[0001] The present invention relates to a valve assembly for a fluid injection valve and
to a fluid injection valve, e.g. a fuel injection valve of a vehicle. It particularly
relates to solenoid injection valves.
[0002] Fuel injection valves are required to deliver fuel very accurately to fulfill legislative
emission regulations such as the EURO 6 C regulation. The amount of fuel injected
during one injection event and the spray distribution, such as cone shape and droplet
size, need to be accurately controlled to comply with these requirements.
[0003] One problem that may occur in controlling the injection characteristics of injection
valves is an uncontrolled re-opening of the valve at the end of an injection event.
This may be caused by the valve needle rebounding from the valve seat, e.g. due to
the momentum transfer when the valve needle hits the valve seat. The uncontrolled
reopening generates an undesired additional injection which may additionally have
a poor atomization of the fluid.
[0004] Such needle rebound can be reduced in solenoid injection valve by decoupling the
magnetic armature from the valve needle to reduce the effective mass for the momentum
transfer when the valve needle hits the valve seat. However, in such valves, the armature
continues moving when the movement of the valve needle is stopped by the valve seat.
The kinetic energy of the armature has to be dissipated so that the injection valve
can come to rest in its closed configuration. This requires damping of the armature
movement relative to the valve needle.
[0005] EP 2 597 296 A1 discloses a valve assembly for an injection valve, with a valve body including a
central longitudinal axis, the valve body comprising a cavity with a fluid inlet portion
and a fluid outlet portion, with a valve needle axially movable in the cavity, the
valve needle preventing a fluid flow through the fluid outlet portion in a closing
position and releasing the fluid flow through the fluid outlet portion in further
positions, with an upper retainer being arranged in the cavity and being fixedly coupled
to the valve needle, with an electro-magnetic actuator unit being designed to actuate
the valve needle, the actuator unit comprising an armature arrangement which is arranged
in the cavity and is axially moveable relative to the valve needle, the armature arrangement
being designed to be coupled to the upper retainer when the valve needle is actuated
to leave the closing position, the armature arrangement being designed and arranged
to mechanically decouple from the upper retainer due to its inertia when the valve
needle reaches the closing position.
[0006] DE 10 2013 222 613 A1 discloses a valve for adding fluid which comprises an electromagnet for actuating
a valve needle which controls an adding opening. When energized, the electromagnet
generates a magnetic flux which passes through an outer pole, a hollow cylindrical
inner pole, an armature which can be displaced on the valve needle and a working air
gap limited by the armature and the inner pole. On opposing sides of the armature,
a driver and an armature stop are fixedly arranged on the valve needle which limits
a free- or pre-stroke of the armature relative to the valve needle which is smaller
than the axial gap width of the working air gap. A pre-stroke spring which is arranged
on the valve needle presses the armature against the armature stop.
[0007] WO 2017/009103 A1 discloses a valve for metering a fluid which can be designed in particular as a fuel
injection valve for internal combustion engines, comprising an electromagnetic actuator
and a valve needle which can be actuated by the actuator and which is used to actuate
a valve closing body which interacts with a valve face to form a sealing seat. An
armature of the actuator comprises an opening through which the valve needle extends.
Also, an annular gap is formed between an inner wall of a housing part and an outer
side of the armature. Said armature can be moved on the valve needle, a stop which
is stationary with respect to the valve needle is provided on the valve needle, on
which the armature impacts, due to an activation used to open the valve seat which
occurs in the direction of opening. At least one throttle element is arranged in the
annular gap, said throttle element being connected to the armature or to the housing
part. Due to the throttle element, at least one movement of the armature counter to
the opening direction is damped.
[0008] It is an object of the present disclosure to provide a valve assembly for an injection
valve and an injection valve enabling an improved and/or cost-effective damping of
the armature movement.
[0009] This object is achieved by means of a valve assembly according to the independent
claim. Advantageous embodiments and developments of the valve assembly and the injection
valve are specified in the dependent claims, the following description and the drawings.
[0010] According to a first aspect of the present disclosure, a valve assembly for a fluid
injection valve is specified.
[0011] The valve assembly comprises a valve needle. Further, it comprises an armature of
an electro-magnetic actuator assembly. The armature is axially displaceable relative
to the valve needle along a longitudinal axis. In other words, the armature can slide
along the valve needle in reciprocating fashion in direction along the longitudinal
axis.
[0012] The armature may expediently be operable to actuate the valve needle. In particular,
the armature is configured for axially displacing the valve needle away from a closing
position, in particular against the bias of a calibration spring of the valve assembly,
the calibration spring being preloaded to bias the valve needle towards the closing
position. The armature is preferably mechanically coupled to the valve needle in such
fashion that it takes the valve needle with it when it moves towards a stationary
pole piece of the actuator assembly.
[0013] The armature has an upper side and a lower side, opposite of the upper side. The
upper and lower sides represent in particular opposite axial ends of the armature.
The armature comprises a recess at the upper side. The recess has a circumferential
side surface and a bottom surface. The circumferential side surface and the bottom
surface of the recess are herein also denoted as "first circumferential surface" and
"first bottom surface". Further, the armature comprises a circumferential surface
which defines a central bore through the armature. The circumferential surface which
defines the central bore is herein also denoted as "second circumferential side surface".
The central bore extends from the first bottom surface to the lower side of the armature.
The bottom surface of the recess in particular is perforated by an aperture o the
central bore. It is in particular an annular surface which extends circumferentially
around the central bore.
[0014] The valve needle comprises a shaft and a retaining element. The retaining element
is fixed to the shaft. This is understood in the present context to comprise also
embodiments in which the retaining element is in one piece with the shaft. In an expedient
embodiment, the valve needle further comprises a sealing element such as a sealing
ball. The sealing element may expediently be fixed to an axial end of the shaft remote
from the retaining element. The armature is in particular operable to engage in form-fit
contact with the retaining element for axially displacing the valve needle away from
the closing position.
