EP1873393A1 - Injector - Google Patents

Abstract

The injector has a nozzle needle (9) exhibiting a control surface (17) that limits a control chamber (38) axially, where an effective hydraulic force charges at the control surface in a closing direction of the nozzle needle during the operation of the injector. The nozzle needle exhibits an articulated section (19), where the nozzle needle in the articulated section is angularly flexible than in a proximate section with respect to a bending load that is oriented transverse to a longitudinal central axis (10) of the nozzle needle.

Description

State of the art

The present invention relates to an injector of a fuel injection system for an internal combustion engine, in particular in a motor vehicle, having the features of the preamble of claim 1.

From the DE 199 19 432 C2 an injector is known which has an injector body, a nozzle needle and a control device. The injector body has at least one injection hole and contains a feed path for supplying the at least one injection hole with fuel under injection pressure. The nozzle needle is mounted in an adjustable stroke in the injector body and has a needle tip for controlling an injection of fuel through the at least one injection hole. The control device is used to control the pressure in a control chamber, and the nozzle needle has a control area axially limiting control surface. During operation of the injector, a hydraulic force acting in the closing direction of the nozzle needle acts on the control surface such that a pressure drop in the control chamber activates the nozzle needle for opening. In the known injector, the nozzle needle comprises a needle body equipped with the needle tip, and two sleeve-shaped piston bodies which bear against one another axially, contain a low-pressure space in their interior and are supported axially on the needle body. The control device is designed as a solenoid valve whose valve member controls an end opening of the sleeve body of the body remote from the needle body, which connects the control chamber with said low-pressure space. Of the Feed path is passed in the injector body to a needle chamber in which at least the sleeve-shaped piston body of the nozzle needle are housed.

As the development of injection technology progresses, so does the increase in the desired injection pressures. Conventional injectors with leaks are then no longer suitable, since the leakage quantities are increasing with increasing pressure.

Advantages of the invention

The injector according to the invention with the features of claim 1 has the advantage that the nozzle needle can be built comparatively long, without causing the risk of leakage generally occurs. This is achieved by means of at least one joint portion within the nozzle needle, whereby the nozzle needle in said joint portion with respect to bending loads, which are oriented transversely to the longitudinal center axis of the nozzle needle, flexurally designed as adjoining sections of the nozzle needle. Due to the increased flexibility or flexibility of the nozzle needle in the respective joint section, transverse loads in the nozzle needle in the region of axial guides can be reduced. In particular, this allows positional tolerances between the nozzle needle and its respective axial guidance to be compensated, thereby reducing lateral loads and wear.

In an advantageous development, at least one of the joint sections can have at least one rectilinear web, wherein the web extends radially with respect to a longitudinal center axis of the nozzle needle and wherein the web connects axially adjacent axial sections of the nozzle needle. With the aid of such a web, the bendability or flexibility of the nozzle needle is greatly increased in the joint section by a bending axis defined by the longitudinal direction of the web. A further development is advantageous in which the respective joint section has at least two such webs, which are axially spaced from each other and offset by 90 ° from one another about the longitudinal center axis of the nozzle needle. As a result, the flexibility of the nozzle needle in the region of the joint portion is increased by two mutually perpendicular axes, resulting in a kind of gimbal mobility of the interconnected via the joint portion sections of the nozzle needle.

Basically, the nozzle needle can be made in one piece and in one piece, which can reduce tolerance chains. It is also possible to assemble the nozzle needle of a plurality of components, which are firmly connected to each other at least in the axial direction. In any case, the nozzle needle can be designed leak-free, so that it is virtually insensitive to attacking pressures. Furthermore, a leak-free design of the nozzle needle allows the accommodation of the nozzle needle in a needle chamber through which the feed path is passed. As a result, the nozzle needle is arranged in the fuel under high pressure, which greatly simplifies the fuel supply within the injector.

Further important features and advantages of the injector according to the invention will become apparent from the subclaims, from the drawings and from the associated description of the figures with reference to the drawings.

drawings

Fig. 1 und 2

jeweils einen stark vereinfachten prinzipiellen Längsschnitt durch einen Injektor, bei verschiedenen Aus führungs formen.

