The present invention relates to a fuel injection valve for the intermittent injection of fuel into the combustion space of an internal combustion engine, according to the preamble of patent claim 1, said fuel injection valve being used preferably in diesel engines.
Fuel injection valves of this type are known, for example, from WO 2005/019637 A1. Further fuel injection valves are disclosed, for example, in WO 02/053904 A1, EP 0 976 924 B1 and DE 37 00 687 A1.
WO 02/053904 A1 shows an injection valve with a piezo-electric actuator which controls an outlet of a valve space. The valve space is connected to a control space via an outlet throttle passage, and this control space is connected to a high-pressure space of the injection valve via an inlet throttle passage. By the pressure of the control space being lowered, the end face of a control piston of the injection valve member is relieved, with the result that the injection valve member can be opened and the injection of fuel can take place. To close the injection valve member at the end of injection, a further passage connected to the high-pressure space can be opened by the piezoelectric actuator, with the result that the inflow of fuel into the control space can also take place through the outlet throttle passage in addition to the inlet throttle passage. This solution is highly complicated, since in order to achieve an exact opening movement, always the same in many injection valves, of the injection valve member, which must be case in a series of structurally identical injection valves, firstly an accurate coordination of the throughflow characteristics both of the inlet and of the outlet throttle passage must be obtained. Secondly, in addition, the further passage also has to be opened in a directed manner by the piezoelectric actuator, in order to organize the closing of the injection valve member at the end of injection at least so quickly that the combustion of the engine cylinder assigned to the injection valve does not suffer too greatly from this. However, since the additional inflow to implement the closing movement of the injection valve member has to flow through the outlet throttle passage, it is throttled and the additional cross section opened by the actuator is utilized to only a slight extent.
In the injection valve disclosed in EP 0 976 924 B1, similarly to the injection valve known from WO 02/053904 A1, an inlet and an outlet throttle passage having the same function and the same disadvantages are present. This solution is preferable inasmuch as, when the valve space is being opened, the actuator valve member simultaneously closes the additional further passage. This function corresponds to that of a three-way valve and has therefore been known for a long time in hydraulics. The further passage is configured as a flat seat, whereas the outlet from the valve space is configured as a conical seat. On account of the small stroke of the valve member actuated by the piezoactuator, the conical seat presents the difficulty of obtaining identical strokes in all the injection valves of a series. Furthermore, the alignment of the valve member of mushroom-shaped type presents problems, since the flat seat is arranged in a first intermediate plate and the conical seat in a second intermediate plate of the injection valve, the valve member being guided radially in the first plate. The two intermediate plates therefore have to be positioned exactly with respect to one another, otherwise the leaktightness of at least one of the seats is prejudiced.
In the injection system known from DE 37 00 687 A1, during injection a solenoid valve, when actuated, connects a duct to a return line. Between the duct and a control space is located a nonreturn valve designed as a wafer with a throttle bore. During the opening movement of the injection valve member, the control space can be emptied into the duct solely via the throttle bore of the nonreturn valve wafer, thus leading to a controllability of the opening movement of the injection valve member. During the closing of the injection valve member, the nonreturn valve wafer opens such that the closing movement of the injection valve member can take place more quickly than the opening movement. In this injection system, too, the fuel volume flow for closing the injection valve member has to flow solely through a throttle which connects the duct to a pressure accumulator of the injection system via an annular space. This throttle has a small cross section and is coordinated with a further throttle which is located at the outlet of the duct. The opening and the closing movement of the injection valve member are consequently controlled by three throttle bores which have to be coordinated exactly with one another.
A fuel injection valve is known from WO 2005/019637 A1 and particularly from
This solution has the disadvantage that the piezoactuator has to be expanded during the operation of closing the injection valve member. In this state, current is applied to the piezoactuator. Since the injection duration amounts to only 5% or less of the duration between two injections, the piezoactuator is almost continuously under an electrical voltage. Furthermore, in this known solution, the position of the throttle bore which determines the opening movement of the injection valve member is unfavorable, since it is located far away from the control space.
The object of the present invention is to provide a fuel injection valve of particularly simple construction, in which, at minimal outlay in structural terms, both a controllability of the opening movement of the injection valve member and a rapid closing operation of the injection valve member can be achieved. Furthermore, in the fuel injection valve of the present invention, the implementation of multiple injections with a very short time interval is to be achievable without difficulty.