[0015] The retaining element has an external circumferential surface and a bottom surface.
The external circumferential surface and the bottom surface of the retaining element
are herein also denoted as "first external circumferential surface" and "second bottom
surface". The shaft has an external circumferential surface, also denoted herein as
"second external circumferential surface".
[0016] At least a portion of the retaining element is arranged in the recess so that the
first bottom surface opposes the second bottom surface. In particular, the form-fit
contact of the armature with the retaining element for axially displacing the valve
needle away from the closing position is established between the bottom surfaces of
the retaining element and the recess. The recess and the retaining element are dimensioned
such that a radial gap is established between the first circumferential surface and
the first external circumferential surface for establishing a fluid leakage path from
the upper side to the first bottom surface.
[0017] The shaft extends through the central bore. The shaft and the central bore are dimensioned
such that a radial gap is established between the second circumferential surface and
the second external circumferential surface for establishing a fluid leakage path
from the lower side to the first bottom surface.
[0018] A "fluid leakage path" is understood in the present context to provide a fluid path
which is in particular dimensioned that its contribution to the fluid flow is insignificant.
In particular, the valve assembly comprises at least one main fluid path in parallel
to the above described fluid leakage paths. The hydraulic diameter of the main fluid
path is preferably at least ten times as large, for example at least 20 times as large,
as the hydraulic diameter of each of the fluid leakage paths. Preferably, the radial
gaps establishing the fluid leakage paths are larger than required due to manufacturing
tolerances of the armature, the retaining element and the shaft. In one embodiment,
each of the radial gaps has a gap width of 10 µm or more, for example of 50 µm or
more. Expediently, the gap width may have a value of 200 µm or less, in particular
of 150 µm or less.
[0019] With advantage, due to the flow resistance through the fluid leakage paths, a large
hydraulic damping is achievable when the bottom surface of the recess and the retaining
element move axially away from one another or approach one another. The amount of
the hydraulic damping force may in particular be dominated by the flow resistance
of the fluid leakage paths. Therefore, the damping effect may advantageously be particularly
insensitive with respect to the distance between the bottom surfaces and/or with respect
to manufacturing tolerances such as the planarity of the bottom surfaces.
[0020] With advantage, additional components - such as a disc element fixed to the shaft
of the valve needle or fixed into a valve body of the valve assembly on the lower
side of the armature, remote from the retaining element - can be omitted. This makes
the valve assembly particularly cost-efficient - e.g. due to reduced number of components
and simpler manufacturing of the armature-needle assembly. It may also be advantageous
for the fluid flow through the valve assembly. In particular, the risk that throttling
elements impede the fluid flow may be particularly small in this way.
[0021] The hydraulic damping force is advantageously generated between surfaces which are
not involved in stopping the armature at the end of its opening transient. Surfaces
which are involved in stopping the armature at the end of the opening transient often
experience large mechanical stress and are subject to wear. This requires costly hard-coatings
to guarantee the tolerances which are required for achieving the damping effect. Such
hard-coatings on the damping surface may be avoidable in the subject valve assembly.
[0022] In one embodiment, the first bottom surface and the second bottom surface are coplanar.
Preferably they have an annular overlapping area. The bottom surfaces of the recess
are preferably unperforated. The annular overlapping area then extends in particular
from the inner circumferential surface to the first external circumferential surface.
In this way, a particularly large hydraulic damping force is achievable.
[0023] In an expedient embodiment, the valve assembly further comprises an armature return
spring which is preloaded and biases the first bottom surface in form-fit contact
with the second bottom surface. This may enable the armature to actuate the valve
needle particularly quickly without delay until the armature can take the valve needle
with it on its travel by means of form-fit contact between the bottom surfaces of
retaining element and the recess.
[0024] In one embodiment, the axial extension of the second circumferential surface is at
least twice as large as the axial extension of the first circumferential surface.
In this way, the leakage path from the bottom surface of the recess to the lower side
of the armature is at least twice as large as the leakage path from the upper side
of the armature to the bottom surface of the recess. This may be advantageous for
achieving suitable leak rates - in particular similar leak rates - through the fluid
leakage paths in the presence of a pressure gradient along the armature.
[0025] In one embodiment, the vale assembly comprises a valve body, in particular sharing
the central longitudinal axis with the valve needle. The valve body comprises a cavity
with a fluid inlet portion and a fluid outlet portion. The valve needle is received
in the cavity.
[0026] The valve needle is axially moveable relative to the valve body. The valve needle
prevents a fluid flow through the fluid outlet portion in the closing position and
releases the fluid flow through the fluid outlet portion in further positions. In
particular, the valve needle is axially displaceable relative to the valve body away
from the closing position for releasing the fluid flow. The armature may expediently
be arranged in the cavity of the valve body. It is axially displaceable in reciprocating
fashion relative to the valve body.
[0027] The valve assembly may expediently comprise a calibration spring which biases the
valve needle towards closing position, i.e. in axial direction towards the fluid outlet
portion in the case of an inward opening valve assembly. One axial end of the calibration
spring may be seated against the retaining element.
[0028] In one embodiment, the armature return spring is seated against the armature and
against a step of the valve body at its opposite axial ends. Preferably, absent the
armature return spring, axial displaceability of the armature with respect to the
valve body and the valve needle in direction away from the retaining element is limited
by said step, and only by said step. This may enable a particularly unimpaired fluid
flow through the cavity below the armature. In particular, apart from the shaft of
the valve needle and the armature return spring, no other elements of the valve assembly
- which could impair the fluid flow - may be arranged in the cavity in the region
between the armature and the step.
