DE19543994A1 - Fuel injection valve for internal combustion engines - Google Patents

Abstract

In a fuel injection valve a valve member 1 has, at its outlet end a sealing face 13 which cooperates with a valve seat 15, force which biases the valve member 1 in the closing direction the opening stroke movement of the valve member (1), having two stages. This two-stage opening stroke movement of the valve member (1) is controlled by means of a single valve spring 51 and a sleeve 31 which is made to act on the valve member 1 during part of the opening stroke movement by the pressure of fuel in chamber 29. The valve may open in the direction of fuel flow (Fig 1) or in the contrary direction (Fig 2).

Description

State of the art

The invention relates to a fuel injection valve for Internal combustion engines according to the preamble of claim 1 out. In such a from DE-Gbm. 94 07 079 known fuel injector is a valve member guided axially in a valve bore of a valve body, the one with its free end in the combustion chamber of the supplying internal combustion engine protrudes. This points Valve member at its end on the combustion chamber side Valve sealing surface with which it is used for control purposes an injection cross section with one on the valve body provided valve seat interacts. The valve member will with a restoring force when the injector is closed held in contact with the valve seat during the Opening stroke of the valve member through the opening direction overcome high pressure fuel acting on the valve member becomes.

For an optimal injection course shaping is the Opening stroke movement of the valve member in the known Fuel injector divided into two stroke phases, whereby the valve member first goes through a first partial stroke, which initially has a smaller opening cross-section is turned on so that at the beginning of the injection only a small amount of pre-injection into the combustion chamber  Comes to the internal combustion engine. With the further increase in pressure on Injector becomes second after a short pause in stroke Drive through the partial stroke, during which the maximum Opening cross-section is released, so that now the Main injection quantity gets into the combustion chamber.

The two-stage opening stroke movement of the Valve member on the known fuel injector two valve springs arranged axially one behind the other shaped, of which a spring only after passing through a Vorhubweges acts on the valve member.

The known use of two valve springs for molding has the two-stage opening stroke movement of the valve member however, the disadvantage that a large space is required becomes and the piston-shaped valve member extremely long must be trained, which is a high manufacturing cost in terms of accuracy and strength on Valve member results.

Advantages of the invention

The fuel injector according to the invention for Internal combustion engines with the characteristic features of the Compared to claim 1 has the advantage that just a valve spring to form the two-stage Opening stroke movement of the valve member is required so that the required installation space on the injection valve and the Significantly reduce the necessary length of the valve member to let.

This is advantageously provided by the provision one actuated by the high pressure fuel Actuator possible that only during part of the entire opening stroke movement acts on the valve member and so in addition to the constantly acting spring force Opening stroke forms.

This adjusting element is structurally simpler Way through a displaceable sleeve on the valve member  formed, one ring end face directly to that of High pressure fuel pressure in the pressure chamber in the valve body borders and the end facing away from the pressure chamber with interacts at least one fixed stop. In addition a stop surface is provided on the sleeve, on which the Valve member bears at least over a partial stroke range. The fuel injection valve can alternatively as after outward opening injection valve or as inward opening injection valve, the Stop surfaces of the sleeve on the respective designs of the injector are adjusted. It is also there alternatively, the restoring force is possible via the additional Force application surfaces on the sleeve in a two-stage convert acting force, or with constant Restoring force the force application surfaces in Vary opening direction.

Further advantages and advantageous configurations of the The invention relates to the description of Drawing and the claims can be removed.

drawing

Two embodiments of the invention Fuel injection valves for internal combustion engines are in of the drawing and are shown in the following Description explained in more detail.

They show: Fig. 1 shows a first embodiment in longitudinal section, wherein said injection valve is an outwardly opening valve member, FIG. 1A is a section through the semi-sided extension of the sleeve, and Figs. 2 to 4, a second embodiment with opening inwardly valve member in two views and an enlarged detail view.

