IT201600123972A1 - GEAR ELECTRIC PUMP - Google Patents

Description

"ELECTRIC GEAR PUMP"

The present invention relates to an electric gear pump. In particular, the present invention relates to an electric gear pump of the gerotor type.

Furthermore, the present invention relates to a pump assembly comprising in series:

- a low pressure pump (the aforementioned electric gear pump of the gerotor type), for drawing fuel, preferably diesel, and for a first compression of the same; And

- a high pressure pump, preferably with pumping pistons, for further compression of the fuel and for supplying high pressure fuel to an internal combustion engine.

It is now known to use fuel supply systems, in particular diesel oil, to an internal combustion engine comprising a high pressure pump, to feed the internal combustion engine, and a low pressure pump to feed fuel to the high pressure pump. . The high pressure pump comprises at least one pumped piston moved by a shaft and housed in a cylinder fed by low pressure fuel. Currently there are at least two different types of low pressure pumps for these systems.

The first type comprises a gear pump driven by the same drive shaft as the pistons of the high pressure pump. In particular, this gear pump can be a “gerotor” pump. As known, the gerotor pump includes an external toothed rotor set in rotation by the shaft and housed inside an internal toothed rotor. During rotation, the teeth of the external toothed rotor engage with the teeth of the internal toothed rotor, which has one more tooth than the external toothed rotor. The two rotors, rotating both in an absolute sense and relatively or relative to each other, pump fuel from an inlet, connected to the tank, to an outlet, connected to the high pressure pump.

The second type of gear pumps includes gear pumps not driven by the drive shaft of the pumping pistons but pumps operated electrically or electromagnetically. According to this type of pump, currently in gerotor pumps at least one of the rotor with internal toothing and the one with external toothing supports magnetic modules, such as packs of iron laminations, which interact electromagnetically with a stator arranged outside the rotor at internal toothing and comprising electric windings. By feeding current to these windings, electromagnetic conditions are created such that the gerotor begins to rotate, realizing the desired pumping between the tank and the high pressure pump.

In this type of gerotor electric gear pumps, the stator equipped with electric windings, which can also be defined as an "electric motor" since it induces the motion of the gerotor, is placed at the same level as the gerotor itself to increase the electromagnetic interaction. This concentric arrangement of gerotor and stator now requires the presence of a bearing arranged between the outer wall of the rotor with internal teeth of the gerotor and the stator. Since metallic materials present between the stator and gerotor could lead to loss of effectiveness of the electromagnetic interaction, currently the aforementioned bearing is made of plastic material, for example in peek (polyether ether ketone). The assembly steps of this peek bearing require that it is first fitted by interference, or in any case by forced surface coupling, inside the stator and then subsequently machined to ensure correct support for the rotation of the gerotor. In this coupling, therefore, the external surface of the rotor with internal teeth is a sliding surface in motion with respect to the bearing fixed to the stator. Due to this sliding surface coupling, the magnets associated with the gerotor cannot be coupled to the external surface of the rotor with internal teeth but must be housed in seats obtained inside this rotor, for example seats made during production by sintering the component. .

The above described type of electric gerotor gear pumps, that is with bearing in plastic material fitted on the stator and magnets embedded in the rotor, has some drawbacks.

A first drawback consists in the fact that the operations of assembling the bearing on the stator and the subsequent surface machining step with the assembled bearing are very complex and expensive.

A second drawback consists in the fact that the steps for making the seats of the magnets in the rotor close to the sliding surface and for fixing the magnets in place are very complex and expensive.

Starting from this known technique, an aim of the present invention is to realize an alternative gear pump, preferably an alternative gerotor electric gear pump.

In particular, it is an object of the present invention that of realizing a gerotor electric gear pump which allows to overcome the drawbacks of the known art previously highlighted in a simple and economical way, both from the functional point of view and from the constructive point of view.

In accordance with these purposes, the present invention relates to an electric gear pump comprising: - a gerotor comprising an external toothed rotor rotating around a rotation axis A and an internal toothed rotor disposed outside the toothed rotor external;

- a stator equipped with electric windings;

- a shaft arranged along the rotation axis A and coupled to the external toothed rotor;

- at least one magnet or a ferromagnetic structure configured in such a way as to induce the shaft to rotate when the electrical windings of the stator are powered by current.

Advantageously, in this way the complex or costly manufacturing of the seats for the magnet or the ferromagnetic structure in the rotors of the gerotor and the subsequent operations of fixing the magnets in these seats is no longer required. In fact, the rotation of the gerotor according to the invention is performed by placing the rotation not the rotors but the shaft, which in cascade drives the gerotor in rotation, in particular the rotor with external teeth.