[0029] In one embodiment, at least one guiding surface is provided on an outer surface of
the armature. This means in particular that the outer surface of the armature has
a section which represents the guiding surface. The guiding surface interacts with
an inner surface of the valve body to guide the axial movement of the armature. In
particular, the guiding surface is in sliding mechanical contact with the inner surface
of the valve body. The "outer surface" of the armature is in particular understood
in the present context to be an external surface of the armature, in particular an
external circumferential surface of the armature. In particular, the outer surface
delimits the armature laterally in radial outward direction. Thus, the outer surface
is in particular the surface of the armature opposing the inner surface of the valve
body. The inner surface of the valve body in particular defines the cavity.
[0030] A plurality of flow passages are formed in the outer surface of the armature. The
flow passages may expediently extend axially along the armature at its periphery,
i.e. at the external surface opposing the inner surface of the valve body. In particular,
the outer surface has recessed further sections. The recessed further sections may
expediently be spaced apart from the inner surface of the valve body to define the
flow passages.
[0031] In a preferred embodiment, the armature has a plurality of guiding surfaces which
are spaced apart from one another in circumferential direction. In particular, the
guiding surfaces are separated from one another in circumferential direction by the
flow passages.
[0032] With advantage, the armature is guided by the guiding surface on the outer surface
of the armature and not by valve needle or by an armature retainer which is fixed
to the valve needle. The flow passages at the periphery of the armature can be manufactured
particularly simply and cost-efficiently. The guiding surfaces on the outer surface
of the armature are manufacturable with particular small tolerances, allowing a particularly
precise axial guidance of the armature.
[0033] The upper side of the armature has in particular a top surface of the armature which
is facing in axial direction towards the pole piece. Preferably, the top surface is
a planar surface which extends radially from the outer circumferential contour of
the upper armature retainer to the outer surface of the armature. This is possible,
because guidance of the valve needle is not effected by way of the upper armature
retainer. A radial flow path with particularly small turbulences is achievable in
this way.
[0034] According to one embodiment, the flow passages provided in the outer surface are
flattened surface sections extending in axial direction from the upper side of the
armature to a lower side of the armature. The lower side in particular comprises a
lower surface of the armature, facing towards the fluid outlet portion in case of
an inward opening valve. The lower side is in particular facing away from the pole
piece. This embodiment has the advantage, that the flow passages can be very easily
formed during manufacture of the armature by flattening the cylindrical surface of
the armature in some places by a suitable process.
[0035] According to one embodiment, the armature is solid and in particular does not comprise
fuel passages on the inside. In particular, the top surface of the armature, extending
radially outward from the retaining element to the outer surface of the armature is
unperforated. That the armature does not comprise fuel passages on the inside means
in particular that the armature has one, and only one, axial opening which is defined
by the recess and the central bore.
[0036] The injection valve has the advantage, that it enables a no-hard-stop-concept and
therefore eliminates the necessity of a hardening coating on the pole piece and the
upper side of the armature. This is due to the fact that the only flow path is built
by the flow passages on the outer surface of the armature. Apart from the small amount
through the leakage paths which is in particular negligible for the flow rate through
the valve assembly, fluid does not flow in passages inside the armature, for no such
passages on the inside are provided. As a consequence, during an opening phase of
the injection vale, there is a pressure gradient across the upper side of the armature,
suspending the armature in a stable position and building up a sufficient hydraulic
force to stop the armature from contacting the pole piece. Thus, fluid can pass between
the lower side of the pole piece and the upper side of the armature. In this way,
a stable suspended stop position for the armature is achievable. The spring rate of
the calibration spring is in particular adapted to the magnetic force of the actuator
assembly in such fashion that the spring force of the calibration spring alone is
smaller than the magnetic force on the armature during operation of the actuator assembly.
Such a comparatively small spring rate may be advantageous for the dynamic behavior
of the valve assembly. Due to the valve assembly having only flow paths along the
passages on the outside of the armature, the spring force of the calibration spring
is supplemented by the hydraulic force generated by the pressure drop along the radial
flow path along the upper side of the armature. This leads to suspension of the armature
in the maximum opening position of the valve assembly at a distance from the pole
piece.
[0037] In this way, a monotonous and preferably linear dependence of the amount of fuel
which is dispensed by the valve assembly during one injection event on the valve opening
time is achievable. The valve opening time is in particular the amount of time for
which a coil of the actuator assembly is energized during one injection event for
generating a magnetic force on the armature to actuate the valve needle. Conventional
valve assembly usually exhibit an S-shaped "wiggle" and a change of slope in the region
of valve opening times at the transition from a ballistic operation mode to an operation
mode where the armature hits the pole piece during the injection event. In this context
a "ballistic operation mode" is an operation mode for injecting small amounts of fluid
in which the coil is energized for such a short time that the valve needle does not
reach its fully open position before it starts returning to the closing position.
[0038] An anti-friction coating may be provided on the at least one guiding surface on the
outer surface of the armature. The anti-friction coating may in particular comprise
tungsten carbon carbide (WCC) or diamond-like carbon (DLC). The coating has the advantage,
that it reduces noise, wear and facilitates guidance of the valve needle.
[0039] According to a further aspect of the present disclosure, a fluid injection valve
with the valve assembly according to at least one of the above embodiments is provided.
The injection valve may in particular be a fuel injection valve of a vehicle. Preferably,
the valve assembly if the fluid injection valve has a solid armature which is free
of internal flow channels as described above.
[0040] Further advantages, advantageous embodiments and developments of the valve assembly
for an injection valve and the fluid injection valve will become apparent from the
exemplary embodiments which are described below in association with the schematic
figures.
- Figure 1
- shows a longitudinal section of an injection valve according to one embodiment of
the invention,
- Figure 2
- shows a detail of figure 1,
- Figure 3
- shows the valve assembly of figure 2 with dimensions of the valve assembly being indicated,
and
- Figure 4
- shows a cross section of the valve assembly according to the embodiment shown in figures
1, 2 and 3.
[0041] In the exemplary embodiments and figures, identical, similar or similarly acting
constituent parts are provided with the same reference symbols. In some figures, individual
reference symbols may be omitted to improve the clarity of the figures.
