For introducing fuel into direct-injection internal combustion engines, stroke-controlled injection systems with a high-pressure reservoir (common rail) are used, as are unit fuel injector systems or pump-line-nozzle systems. In fuel injection systems with a common rail, the injection pressure can advantageously be adapted to the load and rpm of an engine over wide operating ranges. To reduce emissions and to attain a high specific performance, a high injection pressure is necessary. The attainable pressure level in high-pressure fuel pumps is limited for reasons of strength, so that to further increase the pressure in fuel injection systems, pressure amplifiers in the fuel injectors are employed.
BACKGROUND OF THE INVENTION
German Patent Disclosure DE 101 23 913 A1 has a fuel injection system for internal combustion engines with a fuel injector that can be supplied from a high-pressure fuel source as its subject. A pressure booster device having a movable pressure booster piston is connected between the fuel injector and the high-pressure fuel source. The pressure booster piston divides a chamber, which can be made to communicate with the high-pressure fuel source, from a high-pressure chamber that communicates with the fuel injector. For filling a differential pressure chamber of the pressure booster device with fuel or evacuating the differential pressure chamber of fuel, the fuel pressure in the high-pressure chamber can be varied. The fuel injector has a movable closing piston for opening and closing injection openings. The closing piston protrudes into a closing-pressure chamber, so that the closing piston can be acted upon by fuel pressure to attain a force acting in the closing direction on the closing piston. The closing-pressure chamber and the differential pressure chamber are formed by a common closing-pressure differential pressure chamber, and all the portions of the closing-pressure differential pressure chamber communicate permanently with one another from exchanging fuel. A pressure chamber is provided for supplying the injection openings with fuel and for subjecting the closing piston to a force acting in the opening direction. A high-pressure chamber communicates with the high-pressure fuel source in such a way that aside from pressure fluctuations, at least the fuel pressure of the high-pressure fuel source can be applied constantly to the high-pressure chamber; the pressure chamber and the high-pressure chamber are formed by a common injection chamber. All the portions of the injection chamber communicate permanently with one another for exchanging fuel.
From German Patent Disclosure DE 102 47 903.8 A1, a pressure-amplified fuel injection system with an internal control line can be learned. The fuel injection system, which communicates with a high-pressure source, has a multi-part injector body. In it, a pressure booster that can be actuated via a differential pressure chamber is received, and its pressure booster piston divides a work chamber from the differential pressure chamber. The fuel injection system is actuatable via a switching valve. A change in pressure in the differential pressure chamber of the pressure booster is effected via a central control line, which extends through the pressure booster piston. The central control line is passed through the work chamber of the pressure booster and is sealed off from it via a high-pressure-proof connection.
German Patent Disclosure DE 196 11 884 A1 relates to a fuel injection valve for internal combustion engines. It includes a pistonlike valve member that is axially displaceable in a bore of a valve body. This valve member, on its end toward the combustion chamber, has a valve sealing face, which to open an injection cross section cooperates with a valve seat provided on the end of the bore toward the combustion chamber. Moreover, the valve member has a pressure shoulder, pointing in the direction of the valve sealing face, by means of which shoulder the valve member is subdivided into a larger-diameter guide part guided slidingly in the bore and a smaller-diameter free shaft part. A pressure chamber formed by a cross-sectional expansion of the bore is provided, which communicates with the valve seat via a gap formed between the free shaft of the valve member and the wall of the bore and which is adjoined, on the end facing away from the valve seat, by a guide portion of the bore that receives the guide part of the valve member. The valve body is penetrated by a pressure conduit, which discharges radially outward of the bore into the end of the pressure chamber facing away from the valve seat. The pressure shoulder on the valve member constantly plunges so far into the guide portion of the bore that an annular gap remains between the valve member and the wall of the bore on the end of the guide portion of the bore adjacent to the pressure chamber. In this gap, a contrary force on a remaining web between the bore and the pressure conduit is built up.
In previous version of pressure amplifiers controlled via the differential pressure chamber, the differential pressure chamber communicates, through what is as a rule a horizontal bore, with a second, valve-carrying bore. The horizontal bore proves to be extremely difficult to make. Time-consuming, expensive processes such as electrochemical countersinking or erosion must be employed. Moreover, at the intersection points between the differential pressure chamber and the horizontal bore, the maximum stresses occur in the component. High surface quality and rounding off of the edges that necessarily occur in manufacture, given the desired system pressures that must still be increased further, no longer suffice to obtain durable components. The internal central control line known from DE 102 47 903 A1 requires greater effort and expense of production and assembly than simple bores inside the injector body.
In designing pressure amplifiers controlled via the differential pressure chamber, the connection of the differential pressure chamber to the control line represents a potential weak point. Since the control valve for actuating the pressure amplifier, for reasons of installation space, is located above the pressure amplifier, the control line is made to run laterally past the pressure amplifier. In the embodiment proposed according to the invention, the connection between the differential pressure chamber and the control line, which as a rule is embodied as a bore and leads to the valve, is represented by an encompassing groove or a lateral pocket in the cylindrical differential pressure chamber of the pressure amplifier. The resultant advantage is that above all at the high-pressure intersection point between the differential pressure chamber and a groove, or between the differential pressure chamber and the cylindrically shaped pocket, no excessive increase in stresses whatever that impair the pressure resistance of the fuel injector are created. The excessive increase in stress at the high-pressure intersection point between the groove and the control line embodied as a bore, or between the cylindrically shaped pocket and the control line embodied as a bore, can be reduced substantially, so that with a fuel injector of this kind with optimized communication between the high-pressure chambers at the pressure booster, higher injection pressures can be achieved.
