The present invention concerns a fuel injector and has a particular but not exclusive application to fuel injectors intended to deliver pressurized fuel to a combustion chamber of an internal combustion engine.
Fuel injection systems for modern internal combustion engines, in particular compression ignition engines, comprise a plurality of fuel injectors adapted to emit an atomized jet of fuel at high pressure into a combustion chamber of the engine.
A fuel injector known to be used in a system of the above kind. It comprises an injection needle. The needle slides inside the bore formed in a nozzle body and being able to cooperate with a seat to control the distribution of fuel through one or more outlet openings.
When at the start of injection an actuator is electrically energized to perform the opening action, which leads to the movement of an armature and a valve element, also known to professionals as a valve stem. The control stem is situated in the low-pressure chamber, the control stem then moves upward against the action of a coil spring of the actuator. At this stage the length of the spring is reduced and an oscillation propagates from turn to turn and then to the control stem and the oscillation therefore produces to and fro movements creating disturbances in the fuel flow. The propagation of the oscillation comes to disturb the movement of the armature fastened to the control stem member. There then arise oscillations in the forces applied to close or to open the control valve. This problem is explained by a disturbed movement of the armature caused by oscillations to which the spring is subjected. Moreover, this problem will be solved by the present invention, which is to be described later.
The present invention aims to solve the problem of movement of the armature caused by the oscillations to which the spring is subjected. The invention consists in a coil assembly of an electromagnetic actuator adapted to be used in a fuel injector. The coil assembly comprises a magnetic core extending along a principal axis, a winding wound around the core, the winding being overmolded to form a cylindrical overmolding and extending axially from a transverse first face to a second surface 48. The overmolded coil assembly further comprises an axial blind hole extending toward the interior of the coil assembly from the first surface at a distal end. The blind hole is adapted to house at least one spring in order to load a magnetic armature. The coil assembly is further provided with a degassing hole passing through the core and the overmolding from the axial blind hole to an axial cylindrical external surface. The degassing hole is formed in the magnetic core. The degassing hole has a restriction in a first section that is proximal to the axial blind hole. The first section has a first diameter D62 and a first length L62 with the following characteristics:
The degassing hole has a second section with a second diameter D64 at a proximal end of a return circuit and a second length L64:
The degassing hole is disposed proximally to the distal end of the axial blind hole.
The degassing hole is proximal to the first face of the winding.
Moreover a diameter D50b of the blind hole is less than a mean diameter D50a of the axial blind hole with which the first section of the calibrated degassing hole communicates.
The degassing hole is at an angle to the principal axis between 80 degrees and 120 degrees inclusive. The angle may be 90°.
Moreover an actuator of the fuel injector comprises the coil assembly as described above. Also a fuel injector comprises the actuator as described above.
A method of manufacturing a coil assembly as described above comprises the following steps:
The degassing hole may be produced using an attached part during the overmolding of the wire.
Other features, aims and advantages of the invention will become apparent on reading the following detailed description with reference to the appended drawings provided by way of nonlimiting example:
To facilitate and clarify the following description, the top to bottom orientation is chosen arbitrarily and words and expressions such as “hereinabove, below, above, below, top, bottom . . . ” may be used without any intention of limiting the invention.
The injector 10 extends along a longitudinal axis X and comprises, from bottom to top in the conventional and nonlimiting direction of the figures, a nozzle assembly 12 comprising a valve element 14 or as it is commonly called a needle 14 arranged in a nozzle body 16, a control stem 34 arranged in a valve body 20, an actuator 22 arranged in an actuator body 24. The needle 14 is arranged to slide axially in a cylindrical longitudinal bore 26 in the nozzle body between a closed position in which the needle 14 is in contact with a nozzle body seat (not shown) and an open position in which the needle 14 is moved away from the seat (not shown).
As described in
A first embodiment is described now with reference to
The degassing hole 58 has a first section 62 having a first diameter D62 and a first length L62 with the following characteristics:
The choice of these dimensions enables complete reduction of the return waves of the fluid in the axial blind hole 50.
The degassing hole 58 has a second section 64 with a second diameter D64 between the first section 62 and the exterior transverse surface 60 proximal to the leak return circuit 61 and a second length L64:
Similarly the choice of the dimensions of the two sections 62, 64 enables less turbulent flow toward the leak return circuit 61.
The degassing hole 58 is disposed proximally to the distal second end 52. In other alternatives not shown the degassing hole 58 may be proximal to the first end 51 of the blind hole. The degassing hole 58 is at an angle of 90° to the principal axis X. In an alternative embodiment not shown the degassing hole 58 may be at an angle to the principal axis X between 80 degrees and 120 degrees inclusive.
The blind hole 50 extends along the longitudinal axis X. The blind hole 50 has a first diameter D50a and a second diameter D50b. The first diameter D50a is the mean diameter of the hole 50. The second diameter D50b is less than the mean or first diameter D50a of the hole.
The elastic device 32 comprises two coil springs 54, 56 separated by a separator member 66 or pin 66. In other alternatives of the elastic device 32 may comprise a single spring 54, 56. The elastic device 32 is arranged in the axial blind hole 50. In
The method of manufacturing the coil assembly 28 comprises the following steps:
The calibrated degassing hole 58 is therefore formed in the magnetic part 38. The degassing hole 58 may be produced by laser technology or by any other means. The shape of the degassing hole 58 may be round, square or conical or any other shape.
In this chapter we are going to describe the operation of the injector 10. As described in
The following references have been used in the description:
Number | Date | Country | Kind |
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1658148 | Sep 2016 | FR | national |
This application is a national stage application under 35 USC 371 of PCT Application No. PCT/EP2017/071046 having an international filing date of Aug. 21, 2017, which is designated in the United States and which claimed the benefit of FR Patent Application No. 1658148 filed on Sep. 1, 2016, the entire disclosures of each are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/071046 | 8/21/2017 | WO | 00 |