[0042] The fluid injection valve 1 shown in figure 1 is in particular suitable for dosing
fuel to a combustion engine, preferably for dosing fuel directly into a combustion
chamber of the engine.
[0043] The injection valve 1 comprises a valve assembly 3. A detailed longitudinal section
view of the valve assembly 3 is shown in figures 2 and 3. Some reference symbols are
only shown in Fig. 2 and others are only shown in Fig. 3 to improve the clarity of
the figures. Figure 4 shows a cross-sectional view of the valve assembly 3.
[0044] The valve assembly 3 comprises a valve body 4 with a central longitudinal axis L.
A housing 6 is partially arranged around the valve body 4.
[0045] The valve body 4 is hollow so as to define a cavity 9. The cavity 9 has a fluid outlet
portion 7. The fluid outlet portion 7 communicates with a fluid inlet portion 5 which
is provided in the valve body 4. The fluid inlet portion 5 and the fluid outlet portion
7 are in particular positioned at opposite axial ends of the valve body 4. The cavity
9 takes in a valve needle 11. The valve needle 11 comprises a needle shaft 13 and
a sealing ball 12 welded to the tip of the needle shaft 13. The valve needle 11 further
comprises a retaining element 24. The retaining element 24 is positioned adjacent
to an axial end of the needle shaft 13 remote from the sealing ball 12 and is fixedly
coupled to the needle shaft 13 by a welded joint (roughly indicated by the triangles
in Fig. 2).
[0046] In a closing position of the valve needle 11, its sealing element 12 sealingly rests
on a valve seat comprised by a seat element 14 having at least one injection nozzle.
The fluid outlet portion 7 is arranged near the seat element 14. The seat element
14 closes the fluid outlet portion 7 of the valve body 4. In the closing position
of the valve needle 11, a fluid flow through the at least one injection nozzle is
prevented. The injection nozzle may be, for example, an injection hole. However, it
may also be of some other type suitable for dosing fluid.
[0047] A preloaded calibration spring 18 exerts a force on the valve needle 11, biasing
the valve needle 11 towards the closing position. One axial end of the calibration
spring 18 is seated against the retaining element 24 for transferring the spring force
of the calibration spring 18 to the valve needle 11. The other axial end of the calibration
spring 18 is positionally fix relative to the valve body 4.
[0048] The injection valve 1 is provided with an electro-magnetic actuator assembly 19 to
actuate the valve needle 11. Portions of the actuator assembly 19 are shown in Fig.
2 but are omitted in Fig. 3.
[0049] The electro-magnetic actuator assembly 19 comprises a solenoid 21, i.e. an electromagnetic
coil, which is preferably arranged inside the housing 6 and surrounds the valve body
4. Furthermore, the electro-magnetic actuator assembly 19 comprises an armature 23
and a pole piece 25. The housing 6, parts of the valve body 4, the pole piece 25 and
the armature 23 form a magnetic circuit.
[0050] The pole piece 25 is fixed to the valve body 4, in particular inside the cavity 9,
in the present embodiment. It can also be in one piece with the valve body 4. The
armature 23 is arranged in the cavity 9 of the valve boy 4. It is axially displaceable
in reciprocating fashion relative to the valve body 4. In this way, the pole piece
25 and the armature 23 represent a stationary core and a movable core, respectively,
of the actuator assembly 19. A substantially planar, radially extending upper side
27 of the armature 23 is facing towards a lower side 31 of the pole piece 25. A lower
side 41 of the armature 23, remote from the upper side 27, faces away from the pole
piece 25 and in the present embodiment towards the fluid outlet portion 7.
[0051] The armature 23 has a central axial opening through which the valve needle 11 extends.
The central axial opening is formed by a recess 33 which extends into the armature
23 from the upper side 27 and by a central bore 34 which extends from the lower side
41 of the armature 23 to the recess 33.
[0052] The recess 33 has a circumferential surface 231 - i.e. a first internal circumferential
surface of the armature 23 - and a bottom surface 233. The bottom surface 233 is arranged
opposite of the opening of the recess at the upper side 27 and preferably coplanar
with the upper side 27. The circumferential surface 231 is in particular a cylindrical
surface.
[0053] The central bore 34 is defined by a circumferential surface 341 which is a second
internal circumferential surface of the armature 23. The second internal circumferential
surface 341 is preferably also a cylindrical surface. At its opposite axial ends,
the central bore 34 opens out into the bottom surface 233 of the recess 33 and into
the lower side 41 of the armature 23.
[0054] The retaining element 24 has a - preferably cylindrical - external circumferential
surface 241 and a bottom surface 243. The retaining element 24 is embedded into the
recess 33 of the armature 23 so that the upper side 27 of the armature 23 and an upper
side 29 of the upper retaining element 24 are coplanar and the bottom surface 243,
233 of the retaining element 24 and the recess 33 of the armature 23 face towards
each other. The shaft 13 of the valve needle 11 projects on both sides from the retaining
element 24 and extends through the central bore 34 in direction towards the lower
side 41 of the armature 23 where it protrudes from the central bore 34 towards the
fluid outlet portion 7.
[0055] The armature 23 is axially movable relative to the valve needle 11, i.e. it may slide
on the needle 11. Axial displaceability of the armature 23 relative to the valve needle
11 in direction towards the pole piece 25 is limited by the retaining element 24.
Specifically, the bottom surfaces 243, 233 of the retaining element 24 and of the
recess 33 of the armature are coplanar and have an annular overlapping area 32 so
that they are engageable in form-fit connection with one another for limiting the
axial displaceablility of the armature 23 relative to the valve needle 11 in direction
towards the pole piece 25. In the present embodiment, the annular overlapping area
32 extends in radial direction from the external circumferential surface 131 of the
needle shaft 13 to the external circumferential surface 241 of the retaining element
24.
