EP2025920A1 - Injection nozzle for fuel - Google Patents

Abstract

The spray nozzle has valve spool (14) that is provided in the longitudinal direction bore of the nozzle head (3) to open and close the nozzle hole (4.1, 4.2). The actuator (8.2, 9.2, 15) shifts time and operates the valve spool with respect to the needle valve (6). The valve seat (7) which cooperates with a needle valve in order to control the fuel supply to the needle valve arranged inside the nozzle body (2), the longitudinal direction bore (5), and the nozzle holes.

Description

The invention relates to an injection nozzle for injecting fuel in a diesel engine, according to the preamble of claim 1 and a diesel engine, in particular a two-stroke large diesel engine with at least one such injection nozzle.

In some diesel engines, and particularly in two-stroke large diesel engines of conventional design, such as those used in ships and power plants, injectors are used which include a nozzle body and a nozzle head connected thereto having a longitudinal bore and one or more nozzle orifices opening from go out of the longitudinal bore to inject fuel into a arranged in a cylinder combustion chamber of the diesel engine. Further, such injectors include a valve needle disposed within the nozzle body and a valve seat which cooperates with the valve needle to control the fuel supply to the longitudinal bore and the nozzle orifices.

Typically, the valve seat of the fuel injector is located away from the nozzle orifices because it must be sufficiently supported to accommodate the pressure loads resulting from the high injection pressures. This requires a correspondingly robust construction, which takes up relatively much space. But since typically several injectors are provided per cylinder, it would be out Space reasons, difficult to design the areas of the injectors, which are located in the immediate vicinity of the combustion chamber, according to robust. In addition, in a two-stroke diesel engine, the cylinder head is usually so thick that these portions of the injectors would hardly be cooled and would therefore be exposed to very high temperatures during operation if the valve seats of the fuel injectors were not located as usual away from the nozzle holes. Sufficient distance between the valve seats and the corresponding orifices ensures that the valve seats do not overheat during operation and function properly under all operating conditions.

Due to the construction described above, the volume of fuel that remains in the longitudinal bore of the nozzle head after closing the valve needle is significant. The fuel remaining in the longitudinal bore heats up and may leak into the combustion chamber during the expansion phase due to the decreasing pressure. At this point in time, the temperatures in the combustion chamber may already have dropped to such an extent that they are no longer sufficient for complete combustion. Experiments have shown that the volume of the remaining fuel in the longitudinal bore has a significant influence on the soot emission of the diesel engine.

In document WO 93/07386 An injection nozzle is described with a nozzle head which comprises a longitudinal bore and a nozzle opening, and with a valve which comprises a valve seat and a closing part in order to open and close the fuel supply to the nozzle head and the nozzle opening. The injector after WO 93/07386 additionally comprises a closing element designed as a sleeve, which is firmly connected to the closing part of the valve in order to open and close the nozzle opening. With the additional closing element, the unwanted escape of fuel from the longitudinal bore of the nozzle head can be prevented during the expansion phase. Due to the fixed connection between the closing part of the valve and the additional closing element high demands are placed on the manufacturing tolerances, and the cross-sectional profile in the valve seat of the valve and at the nozzle opening must be precisely coordinated so that the fuel pressure does not expand the sleeve too much and thus damaged.

Object of the present invention is to provide an injector for injecting fuel in a diesel engine, in particular a two-stroke large diesel engine available, the closing part and closing element are easier to manufacture, and no critical coordination between the cross-sectional profile in the valve seat of the valve and requires the cross-sectional profile at the nozzle orifices. A further object is to provide a diesel engine, in particular a two-stroke large diesel engine with at least one such injection nozzle available.

This object is achieved according to the invention by the injection nozzle defined in claim 1 and by the diesel engine defined in claim 10.

The injector according to the invention for injecting fuel into a diesel engine, in particular a two-stroke large diesel engine, comprises a nozzle body and a nozzle head connected thereto, which has a longitudinal bore and one or more nozzle openings, which emanate from the longitudinal bore to fuel in a combustion chamber of the diesel engine inject. Furthermore, the injection nozzle comprises a valve needle arranged in the interior of the nozzle body and a valve seat which cooperates with the valve needle in order to control the fuel supply to the longitudinal bore and to the nozzle openings. In the injection nozzle, a slide for opening and closing the nozzle openings is additionally provided in the longitudinal bore of the nozzle head, which is provided with its own actuator to operate the slide in operation offset in time from the valve needle.