According to a preferred embodiment of the invention, the electric gear pump also comprises a cup-shaped structure associated with the shaft which creates a housing seat for the gerotor. According to this example, advantageously, the ferromagnetic structure or the magnet can be coupled externally to the cup structure without interfering in the production of the gerotor.

Preferably, the cup-shaped structure comprises a base and a side wall. According to this example, the ferromagnetic structure or the magnet is coupled to the outer surface of the side wall of the cup structure. Advantageously, in this way the ferromagnetic structure or the magnet is directly facing the stator windings, making the electromagnetic interaction more efficient.

Preferably, the cup-shaped structure is made in one piece with the shaft. Advantageously, in this way, the transfer of motion from the side wall of the cup structure, stressed by the rotating magnet, to the shaft is made more efficient.

Preferably, the electric gear pump further comprises a first bearing interposed between the gerotor, that is the external surface of the internal tooth rotor, and the internal surface of the side wall of the cup structure. In particular, this first bearing can be made of metal material as it is not interposed between the magnet associated with the cup structure and the winding of the stator. By virtue of this arrangement, the aforementioned first bearing can be made in an extremely simpler and more economical way than the plastic bearings used in known electric gear pumps today.

Preferably, the electric gear pump also comprises a seal interposed between the shaft and a portion of the first bearing located below the gerotor. Advantageously, in this way the leakage of the fuel along the shaft below the gerotor is avoided.

In particular, the electric gear pump comprises a support base and a closing cover which includes feed and delivery channels of fuel with respect to the gerotor. According to this example, the first bearing is coupled to the cover preferably by means of screws. Advantageously, in this way the positioning of the first bearing is performed with a very simple and rapid procedure.

Preferably, the electric gear pump comprises a second bearing housed in the support base for the shaft. Advantageously, in this way the rotation of the shaft is guided stably along the axis A of the gerotor.

Finally, the present invention also refers to a pump unit for supplying fuel from a tank to an internal combustion engine. This pump group comprises: - a low pressure electric gear pump;

- a high pressure pump;

- a low pressure suction duct to feed combustion from the tank to the electric gear pump;

- a low pressure delivery duct to feed combustion from the electric gear pump to the high pressure pump;

- at least one high pressure delivery duct to feed combustion from the high pressure pump to the internal combustion engine;

wherein the electric gear pump is made according to any one of the embodiments described above.

Further characteristics and advantages of the present invention will appear clear from the following description of a non-limiting example of its implementation, with reference to the figures of the annexed drawings, in which:

- figure 1 is a schematic view of an example of a pump unit for feeding fuel, preferably diesel, from a tank to an internal combustion engine, in which a low pressure gear pump and a pump are present in series. high pressure pumping pistons;

figure 2 shows a schematic view of a low pressure gerotor gear pump;

Figure 3 shows a sectional view of an embodiment of an electric low pressure pump with gerotor gears according to the present invention.

Figure 1 is a schematic view of an example of a pump unit for feeding fuel, preferably diesel, from a tank to an internal combustion engine, in which a low pressure pump and a high pressure pump are present in series. pressure. In particular, Figure 1 shows a pump assembly 1 comprising:

- a low pressure electric gear pump 4; - a high pressure pump 5;

- a low pressure suction duct 6 to feed the combustion from the tank 2 to the electric gear pump 4;

- a low pressure delivery duct 7 to feed combustion from the electric gear pump 4 to the high pressure pump 5;

- high pressure delivery ducts 8 to feed combustion from the high pressure pump 5 to the internal combustion engine 3.

In this example the internal combustion engine 3 is shown only in schematic form and comprising a common manifold 17 fed by the high pressure delivery ducts 8 and a plurality of injectors 18 configured to nebulize and inject the fuel at high pressure into the engine cylinders. internal combustion 3 (not shown). In figure 1 the high pressure pump 5 is shown only in schematic form and comprising two pumping pistons 11 fed by low pressure fuel in correspondence with supply valves 12 and connected to delivery valves 13 to feed high pressure fuel to the engine 3. Figure 1 also shows a filter 10 arranged downstream of the low pressure pump 4, a fuel metering device 14 downstream of the filter 10, an overflow valve 15 between the filter 10 and the fuel metering device 14, a pressure limiting valve 26 connected to the manifold 17 and a delivery valve 27 to the tank 2. The arrows shown in Figure 1 indicate the path of the fuel in the pump unit 1.

