-feed pump (7) and a high-pressure pump (6), a third line (18) for connecting together the high-pressure pump (6) and the internal combustion engine (3), a fourth line (24) for connecting together the second line (16) and the storage tank (2) and a fifth line (35) for connecting together the second and fourth lines (16, 24); a Venturi pipe (31) being screwed into the fourth line (24) and communicating hydraulically with the fifth line (35).

Description

Title

PUMP UNIT FOR FEEDING FU EL, PREFERABLY DI ESEL FU EL, FROM A STORAGE TAN K TO AN INTERNAL COMBUSTION ENGIN E The present invention relates to a pump unit for feeding fuel, preferably diesel fuel, from a storage tank to an internal combustion engine.

In particular, the present invention relates to a pump unit of the type comprising a pump body, for example a gear pump; a high-pressure pump, for example a piston pump; and a hydraulic circuit comprising, in turn, a first line for connecting together a fuel storage tank and the gear pump, a second line for connecting together the gear pump and the piston pump, and a third line for connecting together the piston pump and an internal combustion engine. Generally, the hydraulic circuit also comprises a metering solenoid valve arranged along the second line for selectively controlling the instantaneous flowrate of the fuel fed to the piston pump depending on the values of a plurality of operating parameters of the internal combustion engine; and a fourth line, which connects together the second line and the storage tank, is connected to the second line upstream of the metering solenoid valve in a direction of flow of the fuel along the said second line and allows, discharging into the storage tank, of at least part of the fuel flow exceeding that fed through the metering solenoid valve. The fourth line is provided, normally, with an overflow valve and a Venturi pipe, which defines part of the fourth line, is arranged downstream of the overflow valve in a direction of flow of the fuel along the fourth line and is connected to a fifth line of the hydraulic circuit connected, in turn, to the second line downstream of the metering solenoid valve in the direction of flow of the fuel along the said second line.

The fifth line allows discharging, into the Venturi pipe and therefore into the storage tank, of the fuel which seeps through the closed metering solenoid valve and part of the fuel fed through the open metering solenoid valve.

The Venturi pipe has a given longitudinal axis, comprises an axial central hole defining a first inlet for receiving the fuel from the fourth line and an outlet for the fuel in the said fourth line and is provided with a radial side hole, which is connected to the central hole and defines a second inlet for receiving the fuel from the fifth line.

In order to prevent the fuel seeping into the second inlet, passing between the Venturi pipe and the fourth line, the Venturi pipe has two joining portions of different diameter which are joined in a fluid-tight manner by means of interference with corresponding joining portions formed in the said fourth line.

From the above description it will be clear that mounting of the Venturi pipe inside the fourth line is relatively complex and difficult and requires high dimensional tolerances in order to ensure a correct fluid-tight connection between the said joining portions.

The object of the present invention is to provide a pump unit for feeding fuel, preferably diesel fuel, from a storage tank to an internal combustion engine, which does not have the drawbacks described above and which is simple and inexpensive to produce.

According to the present invention a pump unit for feeding fuel, preferably diesel fuel, from a storage tank to an internal combustion engine is provided as claimed in the accompanying claims.

The present invention will now be described with reference to the accompanying drawings which illustrate a non-limiting example of embodiment thereof in which: Figure 1 is a hydraulic diagram of a preferred embodiment of the pump unit according to the present invention; and

Figure 2 is a longitudinally sectioned view of a detail of the pump unit according to Figure 1.

With reference to Figure 1, 1 denotes, in its entirety, a pump unit for feeding fuel, in particular diesel fuel, from a storage tank 2 to an internal combustion engine 3, in the case in question a Diesel combustion engine comprising a fuel distribution manifold 4, commonly indicated by the term "common rail", and a plurality of injectors 5 which are connected to the manifold 4 and designed to spray the fuel inside associated combustion chambers (not shown) of the said engine 3.

The pump unit 1 comprises a high-pressure pump 6, in the case in question a piston pump, designed to feed the fuel to the engine 3, and a low-pressure or pre-feed pump 7, in the case in question a gear pump, designed to feed the fuel from the tank 2 to the pump 6.