While a control space and a valve space are continuously connected to one another via an exact throttle passage, an intermediate valve otherwise separates these two spaces continuously from one another. The throttle passage is arranged directly adjacently to the control space. A passage connected to the high-pressure space of the injection valve and leading into the control space and having a large cross section, as compared with the cross section of the throttle passage, is controlled by the intermediate valve. Since the cross section of the outflow, controlled by an electrical actuator arrangement, from the valve space may also be substantially larger than the cross section of the throttle passage, the opening movement of the injection valve member is dependent essentially solely on the cross section of the throttle passage. During the closing of the outflow from the valve space by means of the actuator arrangement, the intermediate valve opens quickly and releases the passage of large cross section connected to the high-pressure space, thus bringing about a rapid termination of the injection operation.
In a preferred further refinement of the present invention, a flat-seat valve member acting as a 2/3-way valve is used, which can execute a specific small stroke in a second intermediate plate in the valve space. In a preferred embodiment, the flat-seat valve member has two flat seats. In the dead state of a piezoactuator advantageously used for actuating the flat-seat valve member, the flat-seat valve member, by means of a first valve seat, closes off a connection between the valve space and the low-pressure fuel return and at the same time releases a high-pressure duct which is located in a first intermediate plate and is connected to the high-pressure inlet and which has a relatively large unthrottled cross section. The throughflow cross section between the flat-seat valve member and the high-pressure inlet, that is to say the valve flat seat, is dependent on the distance, hence on the stroke, of the flat-seat valve member and mostly constitutes a narrower passage than that of the high-pressure duct.
In the live state of the piezoactuator when the latter expands, the flat-seat valve member is pressed onto the high-pressure duct and closes the valve passage by means of its valve flat seat, the low-pressure outlet at the same time being released. A second connecting duct of relatively large cross section in the first intermediate plate connects the control space to the valve space.
Terms such as “relatively large cross section” or “cross section larger than” and the like relate to the cross section of said throttle passage, and such cross sections are preferably at least twice as large, but mostly 5 or 10 times larger, or even larger, than the cross section of the throttle passage.
Particularly preferred embodiments are defined in the further patent claims.
The abovementioned and further advantages of the present invention are explained in more detail by means of preferred embodiments which are illustrated in the drawings and are described below. In the drawings, purely diagrammatically,
A high-pressure fuel inlet 20, designed as a high-pressure supply bore, of the fuel injection valve 1 is connected in a known way to a fuel feed which supplies the fuel injection valve 1 with fuel under very high pressure of, for example, up to 1800 bar or higher. The high-pressure fuel inlet 20 issues laterally into the housing body 10, but could also be manufactured, more or less parallel to the housing axis 8, from above in the housing body 10. The high-pressure fuel inlet 20 has issuing into it a longitudinal bore 22 which is likewise manufactured in the housing body 10 and which issues at the other end into the lower face 10a of the housing body 10.
Diametrically opposite the longitudinal bore 22, and on an actuator axis 8′ which is axially offset with respect to the housing axis 8, is located an actuator arrangement 24 which is preferably designed as a piezoactuator 26 and could alternatively be designed as an electromagnetic actuator.
Located in a high-pressure space 42 of the nozzle body 16 are a needle-shaped injection valve member 28, a supporting cuff 30, a washer 32, a compression spring 34 and a guide sleeve 36. The compression spring 34 is supported on the injection valve member 28 via the washer and supporting cuff 30.
A bore 38 through the second intermediate plate 14 and a bore 40 through the first intermediate plate 12 connect the longitudinal bore 22 to the high-pressure space 42. This high-pressure space 42 extends from that end face 16b of the nozzle body 16 which faces the intermediate plates 12, 14 as far as an injection valve seat 44. Downstream of the injection valve seat 44, the nozzle body has injection orifices 44′. The injection valve member 28 has a radial guide 46 with respect to the nozzle body 16, which radial guide is interrupted by ground faces 48 of the injection valve member 28 for the hydraulically virtually resistanceless supply of high-pressure fuel to the injection valve seat 44.
Located in the first and the second intermediate plate 12 and 14 is a hydraulic control device 52 for controlling the opening and rapid closing movements of the injection valve member 28 during the injection operation. The control device 52 of the fuel injection valve 1 is illustrated and described in detail in connection with
The description of the embodiments shown in
A control piston 28′ of the injection valve member 28 is mounted with a close sliding fit in the guide sleeve 36 so as to be guided radially and so as to be axially displaceable. It delimits, together with the guide sleeve 36, a control space 54, the end face 36b of which guide sleeve 36 is pressed sealingly and statically into bearing contact against a lower face 12a of the first intermediate plate 12 by the spring 34. A shank 58 of a mushroom-shaped intermediate valve member 56 standing on its head 60 engages into an axially continuous orifice of the first intermediate plate 12 and is guided on the latter with a close sliding fit 58′ The head 60 of the intermediate valve member 56 is located axially displaceably in a clearance 62 of the guide sleeve 36. The clearance 62 is permanently connected hydraulically to the control space 54 by means of radial passages 56″ in the head 60 and is therefore part of the control space 54. The head 60 is pressed against a shoulder 64 of the guide sleeve 36 by a small compression spring 66 supported on a lower face 14a of the second intermediate plate 14.