Advantageously, the slide for opening and closing the nozzle openings in the longitudinal direction of the nozzle head is displaceable and / or rotatable relative thereto. The slider may be formed, for example, as a sleeve or part of a sleeve or as a cylindrical part or part of a cylindrical part.

In an advantageous embodiment, the actuator of the slide is designed as an electric, pneumatic or hydraulic actuator, for example as a longitudinal piston or as a hydraulic rotary valve drive. For example, the actuator of the spool may be connected to the fuel supply to the injector to control the spool with the pressure of the fuel supplied. In a further advantageous embodiment, the actuator of the slide comprises a return spring, by means of which the slide or the longitudinal piston or rotary valve drive can be brought into an initial or rest position.

In an advantageous embodiment, the injection nozzle comprises a circuit for cooling the nozzle body and / or nozzle head. For example, the circuit may be fueled and, if desired, connected to a reduced pressure fuel system. In a further advantageous embodiment variant, the injection nozzle comprises a control valve, which may be arranged in an upper part or region of the injection nozzle to the actuation of the slide and / or the fuel supply to the injection nozzle and / or, if present, a circuit for cooling the nozzle body and / or nozzle head to control.

The invention further includes a diesel engine, in particular a two-stroke large diesel engine, with at least one injection nozzle for injecting fuel according to one or more of the embodiments and variants described above.

Thanks to the slide in the longitudinal bore of the nozzle head and thanks to its own actuator for the slide can be avoided in the injectors described above during the expansion phase of the undesirable leakage of fuel from the longitudinal bore of the nozzle head. This also avoids the emission of soot that would otherwise result from incomplete combustion of fuel during the expansion phase. Another advantage is that no voltages are transmitted from the valve needle to the slide in the longitudinal bore, so that it can be moved freely in the bore, since there is no firm connection between the valve needle and the slide in the injector described above. Thanks to its own actuator for the slide, the above described Injector are controlled so that the slide little or no movement, as long as the longitudinal bore is subjected to the fuel pressure. In this way, the wear of both the nozzle head, as well as the slider and actuator can be reduced.

The above description of embodiments and variants is merely an example. Further advantageous embodiments will become apparent from the dependent claims and the drawings. In addition, in the context of the present invention, individual features of the described or shown embodiments and variants can be combined with each other to form new embodiments.

Fig. 1

einen Längsschnitt durch eine herkömmliche Einspritzdüse,

Fig. 2A

einen Längsschnitt durch ein Ausführungsbeispiel einer Einspritzdüse gemäss vorliegender Erfindung,

Fig. 2B

einen Längsschnitt durch ein zweites Ausführungsbeispiel einer Einspritzdüse gemäss vorliegender Erfindung,

Fig. 3

Längsschnitte durch ein drittes Ausführungsbeispiel einer Einspritzdüse und durch ein Steuerventil gemäss vorliegender Erfindung,

Fig. 3A,B,C

Querschnitte zum Ausführungsbeispiel von Fig. 3, und

Fig. 3D

einen Längsschnitt durch das Steuerventil von Fig. 3 während einer Einspritzpause.

In the following the invention will be explained in more detail with reference to the embodiments and with reference to the drawing. Show it:

Fig. 1

a longitudinal section through a conventional injection nozzle,

Fig. 2A

a longitudinal section through an embodiment of an injection nozzle according to the present invention,

Fig. 2B

a longitudinal section through a second embodiment of an injection nozzle according to the present invention,

Fig. 3

Longitudinal sections through a third embodiment of an injection nozzle and by a control valve according to the present invention,

Fig. 3A, B, C

Cross sections of the embodiment of Fig. 3 , and

Fig. 3D

a longitudinal section through the control valve of Fig. 3 during an injection break.