Embodiments of the injector according to the invention are illustrated in the drawings and are explained in more detail below, wherein like reference numerals refer to the same or similar or functionally identical components. Show, in each case schematically,

Fig. 1 and 2

in each case a greatly simplified basic longitudinal section through an injector, with different embodiments.

Description of the embodiments

According to FIGS. 1 and 2, an injector 1 comprises an injector body 2, which consists for example of a control section 3 and a needle section 4. Control section 3 and needle section 4 can be fastened to each other, for example via a connection sleeve, not shown, in the manner of a union nut. The injector body 2 contains in its needle section 4 at least one injection hole 5, by an injection of fuel in an injection chamber 6 is feasible. Furthermore, the injector body 2 contains a feed path 7, which supplies the at least one injection hole 5 with fuel under injection pressure. For this purpose, the injector 1 is connected via the feed path 7 to a high-pressure fuel line 8. This forms as well as the injector 1 is a part of a fuel injection system for an internal combustion engine, not shown otherwise, which can be arranged in particular in a motor vehicle. In a so-called common rail system, several injectors 1 are connected to the same off high pressure line 8.

The injector 1 also has a nozzle needle 9, which is mounted in a manner adjustable in stroke in the injector body 2. The stroke direction is oriented parallel to a longitudinal central axis 10 of the nozzle needle 9. The nozzle needle 9 has a needle tip 11 which cooperates with a needle seat 12 formed on the injector body 2 or on the needle section 4 thereof. The needle tip 11 serves to control an injection of fuel through the at least one spray hole 5. In a closed position of the nozzle needle 9, the needle tip 11 sits in the needle seat 12 and thereby separates the at least one spray hole 5 from the feed path 7. When opening the nozzle needle 9, the needle tip lifts 11 from the needle seat 12 and thereby connects the at least one injection hole 5 with the feed path 7, whereby fuel passes through the at least one injection hole 5 in the injection chamber 6.

The injector 1 also comprises a control device 13, which is designed to control the pressure in a control chamber 38. The control device 13 can - as in the embodiments shown here - be equipped with a solenoid valve 14, the valve member 15 by means of an electromagnetic actuator 16 is actuated. Such a solenoid valve 14 is comparatively inexpensive to implement. Alternatively, the control device 13 may also be equipped with a piezo actuator.

The nozzle needle 9 has on its side remote from the needle tip 11 end face on a control surface 17 which limits the control chamber 38 axially. During operation of the injector 1, the pressure prevailing in the control chamber 38 causes a hydraulic force to be introduced into the control surface 17, specifically in the closing direction of the nozzle needle 9. A pressure drop in the control chamber 38 thus reduces the closing surface on the control surface 17 attacking hydraulic forces and thus can control the nozzle needle 9 to open.

The nozzle needle 9 is designed in one piece in the preferred example shown here and is made from the needle tip 11 to the control surface 17 in one piece. By this construction, the nozzle needle 9 as such leakage is free, since it contains in particular no low-pressure space. Particularly advantageous in the one-piece nozzle needle 9 is that it can be arranged in a needle chamber 18 of the injector body 2, through which the feed path 7 is passed. In this construction, the nozzle needle 9 is surrounded or lapped by the fuel under high pressure. Since the nozzle needle 9 is made in one piece, its functionality can be ensured even in this high-pressure environment. Alternatively, it is basically possible to assemble the nozzle needle 9 of several parts or components. For example, the individual components can be fastened to one another by pressing and / or shrinking connections. In this case, the individual components are firmly connected together in the assembled state, at least in the axial direction. Even with this design, it is in principle possible to design the multi-part nozzle needle 9 leak-free, whereby it can be used without further in a high-pressure environment.