An exact throttle passage 68 of the intermediate valve member 56 connects the control space 54 permanently to a valve space 70 in the second intermediate plate 14; a recess passing through the second intermediate plate 14 and delimited by the first intermediate plate 12 and the housing body 10 forms the valve space 70. The valve space 70 is connected hydraulically to the rear side of the intermediate valve member 56 via a passage 70′; the small space in the continuous orifice of the first intermediate plate 12 on the rear side of the intermediate valve member 56 thus forms hydraulically a part of the valve space 70. According to
Located in the valve space 70 is an actuator valve member 72 which is actuated by the piezoactuator 26 and which in its closed position bears sealingly with its conical sealing face against an annular valve seat DS formed on the housing body 10. The valve seat DS is formed by the mouth of an outlet passage 73 formed in the housing body 10; this outlet passage 73 leads to the low-pressure fuel return 50. An actuator valve member spring 74 exerts on the actuator valve member 72 in the direction of the valve seat DS a spring force which is constant, but is low in comparison with the fuel pressure force.
A bore 76 of relatively large cross section in the first intermediate plate 12 connects the control space 54 to the bore 38 via a lateral passage in the second intermediate plate 14. With the intermediate valve 56′ closed, this connection is interrupted, the intermediate valve 56′, in its open position, forming a circular-cylindrical passage. The lateral passage may alternatively be manufactured in the first intermediate plate 12.
The dimensions of the abovementioned outlet passage, of the bore or of the throttle passage amount, for example, to 0.20 mm for the throttle passage 68, to 0.08 mm for the bore 76 and to 1.3 mm for the valve seat DS of the actuator valve member 72 in the case of a full opening stroke of the actuator valve member 72 of approximately 0.025 mm. The latter corresponds to an outlet throttle passage 73 conforming to a bore with a diameter of approximately 0.36 mm, all these values being merely indicative. Said values show that the sole essential control cross section, which determines the opening movement of the injection valve member 28 in the case of a full opening stroke of the actuator valve member 72, is formed by the throttle passage 68.
The fuel injection valve 1 functions as follows: when current is applied to the piezoactuator 26, the latter expands and, by means of a downward movement of the actuator valve member 72, opens the valve seat DS and therefore the outlet passage 73. This position of the actuator valve member 72 is shown in
To implement separate preinjections or post-injections with a main injection between them and with very short time intervals between the individual injections, the intermediate valve member 56, by current being applied once more to the piezoactuator 26, can be moved in the closing direction of the intermediate valve 56′ again even during the closing movement of the injection valve member 28, since the control space 54 and the distribution space 70 are virtually separated hydraulically due to the sliding fit 58. Subsequent injection can directly follow the end of the preceding injection, and the spacing between the individual separate injections can be shortened virtually to zero. Since the switchable cross section of the intermediate valve 56′ is substantially larger than that of the throttle passage 68, this control device 52 according to the invention can be used to control both small fuel injection valves 1, such as, for example, for applications in passenger car or truck engines, and much larger fuel injection valves which are employed, for example, in locomotives, earth moving machines, current generation plants and ships.
At time point t1, current is applied to the piezoactuator 26, and the actuator valve member 72 is opened, so that, at t2, the opening movement of the injection valve member 28 commences. Between t2 and t3, the injection valve member 28 opens quickly, but covers only a short distance, since the application of current to the piezoactuator 26 is cancelled and therefore the actuator valve member 72 reduces the opening stroke to an extent such that the remaining outlet passage cross section likewise acts as a throttle. The opening speed of the injection valve member is thereby held, greatly reduced, until current is applied fully to the piezoactuator again and the full speed of the opening stroke is restored, this being the situation at t4. The injection valve member 28 thereafter opens again quickly up to t5 and its opening is controlled by the throttle passage 68. It is therefore possible to implement a stepped injection profile.