Fig. 1 shows a longitudinal section through a conventional injector 10 for injecting fuel in a diesel engine, in particular in a two-stroke large diesel engine. The injection nozzle 10 comprises a nozzle holder 1, a nozzle body 2 with a cylinder bore and a nozzle head 3 with a longitudinal bore 5 and nozzle openings 4 extending from the longitudinal bore to inject fuel into a combustion chamber of the diesel engine. Furthermore, the injection nozzle 10 comprises a piston 8, which is arranged movably in the cylinder bore, a valve needle 6, which in the in Fig. 1 is shown formed on the piston 8, and arranged in the extension of the valve needle 6 valve seat 7 and arranged in the extension of the piston 8 plunger 11 and a compression spring 9, the spring force is transmitted via the plunger 11 to the piston 8. Thus, as long as the fuel pressure applied to the injector is low, the valve needle 6 connected to the piston is pressed against the valve seat 7, so that the fuel supply to the nozzle head 3 is interrupted.

Fig. 2A shows a longitudinal section through an embodiment of an injection nozzle for injecting fuel in a diesel engine, in particular a two-stroke large diesel engine, according to the present invention. The injection nozzle comprises a nozzle body 2 and a nozzle head 3 connected thereto, which has a longitudinal bore 5 and at least one nozzle opening 4.1, 4.2, which starts from the longitudinal bore, in order to inject fuel into a combustion chamber of the diesel engine. Furthermore, the injection nozzle comprises a valve needle 6 arranged in the interior of the nozzle body 2 and a valve seat 7 which cooperates with the valve needle in order to control the fuel supply to the longitudinal bore 5 and to the at least one nozzle opening 4.1, 4.2. In the injection nozzle, a slide 14 for opening and closing the nozzle opening or openings 4.1, 4.2 is provided in the longitudinal bore 5 of the nozzle head 3 in addition, which is movable in the longitudinal direction of the nozzle head with advantage, and with its own 8.2, 9.2, 15 is provided to operate the slide 14 in operation offset in time from the valve needle 6.

Next, the injector of in Fig. 2A case shown, a nozzle holder shown in Fig. 2A is omitted for clarity, and / or a piston 8.1, which is movably arranged, for example, in a cylinder bore in the nozzle body 2 and with the valve needle 6 in conjunction, occasionally operative connection, and / or comprise a return spring 9.1, the spring force on a case by case basis Piston 8.1 and / or the valve needle 6 acts to these in the injection breaks and in the To press rest against the valve seat 7 and to interrupt the fuel supply to the nozzle head 3. In an advantageous embodiment, the piston connected to the valve needle 8.1 can be acted upon by a fuel supply 12 with the fuel pressure to separate the valve needle 6 by means of the piston from the valve seat 7 and release the fuel supply to the nozzle head 3.

The slider 14 may, for example, as in Fig. 2A shown as a sleeve or occasionally be formed as part of a sleeve or as a cylindrical part or part of a cylindrical part, wherein in the sleeve or in the said parts case by case one or more openings are provided, the injection of fuel into the injection valve 14 or the the nozzle openings 4.1, 4.2 release.

In an advantageous embodiment, the actuator of the slider 14 is designed as a hydraulic actuator, for example as a longitudinal piston 8.2, which is arranged, for example, in the valve needle 6 and / or in a connected thereto piston 8.1 movable. The hydraulic actuator of the actuator is operatively connected in the embodiment with the slider 14, for example by, as in Fig. 2A shown, the movement of the longitudinal piston 8.2 is transmitted via a pin 15 on the slider. The pin 15 may be movably guided, for example, in a longitudinal bore of the valve needle 6. In some cases, the actuator of the slide can be connected to the fuel supply 12 of the injection nozzle, for example via a compensation opening 13 in the valve needle 6 to actuate the slide 14 with the pressure of the supplied fuel.

In a further advantageous embodiment, the actuator of the slide 14 comprises a return spring 9.2, by means of which the slide or the longitudinal piston 8.2 can be brought into an initial or rest position to close the nozzle opening or openings 4.1, 4.2. If both the valve needle 6 and the actuator of the slider 14 are actuated with the pressure of the supplied fuel, so the spring constant and voltage of the return spring 9.1 of the valve needle 6 is suitably matched to the spring constant and voltage of the return spring 9.2 of the slider 14, and Although with advantage such that the nozzle opening or openings 4.1, 4.2 are released by the slide before the valve needle 6 moves and the fuel supply to the nozzle head 3 is opened.