In the embodiments shown in FIGS. 1 and 2, the nozzle shell 19 is in each case equipped with at least one joint section 19. Such a hinge portion 19 is characterized in that the nozzle needle 9 in him an increased flexibility or elasticity, whereby the nozzle needle 9 in the hinge portion 19 with respect to bending loads, which are oriented transversely to the longitudinal central axis 10 of the nozzle needle 9, more flexible than in adjacent thereto For example, such a hinge portion 19 may be formed by a constriction or taper in the diameter of the nozzle needle 9. However, the embodiment shown here in which each hinge section 19 has at least one straight web 20 is preferred. The respective web 20 extends radially with respect to the longitudinal central axis 10. In addition, the respective web connects 20 axially adjacent thereto axial sections of the nozzle needle 9 with each other. In the preferred variants shown here, the respective joint section 19 has two such webs 20. The webs 20 are axial Positioned spaced apart and oriented around the longitudinal central axis 10 offset by 90 ° to each other. The webs 20 can be produced for example by the fact that on the nozzle needle 9 in the region of the respective joint portion 19 on diametrically opposite sides two recesses 21 are incorporated, which are separated from each other by the respective web 20. The recesses 21 are then arranged mirror-symmetrically with respect to a plane of symmetry in which the longitudinal center axis 10 and the respective web 20 are located. In addition, the respective web 20 preferably extends over the entire diameter of the nozzle needle 9 in the region of the respective joint portion 19. In the region of such a joint portion 19, the nozzle needle 9 has increased flexibility with respect to bending stresses about bending axes, which are defined by the longitudinal axes of the webs 20 , As a result, the nozzle needle 9 in the respective hinge portion 19 bendable about said bending axes. By this construction, the nozzle needle 9 can compensate for positional tolerances between the nozzle needle 9 and an axial guidance of the nozzle needle 9, thereby reducing lateral loads and wear in the region of the axial guidance.

In the embodiments of FIGS. 1 and 2, for example in the needle section 4 of the injector body 2, such an axial guide 22 is formed, via which the nozzle needle 9 is mounted in the injector body 2 in the region of an end section 23 having the needle tip 11. To pass the feed path 7 through said axial guide 22, the nozzle needle 9 may be provided in said end portion 23 within the axial guide 22 with corresponding clearance surfaces 24, which are indicated in Fig. 2.

In the embodiment shown in FIG. 1, the nozzle needle 9 is also mounted in the region of an end portion 25 having the control surface 17 in a guide sleeve 26 by means of an axial guide 27. Said guide sleeve 26 forms a radial boundary of the control chamber 38 and is fixedly arranged on an intermediate plate 28, for. B. welded thereto or integrally formed thereon. On the one hand, the intermediate plate 28 forms an axial boundary of the control chamber 38 lying opposite the control surface 17. On the other hand, the intermediate plate 28 limits a coupling space 29 in the axial direction. Coupling space 29 and control chamber 38 are hydraulically coupled to each other through the intermediate plate 28 via a connection path 30, for example in the form of a throttled bore.

The embodiment shown in FIG. 1 has exactly two hinge portions 19. In this case, the one hinge portion 19 is formed in the needle tip 11 associated end portion 23, while the other hinge portion 19 in the control surface 17 associated end portion 25 is formed. In this respect, 19 position tolerances between the axial guide 27 of the guide sleeve 26 on the one hand and the axial guide 22 of the needle portion 4 on the other hand can be compensated on the hinge portions 19 in order to reduce the transverse forces occurring therein and the associated wear.

In the embodiment shown in Fig. 2, a sealing sleeve 31 is axially adjustably mounted on the nozzle needle 9 in the control surface 17 associated end portion 25, wherein also between the nozzle needle 9 and sealing sleeve 31 again an axial guide 32 is formed. The sealing sleeve 31 forms a radial boundary of the control chamber 38. The sealing sleeve 31 abuts axially on an intermediate plate 28, which also here on the one hand the control chamber 38 and on the other hand, a coupling space 29 axially limited. Again, there is a connection path 30 for hydraulic coupling between the coupling chamber 29 and the control chamber 38, which is passed through the intermediate plate 28. In the embodiment shown in Fig. 2, the nozzle needle 9 is provided with only one hinge portion 19 which is formed in the needle tip 11 associated end portion 23. An alignment between the nozzle needle 9 and the sealing sleeve 31 in the region of the control surface 17 associated end portion 25 is effected by the mobility of the sealing sleeve 31 transversely to the longitudinal center axis 10 along the intermediate plate 28 on which it rests.

In the embodiments of FIGS. 1 and 2, the injector 1 is also equipped with a closing compression spring 33. On the one hand, this is based on the guide sleeve 26 and on the embodiment shown in FIG the sealing sleeve 31. With the help of the closing compression spring 33, the nozzle needle 9 is biased in the closing direction.