The profile of EH(t) shown occurs after the time t5 when the injection valve member 28 possesses no mechanical stroke stop or it does not reach any mechanical stroke stop even during a full-load injection operation. This is therefore an alternative possibility which functions without a mechanical stroke stop. It is possible, by reducing the actuator valve member stroke once more, in a similar way to between t3 and t4, to reduce again the opening speed of the injection valve member 28, starting from the stroke EH, present at t5, which corresponds to a full opening stroke of a fuel injection valve with a mechanical stroke stop. It is thereby possible to keep the maximum value of the stroke EH prior to the commencement of the closing operation of the injection valve member 28 within limits, even when the injection operation lasts a long time. This condition occurs particularly in fuel injection valves for large diesel engines.
At time point t6, the actuator valve member 72 is in the closing position. Between the time t6 and t7, therefore, the injection valve member 28 closes and the stroke EH(t) quickly approaches zero. When current is briefly applied to the piezoactuator 26 once more before the injection valve member 28 reaches the injection valve seat 44, the impact speed of the latter on the injection valve seat 44 can be reduced to an extent such that insignificant seat stress and consequently, should this be a critical condition, a longer service life of the injection valve seat 44 are achieved. The profiles of AH(t) and EH(t) for this situation are illustrated by dashes.
The embodiment according to
The functioning of the arrangement of the intermediate valve member 56 with a conical valve seat is similar to that of
Dashed lines in
Alternatively, the intermediate element 94 and the outlet element 114 could be produced jointly in one piece. Alternatively, in a similar way to
Furthermore, the design of
In an alternative variant, not shown, the solutions of
An alternative separation point between the guide sleeve 78 and the intermediate element 94 is sketched at 94b by a dashed line. Alternatively, the intermediate element 94 and the outlet element 114 could be produced in one piece.
Located in the second intermediate plate 14 is a pill-like flat-seat valve member 120 which acts as a 2/3-way valve and which can be moved by a valve pin 122 which can be actuated, for example, by a piezoactuator. The flat-seat valve member 120 can execute a specific small stroke in the second intermediate plate 14 between the housing body 10 and the first intermediate plate 12. In a preferred embodiment, the flat-seat valve member 120 has two flat seats, since it is thus particularly simple to obtain the specific small stroke by means of the difference in thickness of the second intermediate plate 14 and in thickness of the flat-seat valve member 120. In the de-energized state of the piezoactuator 26, the flat-seat valve member closes with a first valve seat 124 the connection between the valve space 70 and the low-pressure fuel return 50 (see
The lateral passage 70′ and a centric passage bore 138 in the first intermediate plate 12 of relatively large cross section connect the valve space 70 to the throttle passage 68 in the intermediate wafer 132, which has lateral clearances 136 and is pressed by a compression spring 134 against the lower face 12a of the first intermediate plate 12. During the opening movement of the injection valve member 28, the position of the intermediate wafer 132 is as shown in
The control device 140 functions as follows: for injection, the actuator arrangement presses the flat-seat valve member 120 from its position bearing on the first valve seat 124 onto the upper face 12b of the first intermediate plate 12 by means of the valve pin 122, thus opens the first valve seat 124 to the low-pressure outlet 50 and closes the second valve seat 128 to the high-pressure duct 126. As a result, the pressure in the valve space 70 and consequently also in the control space 54 falls. The injection valve member 28 can open, and the opening movement is controlled by the throttle passage 68. When the first valve seat 124 is closed as a result of the movement of the flat-seat valve member 120 in order to terminate injection, the second valve seat 128 opens at the same time. The fuel stream passing through relatively large cross sections into the valve space 70 and into the passage bore 138 opens the intermediate wafer in that the latter is pressed away from its bearing contact against the lower face 12a. The fuel stream passes via the clearances 132 into the control space 54 and the injection operation is terminated quickly. Thus, by the multiple actuation of the actuator arrangement, multiple injections with a very short time interval can be implemented. Alternatively, the intermediate plates 12 and 14 may be produced in one piece from one workpiece.
The exact throttle passage 68 is located in the flat-seat valve member 144 and communicates via the passage bore 146 of relatively large cross section with the control space 54. In order to bridge the axial offset of the two longitudinal axes 8 and 8′, it is advantageous if the passage bore 146 is arranged obliquely in the first intermediate plate 12, as shown. As illustrated in
Here, too, the intermediate plates 12 and 14 could be combined into one workpiece.
The functioning of the control device 142 is similar to that of
In the embodiment of the fuel injection valve according to the invention, as shown in
A downwardly open blind hole-like recess in the intermediate body 150 forms with its circular-cylindrical surface area the sliding fit 58′ with the shank 58 of the mushroom-like intermediate valve member 56 and with the shank 58 delimits the valve space 70. The latter is connected, on the one hand, via a very narrow admission bore 152 to the longitudinal bore 22 connected to the high-pressure inlet and, on the other hand, via the exact throttle passage 68 in the intermediate valve member 56 to the control space 54. Further, the outlet passage 110 leads, axially offset with respect to the longitudinal axis 102, from the valve space 70 to the passage in the housing body 10 in which the actuator shank 112 is arranged and which issues into the low-pressure return 50.
