DE102015217513A1 - Valve for metering a fluid - Google Patents

Abstract

A valve (1) for metering a fluid, which serves in particular as a fuel injection valve for internal combustion engines, comprises an electromagnetic actuator (2) which is arranged in a housing (6), and a valve needle (8) which can be actuated by the actuator (2), which serves to actuate a valve closing body (9). The valve closing body (9) cooperates with a valve seat surface (10) to form a sealing seat. The armature (4) is movably guided on the valve needle (8). In this case, stops (13, 14, 19) are provided, which in connection with an actuation of the valve needle (8) a relative movement between the armature (4) and the housing (6) and / or a relative movement between the armature (4) and the Limit valve needle (8). The armature (4) has cavities (20, 21) which are partially filled with granules (28, 29) movable in their respective cavity (20, 21).

Description

State of the art

The invention relates to a valve for metering a fluid, in particular a fuel injection valve for internal combustion engines. Specifically, the invention relates to the field of injectors for fuel injection systems of motor vehicles, in which there is preferably a direct injection of fuel into combustion chambers of an internal combustion engine.

From the DE 103 60 330 A1 a fuel injector is known which is used for fuel injection systems of internal combustion engines. The known fuel injection valve comprises a valve needle which cooperates with a valve seat surface to a sealing seat, and an armature connected to the valve needle, which is acted upon by a return spring in a closing direction and cooperates with a magnetic coil. The armature is disposed in a recess of an outer pole of the magnetic circuit and has a circumferentially formed on it collar with a triangular cross-section. Due to the shape of the collar, a direction-dependent hydraulic damping of the armature is possible, which dampens the opening movement, while the closing movement is almost undamped, whereby the fuel injection valve can be quickly closed.

Disclosure of the invention

The valve according to the invention with the features of claim 1 has the advantage that an improved design and operation are possible. In particular, in an embodiment with an armature free passage, an improved multiple injection capability with short dead times can be achieved.

The measures listed in the dependent claims advantageous refinements of the specified in claim 1 valve are possible.

In the valve for metering the fluid, the armature (armature) is not fixedly connected to the valve needle, but instead is cantilevered between stoppers. Such stops can be realized by stop sleeves and / or stop rings. About at least one spring, the armature is adjusted in the idle state with respect to the valve needle fixed stop, so that the armature rests there. When the valve is actuated, the complete armature free travel is then available as an acceleration section.

This results in relation to a fixed connection of the armature with the valve needle or a one-piece needle, inter alia, the advantages that the valve needle can be safely opened even at higher pressures, in particular fuel pressures by the resulting pulse of the armature when opening the same magnetic force, which as dynamic mechanical reinforcement can be designated, and that a decoupling of the involved masses takes place, whereby the resulting impact forces on the valve seat surface are divided into two pulses.

However, there are specific problems associated with the flying mounting of the armature on the valve needle. When closing the valve bounces the anchor after hitting the valve closing body close stop back again. As a result, it may happen that the complete anchor free passage is run through again and the anchor when re-striking the valve closing body far stop yet has so much energy that the valve needle is briefly lifted again from its seat. This can lead to unwanted post-injection, resulting in increased pollutant emissions and increased consumption. But even if the anchor does not go through the complete Ankerfreiweg when bouncing back, it takes some time until it calms down again. If a renewed activation takes place before the final reassurance, which is relevant in the case of multiple injections with short intervals between several injections, then there is no longer a robust valve function. It may therefore be that the stop pulses increase or decrease correspondingly and that in the worst case the valve does not open at all, since the stop pulse for this is no longer sufficiently large.

Due to the special design of the anchor according to the proposed design of the valve can be achieved in an advantageous manner that an anchor bounce is prevented or at least substantially reduced. As a result, such specific problems as mentioned above can be solved. Among other things, a more robust multiple injection capability can be achieved with short break times. In addition, lower impact pulses can be achieved when closing, which reduces wear on the armature and the attacks and on the sealing seat. This also results in lower functional changes over the life of the valve. Furthermore, this also achieves a noise reduction. Thus, it can be achieved in an advantageous manner that reduces a rebound height of the armature upon closing of the valve after hitting the relevant stop and the anchor quickly gets back to its rest position. Similarly, the operability with respect to other stops can be improved. An open-valve bounce avoidance improves this, for example Injection behavior, since the opening is controlled and reproducible, and the closing movement, since in this case then the control signal is decisive and no superposition takes place by bouncing movements.