[0056] Between the external circumferential surface 241 of the retaining element 24 and
the circumferential surface 231 of the recess 33, a first radial gap G1 is established.
The first radial gap G1 has a gap width of (D1 - D0)/2, where D1 is the diameter of
the circumferential surface 231 of the recess 33 and D0 is the diameter of the external
circumferential surface 241 of the retaining element 24.
[0057] A second radial gap G2 is established between the circumferential surface 341 of
the central bore 34 and external circumferential surface 131 of the needle shaft 13.
The second radial gap G2 has a gap width of (D4 - D3)/2, where D4 is the diameter
of the circumferential surface 341 of the central bore 34 and D3 is the diameter of
the external circumferential surface 131 of the needle shaft 13 in the region where
it axially overlaps the central bore 34.
[0058] The first radial gap G1 defines a first fluid leakage path which extends from the
upper side 27 of the armature to the bottom surface 233 of the recess 33. The second
radial gap G2 defines a second fluid leakage path which extends from the lower side
41 of the armature to the bottom surface 233 of the recess 33. The length of the second
fluid leakage path G2 is between 3 and 4 times as large as the length of the first
fluid leakage path G1, the limits being included, in this and other embodiments. The
lengths of the first and second fluid leakage paths are in particular defined by the
lengths of the circumferential surfaces 231, 341 of the recess 33 and of the central
bore 34, respectively.
[0059] At least a part of the outer surface 35 of the armature 23 serves as a guiding surface
36 interacting with an inner surface 37 of the valve body 4.
[0060] Figure 4 shows a cross section of parts of the valve assembly 3 along a plane including
the upper retaining element 24. Along the outer surface 35 of the armature 23, a number
of flow passages 39 are formed by flattened sections of the outer surface 35, extending
from the upper side 27 of the armature 23 to the lower side 41 of the armature 23.
Along those flow passages 39, fluid can flow from the fluid inlet portion 5 towards
the fluid outlet portion 7, when the injection valve 1 is open.
[0061] When the actuator assembly is de-energized in a closed configuration of the valve
assembly 3, the bottom surface 233 of the recess 33 of the armature 23 is in form-fit
engagement with the bottom surface 243 of the retaining element 24 due to an armature
return spring which biases the armature 23 in axial direction towards the upper armature
retainer 24. When the solenoid 21 is energized, the armature 23 experiences a magnetic
force and slides upwards - i.e. in axial direction towards the pole piece 25. Due
to the form-fit connection with the retaining element 24, it takes the valve needle
11 with it in axial direction away from the fluid outlet portion 7, thereby compressing
the calibration spring 18. Consequently, the valve needle 11 moves in axial direction
out of the closing position of the valve 1.
[0062] Fuel starts to flow from a central opening of the pole piece 25 in radial outward
direction along the upper armature retainer 24 and the upper surface 27 of the armature
23 and, because there are no passages formed on the inside of the armature 23, to
the outer surface 35 of the armature 23. There, the fuel flows further along the passages
39 in the outer surface 35 of the armature 23 and towards the fluid outlet portion
7. It has to be noted that fluid cannot flow through the first and second fluid leakage
paths through the armature 23 from its upper side 27 to its lower side 41 due to the
form-fit connection in the overlapping area 32 of the bottom surfaces 233, 241 of
the recess 33 of the armature 23 and of the retaining element 24 which blocks fluid
flow from the first to the second fluid leakage path.
[0063] As the armature 23 approaches the pole piece 25, the residual gap between the upper
side 27 of the armature 23 and the lower side 31 of the pole piece 25 decreases. The
decreasing hydraulic diameter of the residual gap effects an increasing pressure difference
between the upper side 27 and the lower side 41 of the armature 23. The pressure difference
generates a hydraulic force on the armature 23 in axial direction away from the pole
piece 25. The magnetic force of the actuator assembly 19 and the spring force of the
calibration spring 18 are adapted to the hydraulic force which is generated under
normal operating conditions of the injection valve 1 that the spring force and the
hydraulic force exceed the magnetic force before the residual gap is completely closed.
[0064] Therefore, the armature 23 stops moving upwards before contact with the pole piece
25 is made. Thus, in a maximum opening position of the valve 1, in which the needle
11 has travelled furthest upwards away from the fluid outlet portion 7, a residual
gap is still present between the upper side 27 of the armature 23 and the lower side
31 of the pole piece 25. The residual gap stays open because of the hydraulic force
the fuel exerts on the upper side 27 of the armature 23 and the upper side 29 of the
upper armature retainer 24. Consequently, there is no hard stop for the armature 23
in the maximum opening position.
[0065] In fact, the armature 23 is suspended in the maximum opening position by an equilibrium
of forces in a stable position. In the maximum opening position, a magnetic force
acting in a direction away from the fluid outlet portion 7 is balanced by the sum
of a hydraulic force and a spring force exerted by the calibration spring 18 both
acting in a direction towards the fluid outlet portion 7.
[0066] When the solenoid 21 is de-energized, the calibration spring 18 is able to force
the valve needle 11 to move in axial direction into its closing position. The valve
needle 11 takes the armature 23 with it by means of the form-fit connection between
the bottom surfaces 243, 233 of the retaining element 24 and the recess 33 of the
armature 23.
[0067] When the sealing element 12 hits the seat element 14, movement of the valve needle
11 relative to the valve body 4 is stopped while the armature travels further in direction
away from the pole piece 25 relative to the valve body 4 and the valve needle 11.
Thus, an axial gap opens between the bottom surfaces 241, 231 o the retaining element
24 and the recess 33 of the armature 23.
[0068] In addition to the bias of the armature return spring 38, the filling of said axial
gap by fluid flow through the first and second leakage paths, dampens the movement
of the armature 23 until the kinetic energy of the armature 23 is dissipated and the
armature movement away from the pole piece 25 is stopped.