Figure 2 shows an enlarged detail of the low pressure pump 4, in particular a gerotor gear pump 9. As can be seen in Figure 2, this gerotor 9 comprises an internal toothed rotor 20 inside which a toothed rotor is housed external 21. In a known way the gerotor 9 comprises an inlet 22, connected to the low pressure supply duct 6, and an outlet 23 connected to the high pressure delivery duct 7. Figure 2 schematically shows the internal chambers of the gerotor 9 for supply, at the inlet 22, and delivery, at the outlet 23. The operation of an electric gerotor gear pump is known and provides for the rotation of the gerotor with respect to a stator due to the effect of the electromagnetic interaction between these elements. In figure 2 for clarity, the stator with the electrical windings arranged externally to the gerotor 9 and the magnets associated with the gerotor 9 itself have not been shown.

Figure 3 shows a preferred embodiment of an electric gear pump 4 according to the invention. According to this example, the electric gear pump 4 comprises:

- a gerotor 9 comprising an external toothed rotor 21 rotating around a rotation axis A and an internal toothed rotor 22 arranged outside the external toothed rotor 21;

- a stator 29 provided with electric windings 30 arranged externally and at the same level as the gerotor 9.

In particular, the external toothed rotor 21 is keyed, or coupled integrally, to a rotation shaft 32 which rotating around its own axis rotates the external toothed rotor 21 along the axis A thus activating the gerotor 9.

During its rotation, the gerotor 9 compresses the fuel fed by the supply channel 6 in a known way and discharges the compressed fuel along a delivery channel 7. In the example of Figure 3, these supply channels 6 and delivery 7 they are obtained in a cover 27 which when constrained to a relative base 28 forms the containment for the gerotor 9 and the stator 29.

According to the embodiment of Figure 3, the shaft 32 is made in one piece with a cup-like structure 37 open towards the lid 27 and comprising a base 38 and a side wall 39. This cup-like structure 37 provides a housing for the gerotor 9. In particular, the external surface of the side wall 39 of the cup-shaped structure 37 supports a magnetic structure 31 directly facing the windings 30 of the stator 29. The external surface of the side wall 39 instead faces a first bearing 34, or radial bearing, the which supports the rotation of the internal toothed rotor 22. As can be seen, this first bearing 34 can be fixed to the cover 27 by means of simple screws 36 and can provide seats for housing a seal 35 at the shaft 32. The bearing is preferably made of metallic material.

Finally, it is clear that modifications and variations may be made to the invention described here without departing from the scope of the attached claims.

Claims (10)

CLAIMS 1. An electric gear pump (4) comprising: - a gerotor (9) comprising an external toothed rotor (21) rotatable around an axis of rotation (A) and an internal toothed rotor (22) arranged externally of the external toothed rotor (21); - a stator (29) provided with electric windings (30); - a shaft (32) arranged along the rotation axis (A) and coupled to the external toothed rotor (21); - at least one magnet or a ferromagnetic structure (31) configured in such a way as to induce the shaft (32) in rotation when the electrical windings (30) of the stator (29) are powered by current. 2. Pump as claimed in claim 1, wherein the pump (4) comprises a cup structure (37) associated with the shaft (32) housing the gerotor (9); the ferromagnetic structure or the magnet (31) being coupled externally to the cup structure (37). Pump as claimed in claim 2, wherein the cup structure (37) comprises a base (38) and a side wall (39); the ferromagnetic structure or the magnet (31) being coupled to the outer surface of the side wall (39) of the cup structure (37). 4. Pump as claimed in claim 2 or 3, in which the cup structure (37) is made integrally with the shaft (32). Pump as claimed in claim 3 or 4, wherein the pump comprises a first bearing (34) interposed between the gerotor (9) and the inner surface of the side wall (39) of the cup structure (37). Pump as claimed in claim 5, wherein the first bearing (34) is made of metallic material. 7. Pump as claimed in claim 5 or 6, wherein the pump (4) comprises a seal (35) between the shaft (32) and the first bearing (34). Pump as claimed in claim 5 or 6 or 7, wherein the pump (4) comprises a support base (28) for the shaft (32) and a closing cover (27) comprising channels (6, 7) supply and delivery with respect to the gerotor (9), the first bearing (34) being coupled to the cover (27). 9. Pump as claimed in claim 8, wherein the pump (4) comprises a second bearing (33) housed in the base (28) supporting the shaft (32). 10. A pump unit for feeding fuel from a tank (2) to an internal combustion engine (3); the pump unit (1) comprising: - a low pressure electric gear pump (4); - a high pressure pump (5); - a low pressure intake duct (6) to feed combustion from the tank (2) to the electric gear pump (4); - a low pressure delivery duct (7) to feed combustion from the electric gear pump (4) to the high pressure pump (5); - at least one high pressure delivery duct (8) to feed combustion from the high pressure pump (5) to the internal combustion engine (3); wherein the electric gear pump (4) is made according to any one of the preceding claims.