The valve closing body, which is actuated by the valve needle, may be formed integrally with the valve needle. The valve closing body can be designed as a spherical valve closing body or in other ways.

The embodiment according to claim 2 has the advantage that after the bouncing of the armature against a stop, the movable, solid material can move largely unhindered for a short distance in accordance with its movement pulse. If during this period, a rebound of the anchor occurs, then this is damped by the delayed impact in the cavity solid. The substance is here preferably filled in bulk as granules in the cavity. The gas in the cavity in this case allows a largely unhindered movement of the solid material.

The embodiment according to claim 3, however, has the advantage that said, due to the momentum of the substance still occurring movement when the anchor is already impacted, in turn, is itself damped. Because by filling the cavity with a liquid substance, the movement of the solid material, which is preferably present in the form of a granulate, is damped. On the choice of the viscosity of the liquid substance in this case a vote is possible.

The development according to claim 4 has the advantage that, depending on the proportion of the magnetic or ferromagnetic granules and the proportion of non-magnetic granules further tuning of the behavior of the armature when opening and closing the valve is possible.

A possible development according to claim 5 allows a vote by preferably several cavities in a suitable manner separately or mixed with magnetic or ferromagnetic substances and non-magnetic substances are partially filled.

Due to the development according to claim 6, an advantageous embodiment with respect to the closure of the cavity of the actuator is possible. When using the spring retainer cage of the spring retainer cage not only the inclusion of a suitable spring, in particular Ankerfreiweg spring, but at the same time the function of the closure of the one or more cavities are taken.

In the development according to claim 7, both a sufficient cavity volume for the bounce avoidance as well as a suitable spatial and thus in particular symmetrical configuration can be achieved via a suitable embodiment of the one or more cavities.

The embodiment according to claim 8 has the advantage that thus impairments due to connection points or the like on a lateral surface of the armature can be avoided so that a fluid possibly passing there is not impaired with respect to its flow behavior. Furthermore, the initially open at the cavities front side of the armature can be closed in this embodiment in an advantageous manner by a cover plate or a tab of a spring retainer cage, as proposed according to claim 6.

Advantageous embodiments and concretizations of a stop on which a damping of the rebound can take place are mentioned in claims 9 and 10.

Specifically, therefore, a configuration can be realized in which anchor has cavities that are not completely filled with granules. Due to the inertia of the granules and the existing axial clearance this applies when striking the anchor to, for example, the inner pole when opening or the impact of the anchor to a stop sleeve when closing late and thereby reduces the rebound of the anchor. This improves the stability of a characteristic of the control and unwanted Nacheinspritzen by anchor bouncing is prevented.

Brief description of the drawings

Preferred embodiments of the invention are explained in more detail in the following description with reference to the accompanying drawings, in which corresponding elements are provided with identical reference numerals. Show it:

1 a valve in an excerpt, schematic sectional view according to an embodiment of the invention, wherein two embodiments variants are shown, and

2 a schematic sequence in an actuation of the valve according to the embodiment of the invention to explain the operation, with examples successive times t ₆ to t ₁₁ are shown.

Embodiments of the invention

1 shows a valve 1 for metering a fluid in an excerptive, schematic sectional view according to an exemplary embodiment. The valve 1 especially as a fuel injector 1 be educated. A preferred application is a fuel injection system, wherein such fuel injection valves 1 as high-pressure injection valves 1 are formed and are used for direct injection of fuel into the associated combustion chambers of the internal combustion engine. In this case, liquid or gaseous fuels can be used as the fuel.

The valve 1 has an actuator 2 on, which is a magnetic coil 3 and an anchor 4 includes. By energizing the solenoid 3 becomes a magnetic circuit via an inner pole 5 the anchor 4 and an at least partially magnetically conductive housing closed. The inner pole 5 is fixed to the case 6 connected.

The valve 1 has one inside the housing 6 along an axis 7 adjustable valve needle 8th on, on which a valve closing body 9 is provided. The valve closing body 9 acts with a valve seat surface 10 to a sealing seat together. The valve closing body 9 can be spherical, semi-spherical or otherwise designed. Furthermore, the valve closing body 9 integral with the valve needle 8th be educated.