[0069] Then, the armature return spring 38 forces the bottom surface 233 of the recess 33
of the armature 23 back in contact with the bottom surface 243 of the retaining element
24, thereby decreasing the gap width of the axial gap between the bottom surfaces
243, 233 to zero. Also this movement is damped by the flow resistances of the first
and second leakage paths when squeezing fluid out of the axial gap through the first
and second leakage paths.
1. Valve assembly (3) for a fluid injection valve (1), comprising a valve needle (11)
and an armature (23) of an electro-magnetic actuator assembly (19),
wherein
- the armature (23) is axially displaceable relative to the valve needle (11) along
a longitudinal axis (L),
- the armature (23) comprises a recess (33) at an upper side (27), the recess (33)
having a first circumferential surface (231) and a first bottom surface (233), and
a second circumferential surface (341) defining a central bore (34) which extends
from the first bottom surface (233) to a lower side (41) of the armature (23), opposite
of the upper side (27),
- the valve needle (11) comprises a retaining element (24) fixed to a shaft (13) of
the valve needle (11), the retaining element (24) having a first external circumferential
surface (241) and a second bottom surface (243) and the shaft having a second external
circumferential surface (131),
- at least a portion of the retaining element (24) is arranged in the recess (33)
so that the first bottom surface (233) opposes the second bottom surface (243) and
the shaft (13) extends through the central bore (34),
- the recess (33) and the retaining element (24) are dimensioned such that a first
radial gap (G1) is established between the first circumferential surface (231) and
the first external circumferential surface (241) for establishing a first fluid leakage
path from the upper side (27) to the first bottom surface (233), and
- the shaft (13) and the central bore (34) are dimensioned such that a second radial
gap (G2) is established between the second circumferential surface (341) and the second
external circumferential surface (131) for establishing a second fluid leakage path
from the lower side (41) to the first bottom surface (233).
2. Valve assembly (3) according to the preceding claim, wherein the first bottom surface
(233) and the second bottom surface (243) are coplanar and have an annular overlapping
area (32), extending in particular from the inner circumferential surface (341) to
the first external circumferential surface (241).
3. Valve assembly (3) according to the one of the preceding claims, further comprising
an armature return spring (38) which is preloaded and biases the first bottom surface
(233) in form-fit contact with the second bottom surface (243).
4. Valve assembly (3) according to the one of the preceding claims, wherein an upper
side (29) of the retaining element (24) is coplanar with an upper side (27) of the
armature (23).
5. Valve assembly (3) according to the one of the preceding claims, wherein the axial
extension (L2) of the second circumferential surface (341) is at least twice as large
as the axial extension (L1) of the first circumferential surface (231).
6. Valve assembly (3) according to one of the preceding claims, further comprising
- a valve body (4) comprising a cavity (9) with a fluid inlet portion (5) and a fluid
outlet portion (7), the valve needle (11) being received in the cavity (9), the valve
needle (11) preventing a fluid flow through the fluid outlet portion (7) in a closing
position and axially displaceable relative to the valve body (4) away from the closing
position for releasing the fluid flow through the fluid outlet portion (7).
7. Valve assembly (3) according to the preceding claim,
wherein the armature return spring (38) is seated against the armature (23) and against
a step (8) of the valve body (4) at its opposite axial ends and, absent the armature
return spring (38), axial displaceability of the armature (23) with respect to the
valve body (4) and the valve needle (11) in direction away from the retaining element
(24) is limited by said step (8).
8. Valve assembly (3) according to one of the preceding claims 6 and 7,
wherein the armature (23) comprises
- at least one guiding surface (36) on an outer surface (35) of the armature (23),
the guiding surface (36) interacting with an inner surface (37) of the valve body
(4) to guide the axial movement of the armature (23) and
- a plurality of flow passages (39) formed in the outer surface (35) of the armature
(23).
9. Valve assembly (3) according to the preceding claim comprising a plurality of guiding
surfaces (36), wherein the outer surface (35) is an external circumferential surface
of the armature (23) having a plurality of sections representing the guiding surfaces
(36) and a plurality of further sections representing the flow passages (39), the
guiding surfaces (36) being separated from one another in circumferential direction
by the flow passages (39).
10. Valve assembly (3) according to one of the preceding claims 8 and 9,
wherein the flow passages (39) provided in the outer surface (35) are flattened surface
sections extending in axial direction from the upper side (27) of the armature (23)
to a lower side (41) of the armature (23).
11. Valve assembly (3) according to one of the preceding claims 8 to 10,
wherein an anti-friction coating is provided on the at least one guiding surface (36)
on the outer surface (35) of the armature (23).
12. Valve assembly (3) according to one of the preceding claims, wherein the armature
(23) is solid and does not comprise fuel passages on the inside.
13. Valve assembly (3) according to one of the preceding claims, further comprising a
calibration spring (18) biasing the valve needle (11) towards the closing position
14. Fluid injection valve (1) with a valve assembly (3) according to one of the preceding
claims.
