FR2852635A1 - MEMBRANE TYPE ELECTRIC FUEL PUMP FOR MOTOR VEHICLE. - Google Patents

Abstract

The invention relates to an electric fuel pump (10) of the diaphragm type for a motor vehicle, wear resistant, of simple design, having a high efficiency for a small space requirement. It is in particular intended for the engines of two-wheeled vehicles, without however being limited to this use. The pump according to the invention comprises at least one membrane (50) directly connected (s) to a piston (22) whose alternating axial movement creates depression or overpressure in a working chamber (60). The piston is driven from the rotation of the engine by a drive mechanism. The latter comprises a cam (42) with cylindrical eccentric driven in rotation from the shaft (30) of the electric motor by means of a gear (32, 34, 36, 38; 32, 74, 76, 80 ), the axes of the gear and the cam being parallel to the motor shaft (30) and perpendicular to the direction of movement of the piston (22).

Description

MEMBRANE TYPE ELECTRIC FUEL PUMP

  FOR A MOTOR VEHICLE The invention relates to an electric fuel pump of the diaphragm type for a motor vehicle. This pump is in particular intended for supplying fuel to two-wheeled vehicles, without however being limited to this use.

  In order to reduce the consumption and the polluting emissions of the engines of two-wheeled vehicles, a system of direct injection of fuel into the cylinder is used when the exhaust lights are closed. This type of injection requires a fuel pump with a flow rate adapted to the engine, which operates at a pressure of approximately 8 bars. Conventional pumps used in automobiles, such as gerotor, turbine or annular side channel pumps, have insufficient efficiency to be able to be used satisfactorily for these vehicles. In particular, their design requires operation of the electric motor in immersion in the fuel, which affects their efficiency and performance.

  Document FR-2 814 779 by the applicant describes an electric fuel pump with a membrane which makes it possible to partially solve these problems. The diaphragm of the pump is directly connected to a piston whose reciprocating axial movement makes it possible to create a depression or an overpressure in a working chamber located on the other side of the membrane. The piston is driven axially from the rotation of the engine by a drive mechanism, the axis of the piston being parallel with the shaft of the engine. This design makes it possible to house the pump in a reduced tubular casing and to isolate the hydraulic part of the drive mechanism and the motor, so that the efficiency is improved. However, this pump has several drawbacks. Due to the parallelism of the piston 30 and the drive shaft, the axes of the drive mechanism are perpendicular to the latter and undergo axial forces which accelerate the wear of the moving parts. In addition, the highly stressed membrane has a limited service life.

  The invention aims to overcome these drawbacks by proposing a more wear-resistant fuel pump, of simple design, which has a high efficiency for a small footprint.

  To this end, the subject of the invention relates to an electric fuel pump of the diaphragm type for a motor vehicle, comprising - an electric motor unit, - a guide body in which a piston is mounted, - a drive mechanism intended to transform the rotary movement of the engine into an alternating axial movement of the piston, - a hydraulic block comprising a suction passage connected to the reservoir and a discharge passage connected to the injection device 10 of the vehicle engine, said passages communicating with a working chamber by non-return valves mounted in opposition. The pump further comprises at least one membrane, the peripheral edge of which is clamped between the guide body and the hydraulic block, the central portion of said at least one membrane being fixed. on the piston, and the piston driving mechanism comprises a cam with cylindrical eccentric driven in rotation from the shaft of the electric motor stick through a gear, the axes of the gear and the cam being parallel to the motor shaft and perpendicular to the direction of movement of the piston. Thus, the axes 20 of the gear undergo only radial stresses, which makes it possible to increase their service life. Placing one or more membranes also improves the service life of the pump.