Description of the embodiments

In the first exemplary embodiment shown in FIG. 1, a piston-shaped valve member 1 is guided in an axially displaceable manner in a valve bore 3 of a valve body 5 . The valve body 5 projects with its free end into a combustion chamber (not shown) of the internal combustion engine to be supplied and is axially clamped against a holding body 9 at its end facing away from the combustion chamber by means of a clamping nut 7 . At its end on the combustion chamber side, the valve member 1 has a head part 11 protruding from the valve bore 3 , the annular end face facing the valve body 5 of which forms a valve sealing surface 13 , which cooperates with an annular valve seat surface 15 formed on the end surface of the valve body 5 on the combustion chamber side and surrounding the valve bore 3 . In addition, a spray hole sleeve 17 is pushed onto the valve member 1 , which is held in axial contact with the head part 11 by means of a compression spring 19 and in which an inlet opening 21 and one or more annularly arranged injection openings 23 are provided in the region near the head part, so that the injection valve 23 is arranged in the Valve bore 3 of the fuel present can flow into a space formed between the spray hole sleeve 17 and the valve member shaft and can pass into the combustion chamber when the injection openings 23 emerge from the overlap with the valve body 5 . The compression spring 19 is supported on the other hand on a support ring 25 arranged on the valve member stem, preferably shrunk on.

For the supply of the conveyed from an unillustrated high-pressure pump fuel to the injection opening 23 a of the holder body 9 and the valve body 5 is penetrating pressure passage 27 is provided, the forming in the region of a pressure chamber 29 cross-sectional enlargement of the valve bore opens out into this third The valve bore section adjoining the pressure chamber 29 on the side remote from the valve seat is designed as a guide bore in which an axially movable sleeve 31 is guided, which on the other hand is slidably guided on the valve member 1 . This sleeve borders with its lower annular end face 33 on the pressure chamber 29 and has at its end facing away from the pressure chamber 29 a stop disk 35 which is formed from two half-shells and whose outer diameter is enlarged compared to the sleeve part guided in the valve bore 3 . The stop disc 35 is displaceable between two fixed stops, a bore shoulder of the valve bore 3 forming a first lower stop 37 , as seen against the direction of movement of the valve member 1 , and a pressure disc 39 with its lower end face forming a second upper stop 41 . The adjustment path between the stops 37 , 41 is adjustable via a spacer ring 43 which is clamped radially around the stop disc 35 between the stops 37 , 41 .

In the area of the thrust washer 39 , the valve member 1 has a collar 45 , the lower ring end face of which faces the pressure chamber 29 forms a valve member abutment surface 47 which interacts with the upper end face 49 of the abutment disk 35 .

In order to prevent the sleeve 31 from slipping into the pressure chamber 29 in the depressurized state, the sleeve 31 , as also shown in FIG. 1A, has a half-sided extension 55 which axially adjoins the lower end face 33 and which is free End cooperates with the support ring 25 . The length of this half-sided extension 55 is designed such that the remaining play to the support ring 25 is greater than the stroke h1 between the collar 45 and the end face 49 . Alternative ways of preventing the sleeve 31 from slipping into the pressure chamber 29 when the valve is depressurized are e.g. B. the provision of a snap ring on the valve member shaft or a surrounding the valve member 1 , acting as a spacer sleeve slotted sheet metal sleeve.

In order to keep the valve member 1 in contact with the valve seat 15 , a valve spring 51 is also provided, which is supported on the upper annular end face of the thrust washer 39 and engages the valve member 1 via a spring plate 53 in such a way that it is pressed against the valve seat 15 .

The first exemplary embodiment of the fuel injection valve according to the invention described in FIG. 1 operates in the following manner.

At the beginning of the injection process, the fuel valve is acted upon by the high-pressure fuel pump via the injection line with fuel under high pressure. This high fuel pressure continues via the pressure channel 27 into the pressure chamber 29 and within the valve bore 3 up to the head part 11 . When a certain opening pressure is reached, the fuel acting on the valve member 1 in the opening direction moves the valve member 1 outward against the restoring force of the valve spring 51 , so that the valve member 1 lifts off with its valve sealing surface 13 from the valve seat 15 . The injection takes place from the point in time when the preferably slot-shaped injection openings 23 emerge from the overlap with the valve body 5 . This first opening stroke phase of the valve member 1 takes place only against the restoring force of the valve spring 51 .

After passing through a certain preliminary stroke path h1, the valve member 1 with the collar 45 comes into contact with the upper end face 49 of the stop disc 35 of the sleeve 31 . At this time, the sleeve 31 is held in contact with the upper stop 41 by the high-pressure fuel acting on the lower end face 33 with the end face 49 of the stop disk 35 . With the valve member collar 45 bearing against the stop disk 35 of the sleeve 31, the opening stroke movement of the valve member 1 acts in addition to the restoring force of the valve spring 51 and now also the hydraulic restoring force of the sleeve 31 , so that the valve member 1 initially remains in its opening stroke movement and only a small part of the Injection opening cross sections released. With further increasing fuel pressure, however, the opening force acting on the valve member 1 in the opening direction is sufficient to overcome the restoring force of the spring 51 and the sleeve 31 and the valve member 1 goes through the second opening stroke phase in the course of which the maximum injection cross section is opened, so that the total fuel injection quantity in reaches the combustion chamber of the internal combustion engine, the maximum opening stroke of the valve member 1 being limited by the contact of the lower end face 50 of the contact disk 35 with the lower stop 37 . The time and course of the two-stage opening stroke movement can be adjusted by coordinating the valve spring force and the effective area of the lower sleeve end face 33 .