In a further advantageous embodiment variant, the piston connected to the valve needle 6 8.1 comprises a spiral groove 8.1 a, which connects the fuel supply 12 of the injection nozzle with a cavity formed in the nozzle body 2, which surrounds the front part of the associated with the valve needle piston 8.1 and parts of the valve needle , In this way, the piston is 8.1 centered in operation and lubricated while slowing down the pressure increase in the cavity when supplying fuel, whereby the operation of the associated with the valve needle 6 piston 8.1 can be delayed.

The injection process will be described below with reference to the embodiment of Fig. 2A explained. If fuel is supplied to the injection nozzle via the fuel supply 12, the pressure in the cavity formed in the nozzle body 2, which surrounds the front part of the piston 8.1 connected to the valve needle and parts of the valve needle 6, increases. The pressure increase is transmitted to the longitudinal piston 8.2 of the slide 14 via the compensation opening 13 in the valve needle, the longitudinal piston being moved as soon as the force effect of the fuel pressure on the longitudinal piston exceeds the spring force of the restoring spring 9.2 acting on the longitudinal piston. The movement of the longitudinal piston 8.2 is transmitted via the pin 15 to the slider 14, wherein the slider is moved to a position in which the opening or openings in the slide with the nozzle orifices 4.1, 4.2 in the nozzle head 3 match and these are released. If the fuel pressure in the cavity continues to increase, the piston 8.1 connected to the valve needle 6 is moved as soon as the force effect of the fuel pressure on the piston exceeds the spring force of the return spring 9.1 acting on the piston. Thus, the valve needle 6 is moved away from the valve seat 7 and the fuel supply to the nozzle head 3 and to the one or more nozzle openings 4.1, 4.2 opened. The fuel exiting through the nozzle orifice is now injected into a combustion chamber of the diesel engine.

The injection process is terminated by stopping the supply of fuel to the injector. In this case, the fuel pressure in the cavity decreases, and the piston 8.1 connected to the valve needle 6 presses the valve needle 6 against the valve seat 7 as soon as the spring force of the return spring 9.1 acting on the piston exceeds the force effect of the fuel pressure on the piston. Thus, the fuel supply to the nozzle head 3 is closed. If the fuel pressure in the cavity continues to decrease, the longitudinal piston 8.2 of the slide 14 is moved as soon as the spring force of the restoring spring 9.2 acting on the longitudinal piston exceeds the force effect of the fuel pressure on the longitudinal piston. The movement of the longitudinal piston 8.2 is transmitted via the pin 15 to the slider 14, wherein the slider is moved to a position in which the nozzle opening or openings 4.1, 4.2 are closed in the nozzle head 3. Thus, when the injection process is completed, an undesirable leakage of fuel from the longitudinal bore of the nozzle head can be avoided.

Fig. 2B shows a longitudinal section through a second embodiment of an injection nozzle for injecting fuel in a diesel engine, in particular a two-stroke large diesel engine, according to the present invention. This in Fig. 2B embodiment shown differs from that in Fig. 2A shown mainly by a modified version of the fuel supply and by a further embodiment in which a drain line 16, 16 'is provided. In the second exemplary embodiment, the injection nozzle comprises a nozzle body 2 and a nozzle head 3 connected thereto, which has a longitudinal bore 5 and one or more nozzle openings 4.1, 4.2 which emanate from the longitudinal bore in order to inject fuel into a combustion chamber of the diesel engine. Furthermore, the injection nozzle comprises a valve needle 6 arranged in the interior of the nozzle body 2 and a valve seat 7 which cooperates with the valve needle in order to control the fuel supply to the longitudinal bore 5 and to the nozzle openings 4.1, 4.2. In the injection nozzle, a slide 14 for opening and closing the nozzle openings 4.1, 4.2 is additionally provided in the longitudinal bore 5 of the nozzle head 3, which is advantageously movable in the longitudinal direction of the nozzle head, and which is provided with its own actuator 8.2, 9.2, 15, to operate the slide 14 in operation offset in time from the valve needle 6.