1. Ventilanordnung (3) für ein Fluidinjektionsventil (1), umfassend eine Ventilnadel
(11) und einen Anker (23) einer elektromagnetischen Aktuatoranordnung (19),
wobei
- der Anker (23) relativ zur Ventilnadel (11) entlang einer Längsachse (L) axial verschiebbar
ist,
- der Anker (23) an einer oberen Seite (27) eine Aussparung (33) umfasst, wobei die
Aussparung (33) eine erste Umfangsfläche (231) und eine erste Bodenfläche (233) aufweist
und wobei eine zweite Umfangsfläche (341) eine zentrale Bohrung (34) definiert, die
sich von der ersten Bodenfläche (233) zu einer unteren Seite (41) des Ankers (23)
gegenüber der oberen Seite (27) erstreckt,
- die Ventilnadel (11) ein Halteelement (24) umfasst, das an einem Schaft (13) der
Ventilnadel (11) befestigt ist, wobei das Halteelement (24) eine erste äußere Umfangsfläche
(241) und eine zweite Bodenfläche (243) aufweist und wobei der Schaft eine zweite
äußere Umfangsfläche (131) aufweist,
- zumindest ein Abschnitt des Halteelements (24) in der Aussparung (33) angeordnet
ist, sodass die erste Bodenfläche (233) der zweiten Bodenfläche (243) gegenüberliegt
und der Schaft (13) sich durch die zentrale Bohrung (34) erstreckt,
- die Aussparung (33) und das Halteelement (24) so bemessen sind, dass zwischen der
ersten Umfangsfläche (231) und der ersten äußere Umfangsfläche (241) ein erster Radialspalt
(G1) eingerichtet ist, um einen ersten Fluidaustrittsweg von der oberen Seite (27)
zur ersten Bodenfläche (233) einzurichten, und
- der Schaft (13) und die zentrale Bohrung (34) so bemessen sind, dass zwischen der
zweiten Umfangsfläche (341) und der zweiten äußeren Umfangsfläche (131) ein zweiter
Radialspalt (G2) eingerichtet ist, um einen zweiten Fluidaustrittsweg von der unteren
Seite (41) zur ersten Bodenfläche (233) einzurichten.
2. Ventilanordnung (3) nach dem vorangehenden Anspruch, wobei die erste Bodenfläche (233)
und die zweite Bodenfläche (243) koplanar sind und einen ringförmigen Überlappungsbereich
(32) aufweisen, der sich insbesondere von der inneren Umfangsfläche (341) zur ersten
äußeren Umfangsfläche (241) erstreckt.
3. Ventilanordnung (3) nach einem der vorangehenden Ansprüche, ferner umfassend eine
Ankerrückstellfeder (38), die vorgespannt ist und die erste Bodenfläche (233) in formschlüssigen
Kontakt mit der zweiten Bodenfläche (243) spannt.
4. Ventilanordnung (3) nach einem der vorangehenden Ansprüche, wobei eine obere Seite
(29) des Halteelements (24) koplanar mit einer oberen Seite (27) des Ankers (23) ist.
5. Ventilanordnung (3) nach einem der vorangehenden Ansprüche, wobei die axiale Erstreckung
(L2) der zweiten Umfangsfläche (341) zumindest doppelt so groß wie die axiale Erstreckung
(L1) der ersten Umfangsfläche (231) ist.
6. Ventilanordnung (3) nach einem der vorangehenden Ansprüche, ferner umfassend
- einen Ventilkörper (4), der einen Hohlraum (9) mit einem Fluideinlassabschnitt (5)
und einem Fluidauslassabschnitt (7) umfasst, wobei die Ventilnadel (11) im Hohlraum
(9) aufgenommen ist, wobei die Ventilnadel (11) in einer Schließposition einen Fluidstrom
durch den Fluidauslassabschnitt (7) verhindert und zum Freigeben des Fluidstroms durch
den Fluidauslassabschnitt (7) axial relativ zum Ventilkörper (4) weg von der Schließposition
verschiebbar ist.
7. Ventilanordnung (3) nach dem vorangehenden Anspruch, wobei die Ankerrückstellfeder
(38) an ihren gegenüberliegenden axialen Enden gegen den Anker (23) bzw. gegen eine
Stufe (8) des Ventilkörpers (4) sitzt und wobei ohne die Ankerrückstellfeder (38)
die axiale Verschiebbarkeit des Ankers (23) in Bezug auf den Ventilkörper (4) und
die Ventilnadel (11) in der Richtung weg vom Halteelement (24) durch die Stufe (8)
begrenzt ist.
8. Ventilanordnung (3) nach einem der vorangehenden Ansprüche 6 und 7,
wobei der Anker (23) Folgendes umfasst:
- zumindest eine Führungsfläche (36) an einer Außenfläche (35) des Ankers (23), wobei
die Führungsfläche (36) mit einer inneren Fläche (37) des Ventilkörpers (4) zusammenwirkt,
um die axiale Bewegung des Ankers (23) zu führen, und
- mehrere Strömungskanäle (39), die in der Außenfläche (35) des Ankers (23) ausgebildet
sind.
9. Ventilanordnung (3) nach dem vorangehenden Anspruch, umfassend mehrere Führungsflächen
(36), wobei die Außenfläche (35) eine äußere Umfangsfläche des Ankers (23) ist, die
mehrere Abschnitte, die die Führungsflächen (36) darstellen, und mehrere Abschnitte,
die die Strömungskanäle (39) darstellten, aufweist, wobei die Führungsflächen (36)
in Umfangsrichtung durch die Strömungskanäle (39) voneinander getrennt sind.
10. Ventilanordnung (3) nach einem der vorangehenden Ansprüche 8 und 9,
wobei die in der Außenfläche (35) bereitgestellten Strömungskanäle (39) Abschnitte
mit abgeflachter Oberfläche sind, die sich in axialer Richtung von der oberen Seite
(27) des Ankers (23) zu einer unteren Seite (41) des Ankers (23) erstrecken.
11. Ventilanordnung (3) nach einem der vorangehenden Ansprüche 8 bis 10,
wobei an zumindest einer Führungsfläche (36) an der Außenfläche (35) des Ankers (23)
eine Gleitbeschichtung bereitgestellt ist.
12. Ventilanordnung (3) nach einem der vorangehenden Ansprüche, wobei der Anker (23) massiv
ist und keine Brennstoffkanäle im Inneren umfasst.
13. Ventilanordnung (3) nach einem der vorangehenden Ansprüche, ferner umfassend eine
Kalibrierungsfeder (18), die die Ventilnadel (11) zur Schließposition hin spannt.
14. Fluidinjektionsventil (1) mit einer Ventilanordnung (3) nach einem der vorangehenden
Ansprüche.