At the valve needle 8th are stop elements 11 . 12 arranged and fixed with the valve needle 8th connected. At the stop elements 11 . 12 are stops 13 . 14 for the anchor 4 educated. The anchor 4 is between the attacks 13 . 14 movable, being at the valve needle 8th is guided. In this regard, an anchor free path 15 specified. The stop elements 11 . 12 may be formed depending on the design, for example in the form of a stop ring and / or a stop sleeve.

In this embodiment, the valve needle 8th over the stop element 11 from a return spring 16 subjected to the valve closing body 9 by means of the valve needle 8th against the valve seat surface 10 acts on. This will turn the valve 1 kept closed at rest.

The following is the operation of the valve 1 also described with reference to certain times t ₀ to t ₁₁ , which are selected by way of example from a sequence and within an operation for opening and closing the valve 1 may occur. In the 1 Here, a time t _{0 is} shown, in which the valve 1 is at rest.

For actuating the valve 1 becomes the magnetic coil 3 energized, causing the anchor 4 in an opening direction 17 against the force of a first Ankerfreiweg spring 18 is pressed. The return spring 16 holds the valve needle 8th in their initial position. By the acceleration of the anchor 4 gets bounced off the stop 13 a movement impulse on the valve needle 8th transferred to the opening of the valve needle 8th leads. This takes place at a time t ₁ .

While it is between the times t ₀ and t ₁ only to accelerate the armature 4 comes is between the time t ₁ and a time t ₂ in which the anchor 4 at a stop 19 of the inner pole 5 strikes, also the valve needle 8th accelerated.

After the anchor 4 at time t ₂ at the stop 19 of the inner pole 5 is struck, puts the valve needle 8th due to their inertia their movement in the opening direction 17 continuing, due to the force of the return spring 16 a reversal of motion takes place at a time t ₃ .

Then the valve needle hits 8th in its movement against the opening direction 17 or the attack 13 the stop element 11 back on the anchor 4 , which ideally until this time t ₄ at the inner pole 5 rests.

To drain while opening the valve 1 To make it as ideal as possible is the anchor 4 suitably modified. This is indicated by the anchor 4 in this embodiment, a plurality of cavities 20 . 21 whose number and design can be adapted to the respective application. It can also be a single cavity 20 be provided. Specifically, a cavity 20 also as a ring-shaped groove 20 be educated. Also, a partial annular configuration of one or more cavities 20 . 21 can be provided. Furthermore, the cavities 20 . 21 Also be designed as a pocket-shaped depressions, as in the 1 is illustrated.

The cavities 20 . 21 are in this embodiment than from a front side 22 of the anchor 4 out in the anchor 4 extending depressions 20 . 21 designed. Additionally or alternatively, the cavities 20 . 21 corresponding recesses also from one end face 23 of the anchor 4 from the front 22 turned away, out into the anchor 4 be formed extending into it. The wells 20 . 21 extend coaxially to the axis 7 the valve needle 8th in the material of the anchor 4 ,

The cavity 20 is through one with the anchor 4 connected cover plate 24 closed, as it corresponds to a first possible embodiment. The cavity 21 is through one with the anchor 4 connected tab 25 a spring cage 26 locked. The spring cage 26 at the same time takes a second Ankerfreiweg spring 27 on.

These two preferred ways to close the cavities 20 . 21 are in the 1 both shown together, it being understood that in practice one of these options is usually selected to the cavities 20 . 21 close together. Accordingly, then preferably eliminates one of the Ankerfreiweg springs 18 . 27 ,

By the arrangement of the cavities 20 . 21 at the of the inner pole 5 distant front side 22 There is the advantage that the front side 23 for striking the stop 19 of the inner pole 5 is available.

In this embodiment, the cavity 20 partially filled with a non-magnetic granulate, loosely. Further, the cavity 21 partially filled with a magnetic or ferromagnetic granules, loosely. The remaining part of the cavities 20 . 21 may contain gas, in particular air, or in a modified embodiment also be filled with a liquid substance.

Specifically, one or more cavities may also be used 20 . 21 each with a magnetic or ferromagnetic material 29 or a non-magnetic substance 28 or a mixture of a magnetic or ferromagnetic material 29 and a non-magnetic substance 28 partially filled. As a result, a vote on the particular application is possible.