Next, the injector of in Fig. 2B case shown, a nozzle holder shown in Fig. 2B is omitted for clarity, and / or a piston 8.1, which is movably arranged, for example, in a cylinder bore in the nozzle body 2 and with the valve needle 6 in conjunction, occasionally operative connection, and / or comprise a return spring 9.1, the spring force on a case by case basis connected to the valve needle piston 8.1 and / or the valve needle 6 acts to press this after the injection of fuel and at rest against the valve seat 7 and to interrupt the fuel supply to the nozzle head 3.

In an advantageous embodiment, the actuator of the slider 14 is designed as a hydraulic actuator, for example as a longitudinal piston 8.2, which is arranged, for example, in the valve needle 6 and / or in a connected thereto piston 8.1 movable. The hydraulic actuator of the actuator is operatively connected in the embodiment with the slider 14, for example by, as in Fig. 2B shown, the movement of the longitudinal piston 8.2 is transmitted via a pin 15 on the slider. The pin 15 may be movably guided, for example, in a longitudinal bore of the piston connected to the valve needle 8.1 and / or in the valve needle 6.

In a further advantageous embodiment, the actuator of the slide 14 comprises a return spring 9.2, by means of which the slide or the longitudinal piston 8.2 can be brought into an initial or rest position to close the nozzle opening or openings 4.1, 4.2.

In the in Fig. 2B In the exemplary embodiment shown, the injection nozzle comprises a fuel feed 12, which is connected to a cavity formed in the nozzle body 2, which surrounds the front part of the piston 8.1 connected to the valve needle and parts of the valve needle. In this way, the piston 8.1 can be acted upon by the fuel pressure to separate the valve needle 6 by means of the piston from the valve seat 7 and release the fuel supply to the nozzle head 3. In some cases, the actuator of the slide with the fuel supply 12 of the injector be connected, for example via a compensation opening 13 in the valve needle 6 to actuate the slider 14 with the pressure of the supplied fuel.

In an advantageous embodiment, a leak oil line 16, 16 'is provided for pressure relief of the guide of the pin 15. If, as in Fig. 2B shown, the pin 15 is movably guided in a longitudinal bore of the associated with the valve needle piston 8.1 and / or in the valve needle 6, a first part 16 of the drain line, for example, formed in the connected to the valve needle piston 8.1 and / or in the valve needle 6 and a second part 16 'in the nozzle body 2, wherein the two parts are connected continuously, when the valve needle 6 rests on the valve seat 7 and the fuel supply to the nozzle head 3 is closed. Thanks to the leak oil line can be prevented that fuel passes along the pin 15 in the longitudinal bore 5 of the nozzle head and the pressure of the fuel in the longitudinal bore increases before the fuel supply to the nozzle head is released by the valve needle 7.

Further embodiments, variants and details for the interpretation of in Fig. 2B shown injection nozzle can the description too Fig. 2A be removed. In addition, in connection with the embodiment of Fig. 2A put forward explanation of the injection process also on the in Fig. 2B shown embodiment.

Fig. 3 shows a longitudinal section through a third embodiment of an injection nozzle for injecting fuel in a diesel engine, in particular a two-stroke large diesel engine, and a control valve according to the present invention. In the third exemplary embodiment, the injection nozzle comprises a nozzle body 2 and a nozzle head 3 connected thereto, which has a longitudinal bore 5 and one or more nozzle openings 4.1, 4.2 which emanate from the longitudinal bore in order to inject fuel into a combustion chamber of the diesel engine. Furthermore, the injection nozzle comprises a valve needle 6 arranged in the interior of the nozzle body 2 and a valve seat 7 which cooperates with the valve needle in order to control the fuel supply to the longitudinal bore 5 and to the nozzle openings 4.1, 4.2. In the injector is in the Longitudinal bore 5 of the nozzle head 3 additionally a slider 14 'for opening and closing the nozzle openings 4.1, 4.2 is provided, which is rotatable with advantage with respect to the nozzle head 3, and which is provided with its own actuator 8.3, 9.3 to the slider 14' in operation offset from the valve needle 6 to actuate.