A further advantage of the embodiment proposed according to the invention is that an intersection point that is not sensitive to tolerances is attained between the groove or pocket and the control line embodied as a bore, since purely mechanical, metal-cutting production processes can be employed for producing the groove or the pocket.
By means of suitable shaping of the groove or of the cylindrically shaped pocket, specific shapes of the opening can thus be achieved that are geometrically oval, rectangular, or otherwise-shaped. By means of a defined shape of the opening, the stresses in the region of the high-pressure intersection point between the groove and the control line embodied as a bore, or between the cylindrically shaped pocket and the control line embodied as a bore, can be varied in a purposeful way and additional reduced still further. With connection points embodied in this way in the high-pressure region between high-pressure chambers of components that are exposed to extreme pressures, on the one hand, over the long term, the service lives of fuel injectors with pressure amplifiers can be shortened because of the lower stress level; on the other hand, by means of the connection proposed according to the invention of high-pressure chambers of components carrying extremely high pressure, it is possible to increase the injection pressure amplifier in fuel injectors still further.
The invention is described in detail below in conjunction with the drawings.
Shown are:
A pressure amplifier 1 includes a work chamber 2 and a differential pressure chamber 4 that can be relieved of pressure or subjected to pressure. The pressure amplifier 1 further includes a compression chamber 5 embodied in the body 11 of the pressure amplifier. The amplifier piston 3 that divides the differential pressure chamber 4 from the work chamber 2 includes a first end face 6 and a second end face 7 that defines the compression chamber 5. Via a high-pressure source, not further shown in
Via a pressure relief of the differential pressure chamber 4 to a pressure level ρfuel,return, the amplifier piston 3, because of the pressure force in the work chamber 2, which is generated by the system pressure (ρrail) and engages the first end face 6 of the amplifier piston, moves into the compression chamber 5. The second end face 7, which defines the compression chamber 5 of the pressure amplifier 1, compresses the fuel supply contained in the compression chamber 5 to an elevated pressure level (ρamplified), which is attainable in accordance with the design ratio of the pressure amplifier piston 3, which is carried in the region of an inlet 10 to an injection valve member, not shown in
The pressure amplifier 1 includes a body 11, in which a control line 12 embodied as a bore extends. The control line 12 embodied as a bore communicates with the differential pressure chamber 4 of the pressure amplifier 1 via a horizontal bore 13. The horizontal bore 13 is a critical region in terms of the stress level that is established in operation of the pressure amplifier 1. Within the critical region 14, also called an intersection region, both a first intersection point 15 with the control line 12 embodied as a bore and with the horizontal bore 13 and a second, critical intersection point 16 between the horizontal bore 13 and the differential pressure chamber 4 of the pressure amplifier 1 develop. In operation of the pressure amplifier 1, the greatest stresses occur at these intersection points 15 and 16 and decisively impair the durability of this kind of pressure amplifier 1 with a horizontal bore 13. The compression chamber 5 is shown in half-section through the body 11 of the pressure amplifier 1 in the view in
It can be seen from the view in
The view in
In the view in
In the view in
In the variant embodiment shown in
In the two variant embodiments, shown in
By comparison, an encompassing groove 18 as in
The differential pressure chamber 4 is embodied symmetrically to an axis of symmetry 25. The control line 12 and the differential pressure chamber 4 communicate with one another via the horizontal bore 13, so that the first intersection point 15 results between the horizontal bore 13 and the control line 12, and the second intersection point 16 is represented by the horizontal bore 13 and the differential pressure chamber 4. The notch effects that form at the intersection point 15 are added together, resulting in a first, very high stress level σmax,1 during operation of the pressure amplifier.
In the view shown in
The cylindrically shaped pocket 19 is molded into the inner wall in the lower region of the differential pressure chamber 4. The cylindrically shaped pocket 19 forms the connection point between the control line 12, embodied as a bore, and the differential pressure chamber 4 in the body 11. The control line 12 can be embodied as either a blind bore (
In this variant embodiment, the encompassing groove 18, which is embodied with a constant height 32, forms a first bore intersection 17. The first bore intersection 17 marks the transition point from the control line 12 embodied as a bore to the encompassing groove 18; a second bore intersection 22 is also established, which represents the transitional region between the differential pressure chamber 4 and the encompassing groove 18. The lower annular face of the encompassing groove 18 is identified by reference numeral 20. Further bores 33 may be connected to the encompassing groove 18, of which one is shown in
The contour of the encompassing groove 18 and of the cylindrically shaped pocket 19 can be embodied as curved, angular, with rounded corners, or with some other geometry.
The versions shown in
Number | Date | Country | Kind |
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103 29 052.4 | Jun 2003 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE04/00743 | 4/8/2004 | WO | 12/16/2005 |