  In an advantageous embodiment, the gear comprises at least one planetary gear comprising a fixed ring and a rotating planet carrier intended to drive the cam in rotation. The ratio obtained is then particularly suitable for the engine of a two-wheeled vehicle. In another advantageous embodiment, the gear comprises at least one planetary gear comprising a fixed planet carrier and a rotating ring intended to drive the cam in rotation. The reduction ratio obtained can be used for pumps intended for the engine of a four-wheeled vehicle, for example as a booster pump for a diesel engine. However, either of these embodiments can be used independently of the application. The difference between these modes is related to the speed of rotation of the electric motor and the reduction ratio to be applied to reduce the beat frequency of the membrane to a value compatible with the application. Consequently, one or the other embodiment will be chosen according to the electric motor used and the desired beat frequency. The latter affects the pump flow rate, as well as the discharge pressure pulses, the service life of the membrane (s), the sensitivity to cavitation, the suction capacity, L use of a planetary gear also allows limited space for the drive mechanism.

  According to one embodiment, two to four membranes are superimposed and fixed between the hydraulic block and the guide body.

  The diaphragm (s) serve both for pumping and for sealing the engine block and the drive mechanism so that the fuel does not pass through the latter, thereby improving efficiency.

  In a particular embodiment, the cylindrical eccentric cam of the pump has a double contact with the piston, so that when it makes a turn it drives the piston so that it performs a back and forth in the body of guide. The movement of the piston is thus perfectly regular and controlled. Advantageously, a needle bearing is arranged between the eccentric cam and the piston so as to reduce the friction between the cam and the piston and to reduce the wear of the parts.

  In a variant, the pump comprises in the suction passage a pressure limiting valve to limit the delivery pressure, which makes it possible to limit the forces provided by the piston drive mechanism during delivery.

  The pump can also include a spring which is put in compression by the piston during the suction, and which during the discharge expands, participating with the cam in the displacement of the piston. The cam, the drive mechanism and the motor are thus less stressed during the delivery, while the greatest effort is to be made, which makes it possible to increase their service life.

  Alternatively, the electric motor block, the gear of the drive mechanism and part of the guide body are contained in a sealed tubular envelope and the other part of the guide block comprising the piston and the cam is contained in a sealed housing formed by two shells, one of the shells containing the hydraulic block. The pump obtained thus has a small footprint.

  Other advantages and embodiments of the invention are now described with reference to the accompanying drawings, which are not limiting, in which: FIG. 1 is an exploded view of an embodiment of a pump according to the invention; - Figure 2 is an axial sectional view of the pump of Figure - Figure 3 is a cross-sectional view along the line AA of Figure 2, - Figure 4 is an axial sectional view of another mode for producing a pump according to the invention, - Figure 5 is a cross-sectional view along line 15 BB of Figure 4.

  In a first embodiment, with reference to FIGS. 1 to 3, the electric fuel pump 10 comprises an electric motor block 12, which is supplied with current from the supply of the vehicle via conductors 14. From side of the 20 conductors 14, a cover 16, insulates the end of the motor. Conductors integrated into the cover 16 (not shown) come into contact with the conductors 14 of the engine block and provide the electrical connection between the electrical power source and the engine. This arrangement makes it possible to obtain a good seal with respect to the envelope of the engine block.

  The engine block 12 and the cover 16 are inserted in a tubular casing 18. Following the engine block 12, a guide body 20 is partially inserted in the tubular casing 18. The inserted part 20a of the guide body is cylindrical. It comes to fit in the casing 30 18, pressing against a motor support 19 substantially in the form of a disc fixed at the end of the motor 12. The other part 20b of the guide body projects from the casing 18. The part 20b has a parallelepiped shape having an elongated cavity 20c of rectangular section whose axis 21 is perpendicular to the axis of the cylindrical part 20a. Inside the cavity 20c, a piston 22 of complementary shape is slidably mounted in the direction of the axis 21.

  The projecting part 20b is contained in a housing formed by two shells 24 and 26 closing the two ends of the cavity 20c, along the axis 21. One of the shells 26 of the housing contains the hydraulic block of the pump. The two shells can for example be snapped onto lugs of the part 20b of the guide body, or be fixed by other means thereon.

  The shaft 30 of the motor 12 rotates a pinion 32, which in turn rotates the satellites 34 of a planetary gear train or planetary gear. There are three satellites 34. They are mounted to rotate in a planet carrier 36. The satellites 34 rotate inside a fixed crown with internal toothing 38. This crown 38 is integral with the internal face of the cylindrical part 20a of the tubular body, so that the crown 38, the satellites 34 and the satellite carriers 36 are contained in this cylindrical part 20a.