Next, the injector of in Fig. 3 case shown, a nozzle holder shown in Fig. 3 is omitted for clarity, and / or a piston 8.1, which is movably arranged, for example, in a cylinder bore in the nozzle body 2 and with the valve needle 6 in conjunction, occasionally operative connection, and / or comprise a return spring, the spring force on a case by case the valve needle connected piston 8.1 and / or the valve needle 6 acts to press them in the injection breaks and in the rest state against the valve seat 7 and to interrupt the fuel supply to the nozzle head 3. In an advantageous embodiment, the piston connected to the valve needle 8.1 can be acted upon by a fuel supply 12 with the fuel pressure to separate the valve needle 6 by means of the piston from the valve seat 7 and release the fuel supply to the nozzle head 3.

The slider 14 'is executed in the embodiment shown as a rotary valve, for example, as in the FIGS. 3 and 3A shown as a part which is cylindrically shaped over the greater part of the circumference, or occasionally may be formed as part of a cylindrical part or as a sleeve or part of a sleeve, wherein provided in said parts or in said sleeve case by case one or more openings are in the injection position of the slide 14 ', the fuel supply to the orifices 4.1, 4.2 release. If necessary, the slider 14 'can be rotatably guided in the nozzle head 3 and / or stored, for example in the longitudinal bore 5 of the nozzle head.

In an advantageous embodiment, the actuator of the slider 14 'is formed as a hydraulic actuator, for example, as in the Figures 3, 3B and 3C shown as a rotary drive with at least one rotatably mounted pin 8.3a and a cam formed thereon 8.3, in a cylindrical cavity or a sector of a cylindrical Cavity is rotatably guided, and which closes the cavity, so that the cam and pin perform a rotational movement when the cavity is subjected to a pressurized medium. The hydraulic actuator of the actuator is in the exemplary embodiment with the slider 14 'operatively connected, for example via a slot coupling. The rotary drive can be arranged, for example, between the valve seat 7 and the nozzle head 3. But it is also possible, for example, to arrange the rotary drive in the upper part of the injection nozzle and, for example via a shaft with the slider 14 'to connect, if necessary with the interposition of gears. In some cases, the hydraulic actuator can also be combined with a control spool of a control valve.

In a further advantageous embodiment, the actuator of the slider 14 'comprises a return spring 9.3, which, for example, as in Fig. 3C shown, may be formed as a spiral spring, by means of which the slide or the rotary drive can be brought into an initial or rest position to close the nozzle opening or openings 4.1, 4.2.

In some cases, the actuator of the slide can be connected to the fuel supply 12 of the injection nozzle to actuate the slide 14 'with the pressure of the supplied fuel. If both the valve needle 6 and the actuator of the slide 14 'are actuated with the pressure of the supplied fuel, so the spring constant and - voltage of the return spring 9.1 of the valve needle 6 is suitably adjusted to the spring constant and voltage of the return spring 9.3 of the slider 14' , and with advantage such that the nozzle opening or openings 4.1, 4.2 are released by the slider before the valve needle 6 is moved and the fuel supply to the nozzle head 3 is opened.

In an advantageous embodiment, the injection nozzle comprises a circuit for cooling the nozzle body 2 and / or nozzle head 3. The circuit can be designed, for example, for fuel and if necessary connected to a fuel system with reduced pressure.

In a further advantageous embodiment, the injection nozzle comprises a control valve 20, which may be arranged in an upper part or region of the injection nozzle to the actuation of the slide 14, 14 'and / or the fuel supply to the injection nozzle and / or, if present, a circuit to control the cooling of the nozzle body 2 and / or nozzle head 3.

In Fig. 3 is shown in the upper part of a longitudinal section through an embodiment of such a control valve. The control valve 20 includes a spool 21, which is in Fig. 3 located in a position for injecting fuel, as well as an in Fig. 3 not shown auxiliary drive, such as a hydraulic cylinder, for actuating the spool. The control valve may occasionally include a valve for controlling the fuel supply with a valve seat, a closing part 22 and a return spring 23 to push the closing part against the valve seat. In the in Fig. 3 shown position of the spool 21, the closing part 22 is pushed away by the same from the valve seat, and the supply of the fuel from the fuel supply 12 'of the control valve to the valve needle 6 of the injection nozzle via the fuel supply 12 of the injection nozzle released. Further, the control valve 20, a control function, which is designed for example as a 2/2-way or 3/2-way valve for controlling the slide 14, 14 'included, and occasionally a control line 18 through which the control valve with the Actuator of the slide is connected. The corresponding supply of a pressurized medium to the control valve takes place for example via an inlet 24, which may be connected to the fuel supply or with a fuel system with reduced pressure. In the in Fig. 3 shown position of the spool 21, the inlet 24 is connected to the control line 18 to actuate the slider 14, 14 'and the nozzle openings 4.1, 4.2 release.