Three bores 96 run through the intermediate body 150 in the radial direction outside the centric blind hole-like recess and are flow-connected on the upper side to the longitudinal bore 22 by means of an essentially V-shaped connecting groove 154. They issue on the lower side into the control space 54 and can be closed by means of the head of the intermediate valve member 56.
Starting from the V-shaped connecting groove 154, the bore 40 runs in the axial direction through the intermediate body 150 and issues on the lower side into a U-shaped distribution groove 156 in the intermediate valve body 150. This distribution groove ensures the connection to the high-pressure space 90 radially outside the guide sleeve 78. By means of the compression spring 34, the guide sleeve 78 is held with its end face 78b in leaktight bearing contact against the intermediate body 150, the guide sleeve 78 bearing against the intermediate body 150 between the U-shaped distribution groove 156 and the mouth of the bores 96. In its end region on this side, the guide sleeve 78 is designed to be widened with respect to the region of the close sliding fit with the control piston 28′ of the injection valve member 28, so that the head of the intermediate valve member 56 can be received with sufficient radial play.
Further, the intermediate body 150 has two blind hole-like positioning holes 158 into which positioning pins on the housing body 10 come into engagement.
As can be seen particularly from
In a similar way to that described further above, dashed lines in
In the state of rest, the actuator shank 112 closes the outlet passage 110, the injection valve member 28 bears against the injection valve seat 44 and the intermediate valve 56′ is open; its head bears against an inner shoulder of the guide sleeve 78. To trigger an injection operation, the actuator shank 112 is retracted, thus leading to a pressure drop in the valve space 70 because the flow cross section of the outlet passage 110 is substantially larger than the sum of the flow cross sections of the throttle passage 68 and of the admission bore 152. The result of this is that the intermediate valve 56′ closes and the pressure in the control space 54 therefore falls very quickly. The injection valve member 28 is lifted off from the injection valve seat 44 counter to the action of the compression spring 34 by the pressure drop in the control space 54. To terminate the injection operation, the outlet passage 110 is closed by means of the actuator shank 112. At least approximate pressure compensation occurs very quickly between the control space 54 and the valve space 70. Further, the high pressure prevailing in the bores 96 and, via the control piston 98′, the compression spring 34 exert an opening force on the intermediate valve member 56, thus causing a very rapid closing movement of the injection valve member 28.
In a similar way to what was described further above, multiple injections are possible.
The embodiment indicated in
In the exemplary embodiments shown the opening cross section of the outlet passage is at least twice as large as the cross section of the exact throttle passage 68.
Of course, the features of the control devices of the fuel injection valves of the present invention may also be used individually or in other combinations than those shown here.
Number | Date | Country | Kind |
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0340/06 | Mar 2006 | CH | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/CH2007/000091 | 2/22/2007 | WO | 00 | 8/27/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/098621 | 9/7/2007 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5551391 | Beck et al. | Sep 1996 | A |
5655716 | Mathis | Aug 1997 | A |
5685483 | Ganser | Nov 1997 | A |
5842640 | Ganser | Dec 1998 | A |
6293254 | Crofts et al. | Sep 2001 | B1 |
6499669 | Ganser | Dec 2002 | B2 |
20030141472 | Mattes | Jul 2003 | A1 |
20050242211 | Funai et al. | Nov 2005 | A1 |
Number | Date | Country |
---|---|---|
37 00 687 | Jul 1987 | DE |
44 06 901 | Sep 1995 | DE |
100 30 119 | Dec 2000 | DE |
102 54 750 | Jun 2004 | DE |
10 2005 020048 | Nov 2005 | DE |
0 976 924 | Feb 2000 | EP |
2185530 | Jul 1987 | GB |
02053904 | Jul 2002 | WO |
2005019637 | Mar 2005 | WO |
Entry |
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International Search Report of International Application No. PCT/CH2007/000091, mailed on Jun. 20, 2007. |
International Preliminary Examination Report (in German) of International Application No. PCT/CH2007/000091, mailed on Jun. 17, 2008. |
International Preliminary Examination Report (in English) of International Application No. PCT/CH2007/000091, mailed on Jun. 17, 2008. |
Number | Date | Country | |
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20090065614 A1 | Mar 2009 | US |