The end of the injection takes place in known manner by the completion of the high-pressure fuel supply to the injector, the high fuel pressure is reduced in consequence of the valve member 1 and the valve member 1 is moved by the valve spring 51 again into abutment with the valve seat 15 °.

The second exemplary embodiment of the fuel injection valve according to the invention shown in different views in FIGS. 2 to 4 is based on the inwardly opening type.

The valve member 1 guided in the valve bore 3 has , at its end facing the combustion chamber of the internal combustion engine to be supplied, a conical valve sealing surface 61 formed by a reduction in cross section, with which it interacts with a conical valve seat surface 63 formed by a reduction in cross section at the end of the valve bore 3 on the combustion chamber side. In the second exemplary embodiment, the valve bore 3 is designed as a blind bore, from the closed end of which adjoins the conical valve seat 63, two injection openings 21 lead away, which are designed as injection bores. As in the first exemplary embodiment, the fuel is supplied to the valve seat 63 via a pressure channel 27 which opens into a pressure chamber 29 surrounding the valve member 1 and which is connected to a high-pressure fuel pump via an injection line (not shown).

Adjacent to the side of the pressure chamber 29 facing away from the valve seat 63 is a sleeve 31 which, analogously to the first exemplary embodiment, is axially movably guided between the stem of the valve member 1 and the wall of the valve bore 3 and whose lower end face 33 adjoining the pressure chamber 29 is a contact surface for forms the high fuel pressure. In order to prevent the sleeve 31 from sliding into the pressure chamber 29 when there is no pressure, a locking ring 83 is provided on the valve member shaft. Alternatively, however, a half-sided extension of the sleeve 31 or a slotted sheet metal sleeve acting as a spacer sleeve can also be provided on the valve member 1 , which can be supported on a lower bore shoulder of the valve bore 3 .

At its end facing away from the pressure chamber 29 , the sleeve 31 has two diametrically opposed longitudinal slots 67 , in which a collar of the valve member 1, designed as a profile 69 with two smooth side surfaces, is guided in an axially sliding manner. The axial end faces of the longitudinal slots 67 form a stop face 71 for the valve member profile 69 in the direction of the valve seat face 63 , against which a lower end face 81 of the profile 69 comes to rest. An intermediate disk 73 axially adjoining the valve body 5 forms with its end face 75 a further stop face against which the upper ring end face 77 of the sleeve 31 and the upper face 79 of the valve member profile 69 come to rest after passing through a certain stroke path.

The restoring force holding the valve member 1 in contact with the conical valve seat 63 is in turn formed by a valve spring 51 which is supported in a stationary manner and which acts on the valve member 1 via a spring plate 53 in the direction of the valve seat 63 .

The embodiment shown in FIG. 2 works in the following way.

At the beginning of the high-pressure injection, fuel under high pressure passes from the high-pressure fuel pump into the pressure chamber 29 via the pressure channel 27 and continues through the gap between the valve member 1 and the valve bore 3 to the conical valve seat 63 . The high-pressure fuel acts on the free lower ring end face 33 of the sleeve 31 and further over the lower end face 81 of the profile 69 and part of the conical sealing surface 61 in the opening direction on the valve member 1 and, after exceeding a certain opening pressure, displaces it against the force of the valve spring 51 from the valve seat 63 , so that an opening cross-section is opened at the valve seat 63 , via which the fuel flows to the injection openings 21 and further into the combustion chamber of the internal combustion engine. This first partial opening stroke movement h1 of the valve member 1 is terminated by the abutment of the upper annular end face 77 of the sleeve 31 on the end face 75 of the intermediate disk 73 , from which point the sleeve 31 no longer influences the opening stroke movement of the valve member 1 .