  The planet carrier 36 is integral in rotation with an axis 40 coaxial with the shaft 30 of the engine. This axis 40 rotates a cam with a cylindrical eccentric 42. The axis 40 journals in two orifices of the parallelepiped part 20b of the guide body located on either side of the cavity 20c, for example by means of bearings 20 or bearings 44 supported by elements 70.

  As clearly shown in Figure 3, the cam 42 is received in an oblong recess 46 formed at. through piston 22.

  A needle bearing 48, such as a needle sleeve, is placed in the recess between the cam and the piston, so that the surface of the cam is in contact with the needles of the sleeve 48 and the latter has always two diametrically opposite contacts on the wall of the recess 46.

  The face of the piston 22 directed towards the hydraulic block is fixed to the central part of a membrane 50, the peripheral edge of which is strongly clamped between the part 20b of the guide body and the shell 26 of the housing. In order to increase the service life of the pump, several membranes can be superimposed. Preferably, two to four membranes will be used.

  The hydraulic block has a suction passage 52 connected to the vehicle fuel tank, and a discharge passage 54 connected to the vehicle injection device. Said passages communicate via two non-return valves 56, 58 mounted in opposition, with a working chamber 60 formed on the inner face of the hydraulic block, facing the central part of the membrane 50. The valves 56, 58, are applied against their respective seats by return springs. It may however be valves 5 without return spring or "duckbill" valves. Another pressure limiting valve 62 is placed in the suction passage 52 and applied against its seat by a spring 64. This valve makes it possible to limit the amount of fuel introduced into the working chamber 60 and thus to limit the pressure during of repression. The calibration of the valve 62 is a function of its application. It can be adjusted to limit the discharge pressure to approximately 10-11 bar for a two-stroke moped or to approximately 4 bar for a 4-stroke moped The piston 22 is supported on a helical spring 66 on the side of its end opposite the membrane 50. The other end of the spring 15 66 is supported on the bottom of the shell 24 of the housing.

  The seal between the shell 26 and the part 20b of the guide body 20 is ensured by the membrane (s) 50, while the seal between the shell 24 and the part 20b is ensured by an O-ring 68. The seal between the guide body 20 and the casing 18 20 is provided by an O-ring 69 placed between the cylindrical part 20a and the internal face of the casing. An O-ring 72 seals between the cover 16 of the engine and the internal face of the tubular casing 18. A seal 73 seals the valve 62 in the suction passage 52. The pump 10 is thus perfectly sealed and the pump 25 can possibly be completely immersed in the fuel tank of the vehicle.

  In this embodiment, the suction 52 and discharge 54 passages are oriented in opposite directions from a direction parallel to the motor shaft, thereby reducing the size of the pump. This orientation can however be modified depending on the application. Such a pump is particularly well suited to use for a moped engine, without however being limited thereto.

  A filter element 78 is also provided in the suction passage 52 in order to protect the pump and the injection device placed downstream of the pump from impurities present in the fuel and liable to cause a malfunction.

  Another embodiment is described with reference to Figures 4 and 5. It is particularly suitable for use with a four-wheeled vehicle engine, but can be used for other applications. The general structure of the pump shown is identical to that which has just been described and differs essentially in the structure of the gear of the drive mechanism. Identical elements have been represented by the same references.

  The gear consists of a planetary gear train which comprises a rotating internal gear ring 74, and integral in rotation 10 with the axis 40 of rotation of the cam 42. A fixed planet carrier 76 is conjugated to the motor support placed at the end of the motor 12, in the envelope 18. The pinion 32 connected to the motor shaft drives the satellites 80 in rotation, the axes of which are supported by the satellite carriers 76. The toothed ring 74, the planet carrier 76, and the 15 satellites 80 are placed in the part 20a of the guide body.

  The pressure limiting valve 62 has been eliminated in favor of an external regulator, not shown. It can however be added depending on the use of the pump. Although the suction 52 and discharge 54 passages are oriented in opposite directions in a direction perpendicular to the motor shaft, the space requirement of the pump remains small. A configuration identical to the first embodiment can also be carried out.