The pump 6 comprises a pump body 8 with a given longitudinal axis 9, and a plurality of cylinders 10 (in the case in question two cylinders 10), which are formed in the pump body 8, are uniformly distributed around the axis 9 and have respective longitudinal axes substantially perpendicular to the said axis 9 and which are each engaged slidably by a respective piston 12.

The pistons 12 are displaced along the associated cylinders 10 by an actuating device 13 of the known type housed inside the pump body 8, with a reciprocating rectilinear movement, comprising an outward stroke for intake of the fuel into the associated cylinders 10 and a return stroke for compressing the fuel contained inside said associated cylinders 10.

The pump unit 1 also comprises a hydraulic circuit 14 for feeding the fuel, comprising, in turn, a first line 15 for connecting together the tank 2 and the pump 7, a second line 16, which connects together the pumps 6 and 7, extends through the pump body 8 in order to lubricate the actuating device 13, and is connected to each cylinder 10 via an associated intake valve 17, and a third line 18, which extends between the pump 6 and the manifold 4, and is connected to each cylinder 10 by means of an associated delivery valve 19.

The line 16 is provided with a metering solenoid valve 20 which is mounted upstream of the valves 17 in a direction 21 of flow of the fuel along the sections 15, 16 and 18, is movable between a closed position and an open position, and is designed to control selectively the instantaneous flowrate of the fuel fed to the pump 6 depending on the values of a plurality of operating parameters of the engine 3.

The circuit 14 also comprises a fourth line 22 which extends between the manifold 4 and the tank 2 and is provided with a metering solenoid valve 23, which cooperates with the solenoid valve 20 so as to control selectively the flowrate of the fuel fed to the injectors 5 and allows discharging into the tank 2 of the fuel flow exceeding that required for the injectors 5.

The circuit 14 also has a fifth line 24, which connects the line 16 upstream of the solenoid valve 20 in the direction 21 to the line 22 and allows discharging, into the line 22 and therefore into the tank 2, of at least part of the fuel flow exceeding that fed through the said solenoid valve 20.

The line 24 has a given longitudinal axis 25, comprises a widened section 26 and a narrow section 27 connected together at an end-of-travel shoulder 28 at right angles to the axis 25 and is provided with an overflow valve 29.

The valve 29 has an inlet 29a for receiving the fuel from the line 24, a first outlet 29b for the fuel in the line 24 and a second outlet 29c for the fuel in a line 30 of the circuit 14 extending between the valve 29 and the line 15.

The valve 29 is also configured to open only the outlet 29b when the flowrate of the fuel fed along the line 24 is less than a given threshold value and to open the two outlets 29b and 29c when the flowrate of the fuel fed along the line 24 is at least equal to the threshold value itself.

In accordance with that shown in Figures 1 and 2, the circuit 14 also comprises a Venturi pipe 31 which is mounted in the section 26 downstream of the valve 29 in a direction 32 of flow of the fuel along the line 24 and is provided with a central hole 33 which extends through the pipe 31 coaxially with respect to the axis 25 and comprises a frustoconical inlet portion 33a converging in the direction 32, a frustoconical outlet portion 33b diverging in the direction 32 and a cylindrical intermediate portion 33c extending between the portions 33a and 33b.

The pipe 31 also has a radial calibrated hole 34 which is formed in a middle point of the pipe 31 transversely with respect to the axis 25, communicates with the portion 33c of the hole 33 and also communicates with a further line 35 of the circuit 14 in turn connected to the line 16 downstream of the solenoid valve 20 in the direction 21.

Since the pressure of the fuel in the portion 33c is relatively low and less than the pressure of the fuel in the line 35, the pipe 31 is able to take in the fuel flow which seeps through the solenoid valve 20 when said solenoid valve 20 is closed. Since the line 35 is always connected to the line 16 and to the hole 34 it should be pointed out that the pipe 31 also takes in part of the fuel flow fed through the solenoid valve 20 when the solenoid valve 20 is open and the hole 34 is configured to keep below a given threshold value the quantity of fuel taken in by the pipe 31 when the solenoid valve 20 is open.