Through the granules 28 . 29 For example, at time t ₂ , where the anchor 4 at the stop 19 of the inner pole 5 impinges, a damping of a possible rebounding of the armature 4 achieved. A rebounding anchor 4 namely stopped or at least slowed down in terms of its backward movement, since the granules 28 . 29 another movement impulse in the opening direction 17 have and delay within the cavities 20 . 21 their momentum on the anchor 4 transfer. The brake pulse applied to the armature 4 allows the anchor 4 between the times t ₂ and t ₄ as possible in the desired position at the stop 19 of the inner pole 5 remains.

Accordingly, a damping when hitting the stop element 11 on the anchor 4 between the time t ₄ and a time t ₅ , at which the anchor 4 then ideally only from the inner pole 5 should be solved, be subdued. In both cases lead to high impact pulses inadequate hydraulic damping and / or insufficient magnetic force namely to an unintentional rebounding of the armature 4 from the inner pole 5 , which manifests itself in an unstable opening behavior and a wavy or strongly scattering characteristic.

The following is also with reference to the 2 the sequence when closing explained in more detail.

2 shows a schematic sequence upon actuation of the valve 1 according to the exemplary embodiment for explaining the mode of operation, examples of successive times t ₆ to t _{11 being} shown. The influence of a magnetic field of the actuator 2 on the magnetic or ferromagnetic granules 29 is here illustrated in each case on the right side, wherein the magnetic field via schematically illustrated field lines 40 is shown in a possible shape. The magnetic field 40 has in turn influence on the magnetic or ferromagnetic granules 29 , so that this at time t ₆ as close to the inner pole 5 located. The non-magnetic granules 28 on the left side, however, is subject to the influence of gravity.

From the time t ₆ , the anchor moves 4 with the valve needle 8th against the opening direction 17 until the time t _7, the valve closing body 9 the valve needle 8th on the valve seat surface 10 strikes. Due to the inertia of the anchor 4 and because of the anchor freewheel springs 18 . 27 puts the anchor 4 his way against the opening direction 17 until he stops 14 the valve closing body near stop element 12 impinges, which takes place at the time t ₈ . If it is here to bounce back the anchor 4 comes, which is exemplified at time t ₉ , then there is an attenuation on the granules 28 . 29 , Because the granules 28 . 29 continue to carry a motion impulse against the opening direction 17 and have due to the loose, partial filling in the cavities 20 . 21 still an additional movement path opposite the anchor 4 so that she delays with the anchor 4 collide, which is the case at time t ₁₀ .

At time t _10, the granules collide 28 . 29 with the anchor 4 and transmit their motion impulse partially to the anchor 4 , This will cause a further return movement of the armature 4 in the opening direction 17 prevented. Thus, the anchor gets 4 even with a rebound after a short time back to its rest position, which is the case at time t ₁₁ . Thus, the time interval between the time t ₁₁ and the time t ₈ due to the described operation is shortened and short enough to the valve 1 bring in its closed rest position before, for example, in the context of a multiple injection a re-actuation occurs.

Thus, by the inventive design of one example with granules 28 . 29 partially filled anchor 4 a rebounding movement of the anchor 4 stopped or reduced as the granules 28 . 29 late impact and thus a braking pulse on the rebounding anchor 4 exercise. This can both for the opening process as well as for the closing of the valve 1 be used. Especially during the closing process prevents the anchor 4 when rebounding, as illustrated at time t ₁₀ , to the valve closing body far stop 13 passes, there impinges and due to its momentum possibly a brief opening of the sealing seat conditionally. Furthermore, the anchor arrives 4 more quickly to rest, which corresponds to the time t ₁₁ , so that in a defined manner and reliable reopening is possible. In the context of a multiple injection shortening therefore required pause times in the control, within which the anchor 4 calm down.

Regarding the substances 28 . 29 Combinations of several materials with different properties in any mixing ratios are conceivable. Furthermore, the cavities 20 . 21 in which, for example, the granules 28 . 29 In addition, in addition, be wholly or partially filled with a liquid substance to the movement of granules 28 . 29 or the like to the anchor 4 to slow down and thus delay the time of impact.

The Ankerfreiwegfedern 18 . 27 are for ease of illustration in the 2 not shown. A possible configuration and arrangement, however, results from the 1 , In the embodiment with a spring-receiving cage 26 can circumferentially distributed suitable openings 41 for media flow into the spring retainer cage 26 be educated. About through holes 42 . 43 may be a fluid, in particular fuel or a special damping fluid, through the armature 4 be guided. By such a fluid can also be a hydraulic damping of the armature 4 be achieved. As a result, a further vote is possible.