1. Ensemble de soupape (3) pour une soupape d'injection de fluide (1), comprenant une
aiguille de soupape (11) et une armature (23) d'un ensemble actionneur électromagnétique
(19),
l'armature (23) étant déplaçable axialement par rapport à l'aiguille de soupape (11)
le long d'un axe longitudinal (L),
l'armature (23) comprenant un évidement (33) au niveau d'un côté supérieur (27), l'évidement
(33) ayant une première surface circonférentielle (231) et une première surface inférieure
(233), et une seconde surface circonférentielle (341) définissant un alésage central
(34) qui s'étend de la première surface inférieure (233) à un côté inférieur (41)
de l'armature (23), opposé au côté supérieur (27),
l'aiguille de soupape (11) comprenant un élément de retenue (24) fixé à un arbre (13)
de l'aiguille de soupape (11), l'élément de retenue (24) ayant une première surface
circonférentielle externe (241) et une seconde surface inférieure (243) et l'arbre
ayant une seconde surface circonférentielle externe (131),
au moins une partie de l'élément de retenue (24) étant disposée dans l'évidement (33)
de sorte que la première surface inférieure (233) s'oppose à la seconde surface inférieure
(243) et que l'arbre (13) s'étende à travers l'alésage central (34),
l'évidement (33) et l'élément de retenue (24) étant dimensionnés de sorte qu'un premier
espace radial (G1) soit établi entre la première surface circonférentielle (231) et
la première surface circonférentielle externe (241) pour établir un premier trajet
de fuite de fluide du côté supérieur (27) vers la première surface inférieure (233),
et
l'arbre (13) et l'alésage central (34) étant dimensionnés de sorte qu'un second espace
radial (G2) soit établi entre la seconde surface circonférentielle (341) et la seconde
surface circonférentielle externe (131) pour établir un second trajet de fuite de
fluide du côté inférieur (41) vers la première surface inférieure (233).
2. Ensemble de soupape (3) selon la revendication précédente, la première surface inférieure
(233) et la seconde surface inférieure (243) étant coplanaires et ayant une zone de
chevauchement annulaire (32) s'étendant en particulier de la surface circonférentielle
interne (341) vers la première surface circonférentielle externe (241).
3. Ensemble de soupape (3) selon l'une des revendications précédentes, comprenant en
outre un ressort de rappel d'armature (38) qui est préchargé et sollicite la première
surface inférieure (233) en contact ajusté avec la seconde surface inférieure (243).
4. Ensemble de soupape (3) selon l'une des revendications précédentes, un côté supérieur
(29) de l'élément de retenue (24) étant coplanaire avec un côté supérieur (27) de
l'armature (23).
5. Ensemble de soupape (3) selon l'une des revendications précédentes, l'extension axiale
(L2) de la seconde surface circonférentielle (341) étant au moins deux fois plus grande
que l'extension axiale (L1) de la première surface circonférentielle (231).
6. Ensemble de soupape (3) selon l'une des revendications précédentes, comprenant en
outre
un corps de soupape (4) comprenant une cavité (9) avec une partie d'entrée de fluide
(5) et une partie de sortie de fluide (7), l'aiguille de soupape (11) étant reçue
dans la cavité (9), l'aiguille de soupape (11) empêchant un écoulement de fluide à
travers la partie de sortie de fluide (7) dans une position fermée et déplaçable axialement
par rapport au corps de soupape (4) à l'opposé de la position de fermeture pour libérer
l'écoulement de fluide à travers la partie de sortie de fluide (7).
7. Ensemble de soupape (3) selon la revendication précédente, le ressort de rappel d'armature
(38) étant placé contre l'armature (23) et contre une marche (8) du corps de soupape
(4) au niveau de ses extrémités axiales opposées et, sans le ressort de rappel d'armature
(38), le déplacement axial de l'armature (23) par rapport au corps de soupape (4)
et à l'aiguille de soupape (11) dans la direction opposée à l'élément de retenue (24)
étant limité par ladite marche (8).
8. Ensemble de soupape (3) selon l'une des revendications précédentes 6 et 7,
l'armature (23) comprenant
au moins une surface de guidage (36) sur une surface extérieure (35) de l'armature
(23), la surface de guidage (36) interagissant avec une surface intérieure (37) du
corps de soupape (4) pour guider le mouvement axial de l'armature (23) et
une pluralité de passages d'écoulement (39) formés dans la surface extérieure (35)
de l'armature (23).
9. Ensemble de soupape (3) selon la revendication précédente comprenant une pluralité
de surfaces de guidage (36), la surface extérieure (35) étant une surface circonférentielle
externe de l'armature (23) ayant une pluralité de sections représentant les surfaces
de guidage (36) et une pluralité d'autres sections représentant les passages d'écoulement
(39), les surfaces de guidage (36) étant séparées les unes des autres dans la direction
circonférentielle par les passages d'écoulement (39).
10. Ensemble de soupape (3) selon l'une des revendications précédentes 8 et 9,
les passages d'écoulement (39) pratiqués dans la surface extérieure (35) étant des
sections de surface aplaties s'étendant dans la direction axiale du côté supérieur
(27) de l'armature (23) vers un côté inférieur (41) de l'armature (23).
11. Ensemble de soupape (3) selon l'une des revendications précédentes 8 à 10,
un revêtement anti-frottement étant disposé sur l'au moins une surface de guidage
(36) sur la surface extérieure (35) de l'armature (23).
12. Ensemble de soupape (3) selon l'une des revendications précédentes,
l'armature (23) étant solide et ne comprenant pas de passage à carburant à l'intérieur.
13. Ensemble de soupape (3) selon l'une des revendications précédentes,
comprenant en outre un ressort d'étalonnage (18) sollicitant l'aiguille de soupape
(11) vers la position de fermeture.
14. Soupape d'injection de fluide (1) avec un ensemble de soupape (3) selon l'une des
revendications précédentes.