If the injection nozzle comprises a circuit for cooling the nozzle body 2 and / or nozzle head 3, a control function for controlling the circuit may be provided in the control valve 20, which comprises, for example, a 2/2-way valve. Advantageously, the control valve is connected for this purpose via a return 17 to the cooling device of the injection nozzle. As a cooling device, for example, as in Fig. 3 shown, the fuel supply 12, the cavity formed in the nozzle body 2, which surrounds the front part of the associated with the valve needle piston 8.1 and parts of the valve needle, and the return 17 can be used. For example, the circuit may be fueled and, if desired, connected to a reduced pressure fuel system to conserve pump power. In the in Fig. 3 shown position of the spool 21, the return 17 is closed, since in the variant shown during the injection of fuel no circulation is provided in the cooling circuit.

Fig. 3D shows a longitudinal section through the control valve of Fig. 3 during an injection break. The control valve 20 includes a spool 21, which is in Fig. 3D is in a rest position corresponding to the position during the injection pauses. The control valve may occasionally include a valve for controlling the fuel supply with a valve seat, a closing part 22 and a return spring 23. In the in Fig. 3D shown position of the spool 21 is the same separated from the closing part 22, so that the closing part is pressed by the return spring 23 against the valve seat and the fuel supply from the fuel supply 12 'of the control valve to the valve needle 6 of the injection nozzle is interrupted. Further, the control valve 20, a control function, which is designed for example as a 2/2-way or 3/2-way valve for controlling the slide 14, 14 'included, and occasionally a control line 18 through which the control valve with the Actuator of the slide is connected. In the in Fig. 3D shown position of the spool 21, the control line 18 is connected to an outlet 25, which may for example be in communication with a leak oil tank to relieve the actuator of the slide and to close the nozzle opening or openings 4.1, 4.2.

If the injection nozzle comprises a circuit for cooling the nozzle body 2 and / or nozzle head 3, a control function for controlling the circuit may be provided in the control valve 20, which comprises, for example, two 2/2-way valves. Advantageously, the control valve is connected for this purpose via a return 17 to the cooling device of the injection nozzle. The circuit may be designed, for example, for fuel and if necessary, connected to a fuel system with reduced pressure to save pump power. In the in Fig. 3D shown position of Spool valve 21, the return 17 is connected to an outlet 26, which may be connected, for example, to a tank of the fuel system with reduced pressure. In addition, in the illustrated position of the spool valve 21, the inlet 24, which may be connected to the reduced pressure fuel system, for example, is connected to the fuel supply 12 of the injector. In this way, fuel can be passed through the cooling device of the injection nozzle at reduced pressure. As a cooling device, for example, as in Fig. 3 shown, the cavity formed in the nozzle body 2, which surrounds the front part of the associated with the valve needle piston 8.1 and parts of the valve needle, and the fuel supply 12 and the return 17 are used, which are in communication with the cavity.

Depending on the design, the course of the injection process and / or the actuation of the slide 14, 14 'in the nozzle head 2 and / or a circuit for cooling the nozzle body 2 and / or nozzle head 3 can be controlled by means of the control valve 20. Advantageously, the cooling circuit and optionally the actuator for actuating the slide from a low pressure system, such as a fuel system with reduced pressure, fed to keep the pumping losses in the cooling circuit low. With the beginning of the injection process, the spool 21 interrupts the supply to the cooling device in the injection nozzle and the return circuit 17 of the cooling circuit and / or opens the connection between the connected to a pressure system inlet 24 and the control line 18, the control valve with the actuator for the slide combines. As a result, the slide in the nozzle head is brought into the injection position and the nozzle opening or openings 4.1, 4.2 are released. The actual injection process is triggered by a further displacement of the spool 21, which opens a valve provided in the control valve for controlling the fuel supply, whereby the fuel passes to the valve needle 6 in the injection nozzle. As a result of the fuel pressure, the piston 8.1 connected to the valve needle 6 and the valve needle are pushed away from the valve seat 7 and the fuel supply to the nozzle head 3 and to the nozzle orifices 4.1, 4.2 is opened. The fuel exiting through the nozzle orifice is now injected into a combustion chamber of the diesel engine.