The invention is not limited to the described embodiments.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10360330 A1 [0002]

Claims (10)

Valve ( 1 ) for metering a fluid, in particular fuel injection valve for internal combustion engines, with a housing (in 6 ) arranged electromagnetic actuator ( 2 ) and one of the actuator ( 2 ) operable valve needle ( 8th ), which is used to actuate a valve closing body ( 9 ), which is provided with a valve seat surface ( 10 ) cooperates to a sealing seat, characterized in that the armature ( 4 ) on the valve needle ( 8th ) is movably guided, that at least one stop ( 13 . 14 . 19 ) is provided, which in connection with an actuation of the valve needle ( 8th ) a relative movement between the armature ( 4 ) and the housing ( 6 ) and / or a relative movement between the armature ( 4 ) and the valve needle ( 8th ), and that the anchor ( 4 ) at least one cavity ( 20 . 21 ) with at least one in the cavity ( 20 . 21 ) movable material ( 28 . 29 ) is at least partially filled. Valve according to claim 1, characterized in that at least one cavity ( 20 . 21 ) partially with at least one in the cavity ( 20 . 21 ) movable, solid material ( 28 . 29 ) and otherwise at least substantially filled with gas. Valve according to claim 1, characterized in that the cavity ( 20 . 21 ) partially with at least one solid substance ( 28 . 29 ) and at least one liquid substance is filled or that the cavity ( 20 . 21 ) partially with at least one solid substance ( 28 . 29 ) and filled with at least one liquid substance. Valve according to one of claims 1 to 3, characterized in that the cavity ( 20 . 21 ) partly with a substance ( 29 ), in the form of a magnetic or ferromagnetic granules ( 29 ) and / or a substance ( 28 ), in the form of a non-magnetic granules ( 28 ) is formed, is filled loosely. Valve according to one of claims 1 to 4, characterized in that one or more cavities ( 20 . 21 ) each with at least one magnetic or ferromagnetic substance ( 29 ) and at least one non-magnetic substance ( 28 ) are partially filled and / or that one or more cavities ( 20 . 21 ) each with at least one magnetic or ferromagnetic substance ( 29 ), but not a non-magnetic substance ( 28 ) are partially filled and / or that one or more cavities ( 20 . 21 ) each with at least one non-magnetic ( 28 ), but no magnetic or ferromagnetic material ( 29 ) are partially filled. Valve according to one of claims 1 to 5, characterized in that the at least one cavity ( 20 . 21 ) by one with the anchor ( 4 ) connected cover plate ( 24 ) or one with the anchor ( 4 ) connected tab ( 25 ) of a spring receiving cage ( 26 ) is closed. Valve according to one of claims 1 to 6, characterized in that at least one cavity ( 20 . 21 ) of the anchor ( 4 ) as an annular or partially annular groove ( 20 . 21 ) is formed and / or that at least one cavity ( 20 . 21 ) of the anchor ( 4 ) as a pocket-shaped depression ( 20 . 21 ) is trained. Valve according to one of claims 1 to 7, characterized in that at least one cavity ( 20 . 21 ) than from one end face ( 22 . 23 ) of the anchor ( 4 ) out into the anchor ( 4 ) extending depressions ( 20 . 21 ) is configured. Valve according to one of claims 1 to 8, characterized in that a stop ( 19 ) at an inner pole ( 5 ) of the actuator ( 2 ) is formed in connection with an actuation of the valve needle ( 8th ) one in an opening direction ( 17 ) relative movement of the armature ( 4 ) relative to the housing ( 6 ) limited. Valve according to one of claims 1 to 9, characterized in that a valve closing body further stop ( 13 ) fixed to the valve needle ( 8th ) is provided, which in connection with an actuation of the valve needle ( 8th ) one in an opening direction ( 17 ) relative movement of the armature ( 4 ) relative to the valve needle ( 8th ) and / or that a valve closing body near stop ( 14 ) fixed to the valve needle ( 8th ) is provided, which in connection with an actuation of the valve needle ( 8th ) one against an opening direction ( 17 ) relative movement of the armature ( 4 ) relative to the valve needle ( 8th ) and when the valve closing body ( 9 ) on the valve seat surface ( 10 ), also relative to the housing ( 6 ) limited.

Images