The section 26 and the pipe 31 have respective joining portions 39 which are formed on the inner surface of the section 26 and on the outer surface of the pipe 31, respectively, and are joined together in a fluid-tight manner by means of respective gas threads 37.

The pipe 31 is screwed into the section 26 so as to be arranged in contact with the shoulder 28 and be joined in a fluid-tight manner to the shoulder 28 itself and has a polygonal hollow head 38 which is formed inside the hole 33 upstream of the portion 33a in the direction 32 and allows an Allen key (known and not shown) to screw/unscrew the pipe 31 into/from said line 24.

In connection with the above description it should be pointed out that:

the fluid-tight connections between the gas threads 37 and between the shoulder 28 and the pipe 31 prevent the fuel from seeping between the sections 26 and 27 of the line 24 and the pipe 31, allowing the pipe 31 to take in the fuel through the hole 34; and the gas threads 37 allow the pipe 31 to be mounted in a relatively simple and low-cost manner in the line 24.

Claims

1. Pump unit for feeding fuel, preferably diesel fuel, from a storage tank (2) to an internal combustion engine (3), the pump unit comprising a pre-feed pump (7); a high-pressure pump (6); a hydraulic circuit (14) comprising, in turn, a first line (15) for connecting together the storage tank (2) and the pre-feed pump (7), a second line (16) for connecting together the pre-feed pump (7) and the high- pressure pump (6), a third line (18) for connecting together the high-pressure pump (6) and the internal combustion engine (3), a fourth line (24) for connecting together the second line (16) and the storage tank (2) and a fifth line (35) for connecting together the second and fourth lines (16, 24); and a Venturi pipe (31) which defines part of the fourth line (24) and communicates hydraulically with the fifth line (35); and being characterized in that the Venturi pipe (31) is screwed into the fourth line (24).

2. Pump unit according to Claim 1, wherein the fourth line (24) and the Venturi pipe (31) comprise respective joining portions (36) which are formed on the inner surface of the fourth line (24) and on the outer surface of the Venturi pipe (31), respectively, and are joined together in a fluid-tight manner by means of respective gas threads (37).

3. Pump unit according to Claim 2, wherein the Venturi pipe (31) comprises a first inlet (33a) for receiving the fuel from the fourth line (24), a second inlet (34) for receiving the fuel from the fifth line (35) and an outlet (33b) for the fuel in said fourth line (24).

4. Pump unit according to Claim 3, wherein the second inlet (34) is formed downstream of the joining portion (36) of the Venturi pipe (31) in a direction of flow (32) of the fuel along the fourth line (24).

5. Pump unit according to Claim 3 or 4, wherein the Venturi pipe (31) is provided with a central hole (33) which extends through the Venturi pipe (31), coaxially with respect to a longitudinal axis (25) of the fourth line (24), so as to define the first inlet (33a) and the outlet (33b); the second inlet (34) extending radially through the Venturi pipe (31) so as to communicate hydraulically with the central hole (33).

6. Pump unit according to any one of the preceding claims, wherein the fourth line (24) comprises a widened portion (26) and a narrow portion (27) which are arranged in succession with each other and are connected together at an end-of-travel shoulder (28) which is substantially at right angles to a longitudinal axis (25) of said fourth line (24); the Venturi pipe (31) being screwed into said widened portion (26) so as to be arranged in contact with and be joined in a fluid- tight manner to said end-of-travel shoulder (28).

7. Pump unit according to any one of the preceding claims, wherein the Venturi pipe (31) has a polygonal head (38) suitable for engagement by an operating spanner.

8. Pump unit according to any one of the preceding claims and also comprising an overflow valve (29) arranged along the fourth line (24) upstream of the Venturi pipe (31) in a direction of flow (32) of the fuel along said fourth line (24).

9. Pump unit according to any one of the preceding claims, wherein the hydraulic circuit (14) also comprises a metering solenoid valve (20) mounted along the second line (16); the fourth line (24) and the fifth line (35) being connected to the second line (16) upstream and downstream, respectively, of the metering solenoid valve (20) in a direction of flow (21) of the fuel along the said second line (16).