The opening stroke movement of the valve member 1 is continued after a brief persistence of the valve member 1 in this position, the entire cross section of the valve member 1 now acting as a force introduction surface for the high fuel pressure in the opening direction during this second main injection phase, so that the restoring force of the valve spring 51 is overcome and the remaining stroke is traversed until the upper end face 79 of the valve member profile 69 abuts on the intermediate disk 73 , the maximum total stroke movement hG being limited by the contact of the profile 69 on the end face 75 of the intermediate disk 73 .

As in the first exemplary embodiment, the closing stroke movement of the valve member 1 takes place by the lowering of the high fuel pressure in the valve bore 3 , as a result of which the valve spring 51 displaces the valve member 1 against the remaining hydraulic residual force in contact with the valve seat 63 .

Claims (9)

1. Fuel injection valve for internal combustion engines with a valve body ( 5 ), in which a valve bore ( 3 ) is provided, in which a valve member ( 1 ) is axially displaceable, which has a valve sealing surface ( 13 , 61 ) at its end facing the combustion chamber of the internal combustion engine. with which it cooperates to control an injection cross section with a valve seat ( 15 , 63 ) on the valve body ( 5 ) and with a restoring force acting on the valve member ( 1 ) in the closing direction towards the valve seat, the opening stroke movement of the valve member ( 1 ) countering the restoring force is designed in two stages, characterized in that the two-stage opening stroke movement of the valve member ( 1 ) by means of a single valve spring ( 51 ) acting on the valve member ( 1 ) in the closing direction and a valve spring ( 51 ) which acts on the valve member ( 1 ) during a partial stroke and is acted upon by the high fuel pressure and an additional force a is formed on the valve member ( 1 ) transmitting adjusting member. 2. Fuel injection valve according to claim 1, characterized in that the adjusting member is formed by an axially displaceable, between the valve member ( 1 ) and the valve bore ( 3 ) arranged sleeve ( 31 ) which with one end ( 33 ) to one of the valve member ( 1 ) adjacent pressure chamber ( 29 ) and whose end facing away from the pressure chamber ( 29 ) cooperates with at least one stationary stop, wherein on the sleeve ( 31 ) a stop surface ( 49 , 71 ) is provided, on which the valve member ( 1 ) during of a partial stroke range. 3. Fuel injection valve according to claim 2, characterized in that the valve member at its combustion chamber end has a projecting from the valve bore ( 3 ) head part ( 11 ), the valve body ( 5 ) facing the annular end face forms the valve sealing surface ( 13 ) with a the end face of the valve body ( 5 ) formed on the combustion chamber side and which surrounds the valve bore ( 3 ) and surrounds the annular valve seat surface ( 15 ). 4. Fuel injection valve according to claim 3, characterized in that the sleeve ( 31 ) at its end facing away from the pressure chamber ( 29 ) has an enlarged diameter stop disk ( 35 ) which is axially displaceable between two fixed stops ( 37 , 41 ) and on whose end face ( 49 ) facing away from the pressure chamber ( 29 ), the valve member ( 1 ) comes into contact with a collar ( 45 ) after passing through a certain preliminary stroke. 5. Fuel injection valve according to claim 4, characterized in that the maximum opening stroke movement of the valve member ( 1 ) by the abutment on the pressure chamber ( 29 ) facing the annular end face ( 50 ) of the stop disc ( 35 ) formed stop face on a stationary stop ( 37 ) is. 6. Fuel injection valve according to claim 2, characterized in that the valve sealing surface ( 61 ) is provided on a conical cross-sectional reduction on the combustion chamber end of the valve member ( 1 ) and the valve seat surface ( 63 ) on a conical diameter reduction of the combustion chamber end of the valve member bore ( 3 ) which connects at least one injection opening ( 23 ) downstream in the injection direction. 7. Fuel injection valve according to claim 6, characterized in that the sleeve ( 31 ) with its end face ( 77 ) facing away from the pressure chamber ( 29 ) can be brought into contact with a stationary stop ( 75 ). 8. Fuel injection valve according to claim 7, characterized in that the pressure chamber ( 29 ) facing away from the end of the sleeve ( 31 ) has two diametrically opposite longitudinal slots ( 67 ) in which a corresponding cross-sectional profile ( 69 ) of the valve member ( 1 ) slidably is guided, the axial ends of the longitudinal slots ( 67 ) forming a stop surface ( 71 ) for the valve member profile ( 69 ). 9. Fuel injection valve according to claim 8, characterized in that the end face ( 79 ) of the profile ( 69 ) facing away from the pressure chamber ( 29 ) on the valve member ( 1 ) comes into contact with the fixed stop ( 75 ) after passing through a total opening stroke path (hG).