The injection process is terminated by the control spool 21 of the control valve first closing the fuel supply control valve provided therein. In this case, the fuel pressure at the piston connected to the valve needle 6 drops 8.1 and the valve needle 6 is pressed by the spring force of the force acting on the piston return spring 9.1 against the valve seat 7. Thus, the fuel supply to the nozzle head 3 is closed. By further displacement of the spool, the connection between the inlet connected to a pressure system inlet 24 and the control line 18, which connects the control valve with the actuator for the slide, can be interrupted. As a result, the slider is moved to a position in which the nozzle opening or openings 4.1, 4.2 are closed in the nozzle head 3. In this way, when the injection process is completed, an undesirable leakage of fuel from the longitudinal bore of the nozzle head can be avoided. If a circuit for cooling the nozzle body 2 and / or nozzle head 3 is present, the supply to the cooling device in the injection nozzle and the return 17 of the cooling circuit by means of the spool can be opened to the nozzle body and / or nozzle head in the injection breaks or in the rest position to cool the injector.

Thanks to its own actuator for the slide, it is possible to control the injector, as described above, so that the slide little or no movement, as long as the longitudinal bore in the nozzle head is acted upon by the fuel pressure from the fuel supply. This has the advantage that both the wear of the nozzle head, as well as the wear of the slide and actuator can be reduced.

Claims (10)

Injection nozzle for injecting fuel in a diesel engine, in particular a two-stroke large diesel engine, comprising a nozzle body (2), a nozzle head (3) connected thereto and having a longitudinal bore (5) and one or more nozzle openings (4.1, 4.2) Starting from the longitudinal bore to inject fuel into a combustion chamber of the diesel engine, as well as with a valve needle (6) arranged inside the nozzle body (2) and with a valve seat (7) which cooperates with the valve needle to the fuel supply to the longitudinal bore (5 ) and to the nozzle openings (4.1, 4.2) to control, characterized in that in the longitudinal bore of the nozzle head (3) in addition a slide (14, 14 ') for opening and closing the nozzle openings (4.1, 4.2) is provided with its own actuator (8.2, 8.3, 9.2, 9.3, 15) is provided in order to actuate the slide (14, 14 ') in operation offset in time from the valve needle (6). Injection nozzle according to claim 1, wherein the slide (14, 14 ') for opening and closing the nozzle openings (4.1, 4.2) in the longitudinal direction of the nozzle head (3) is displaceable and / or rotatable relative thereto. Injection nozzle according to one of claims 1 or 2, wherein the slide (14, 14 ') is formed as a sleeve or part of a sleeve or as a cylindrical part or part of a cylindrical part. Injection nozzle according to one of claims 1 to 3, wherein the actuator (8.2, 8.3, 9.2, 9.3, 15) of the slide (14, 14 ') is designed as a hydraulic actuator. Injection nozzle according to claim 4, wherein the hydraulic actuator as a longitudinal piston (8.2) or as a hydraulic rotary valve drive (8.3) is trained. Injection nozzle according to claim 4 or 5, wherein the actuator (8.2, 8.3, 9.2, 9.3, 15) of the slide (14, 14 ') is connected to the fuel supply to the injection nozzle to control the slide with the pressure of the supplied fuel. Injection nozzle according to one of the preceding claims, wherein the actuator (8.2, 8.3, 9.2, 9.3, 15) of the slide (14, 14 ') comprises a return spring (9.2, 9.3). Injection nozzle according to one of the preceding claims comprising a circuit for cooling the nozzle body (2) and / or nozzle head (2), in particular a circuit for fuel, which is for example connected to a fuel system with reduced pressure. Injection nozzle according to one of the preceding claims, comprising a control valve (20) for actuating the slide (14, 14 ') and / or the fuel supply to the injection nozzle and / or, if present, a circuit for cooling the nozzle body and / or nozzle head Taxes. Diesel engine, in particular two-stroke large diesel engine, with at least one injection nozzle according to one of claims 1 to 9.

Images