  An operating cycle of the pump 10 is now described. When the motor 12 is supplied with current, its shaft 30 25 rotates the pinion 32. In the embodiment shown in FIGS. 1 to 3, this pinion 32 rotates the satellites 34 in the fixed toothed ring 38, so that the satellites in turn drive the planet carrier 36, and consequently the cam 42.

  In the embodiment shown in FIGS. 4 and 5, the pinion 32 rotates the satellites 80 in the ring gear 74. The satellite carriers 76 being fixed, the ring 74 is in turn rotated, as is the cam 42. The operation is then identical to that described in document FR-2 814 779, namely, a rotation of one revolution of the cam 32 in the oblong recess 46 causes a forward movement of the piston in a direction opposite to the membrane and a return movement of the piston towards the membrane. The piston being linked to the membrane, these movements respectively lead to a vacuum in the working chamber 60 resulting in the suction of a dose of fuel therein, and to an overpressure in the working chamber 60 causing the fuel to be discharged out of it.

  Depending on the use and the type of motor used, the reduction ratio of the planetary gear may be varied in order to obtain the desired flow rate. For this purpose, it is also possible to modify the volume of the working chamber 60 and / or the section of the piston, as well as the adjustment of the non-return valves, and / or of the pressure limiting valve.

Claims (9)

  1. An electric fuel pump (10) of the membrane type for a motor vehicle, comprising - an electric motor unit (12), - a guide body (20) in which a piston (22) is mounted, - a mechanism for drive intended to transform the rotary movement of the engine into an alternating axial movement of the piston, - a hydraulic block comprising a suction passage (52) 10 connected to the reservoir and a discharge passage (54) connected to the injection device of the engine of the vehicle, said passages (52, 54) communicating with a working chamber (60) by non-return valves (56, 58) mounted in opposition, the pump comprising at least one membrane (50) whose peripheral edge is clamped between the guide body (20) and the hydraulic block, the central portion of said at least one membrane (50) being fixed on the piston (22), and the piston drive mechanism (22) comprising a cam (42) to cylindrical eccentric rotated at starting from the shaft (30) of the electric motor via a gear (32, 34, 36, 38; 32, 74, 76, 80), the axes of the gear and of the cam being parallel to the motor shaft (30) and perpendicular to the direction of movement of the piston (22).   2. Pump according to claim 1, characterized in that the gear (32, 34, 36, 38) comprises at least one planetary gear 25 comprising a fixed ring (38) and a rotating planet carrier (36) intended to drive in rotation the cam (42).   3. Fuel pump according to claim 1, characterized in that the gear (32, 74, 76, 80) comprises at least one planetary gear comprising a fixed planet carrier (76) and a rotating crown (74) intended to rotate the cam (42).   4. Fuel pump according to one of claims 1 to 3, characterized in that two to four superimposed membranes (50) are fixed between the hydraulic block and the guide body.   5. Fuel pump according to one of claims 1 to 4, characterized in that the cam (42) with cylindrical eccentric has a double contact with the piston (22), so that when it makes a revolution it drives the piston (22) so that it goes back and forth in the guide body (20).   6. Fuel pump according to claim 5, characterized in that a needle bearing (48) is arranged between the cam (42) and the piston (22).   7. Fuel pump according to one of claims 1 to 6, characterized in that it comprises in the suction passage (52) a pressure relief valve (62) for limiting the discharge pressure.   8. Fuel pump according to one of claims 1 to 7, characterized in that it comprises a spring (66) which is put in compression by the piston (22) during the suction and which during the discharge expands participating with the cam (42) in the displacement of the piston (22).   9. Fuel pump according to one of the preceding claims, characterized in that the electric motor block (12), the gear (32, 34, 36, 38; 32, 74, 76, 80) of the drive mechanism and a part (20a) of the guide body (20) are contained in a sealed tubular casing (18) and in that the other part (20b) of the guide block (20) 20 comprising the piston (22) and the cam (42) is contained in a sealed housing formed by two shells (24, 26), one (26) of the shells containing the hydraulic block.