In the embodiments shown here, the control device 13 is configured to control the pressure in the coupling space 29. By the hydraulic coupling For example, the coupling chamber 29 is connected to a relatively unpressurized return line 35, wherein a connection between the coupling chamber 29 and return 35 through the respective control device 13, for example by the valve member between coupling space 29 and control chamber 38 15, is controlled. When the nozzle needle 9 and closed connection between coupling space 29 and return 35 prevails in the coupling chamber 29 as well as in the control chamber 38, the same pressure as in the needle chamber 18, so the injection pressure of Zuführpfads 7. For this purpose, the control chamber 38 via a corresponding connection path 36, the z , B. can be realized by at least one throttled bore in the guide sleeve 26 and in the sealing sleeve 31, with the needle chamber 18, ie with the Zuführpfad 7. In addition, in the embodiment of FIG. 2, the coupling space 29 via a corresponding connection path 37th , z. B. in the form of a throttled bore, also communicate directly with the needle chamber 18, so with the Zuführpfad 7. As a result, to close the nozzle needle 9 in the coupling chamber 29, the required high pressure can be built up more quickly.

To open the nozzle needle 9, the connection between the coupling chamber 29 and return line 35 is opened, resulting in a pressure drop in the coupling space 29. The opening of said connection is effected by a corresponding actuation of the control device 13, thus in particular by a corresponding control of the solenoid valve 14, ie in particular by a corresponding stroke of the valve member 15. The pressure drop entering in the coupling chamber 29 propagates into the control chamber 38 and leads there a decrease in the control surface 17 acting on closing forces. As a result, acting on the nozzle needle 9, acting in the closing direction forces are greatly reduced, whereby the forces acting on the nozzle needle 9, acting in the opening direction of hydraulic forces predominate. As a result, the nozzle needle 9 lifts out of the needle seat 12 and the injection process begins. To close the nozzle needle 9, the connection between the coupling chamber 29 and return 35 is again blocked by a corresponding actuation of the control device 13 or by a corresponding control of the solenoid valve 14. About the connection paths 30, 36 and 37 may be in the control chamber 38 and in the coupling space 29 rebuild the injection pressure, so that the effective in the closing direction hydraulic Forces on the control surface 17 increase again and drive the nozzle needle 9 in the closing direction.

Claims (10)

Injector of a fuel injection system for an internal combustion engine, in particular in a motor vehicle, - With an injector body (2) having at least one injection hole (5) and in which a feed path (7) for supplying the at least one injection hole (5) is formed with standing under injection pressure fuel, with a nozzle needle (9) mounted in a stroke-adjustable manner in the injector body (2) and having a needle tip (11) for controlling an injection of fuel through the at least one injection hole (5), - with a control device (13) for controlling the pressure in a control chamber (38), - wherein the nozzle needle (9) has a control chamber (38) axially delimiting control surface (17) on which act in operation of the injector (1) in the closing direction of the nozzle needle (9) acting hydraulic forces, such that a pressure drop in the control chamber ( 38) controls the nozzle needle (9) to open, characterized,
in that the nozzle needle (9) has at least one articulated section (19) in which the nozzle needle (9) is more flexible in bending than in adjacent sections with respect to bending loads oriented transversely to the longitudinal center axis (10) of the nozzle needle (9). Injector according to claim 1,
characterized,
in that at least one of the hinge sections (19) has at least one rectilinear web (20) which extends radially with respect to the longitudinal center axis (10) of the nozzle needle (9) and which connects the axially adjacent axial sections of the nozzle needle (9). Injector according to claim 2,
characterized, - That the respective hinge portion (19) has at least two webs (20) which are axially spaced from each other, and which are arranged offset by 90 ° to each other about the longitudinal center axis (10) of the nozzle needle (9), and / or - That the respective web (20) extends over the entire diameter of the nozzle needle (9). Injector according to claim 2 or 3,
characterized,
that the respective web (20) is formed in that on the nozzle needle (9) has two recesses (21) are incorporated with respect to a plane of symmetry in which the longitudinal central axis (10) of the nozzle needle (9) and the web (20) are , are arranged mirror-symmetrically. Injector according to one of claims 2 to 4,
characterized, - that the nozzle needle (9) in the region of the needle tip (11) having end portion (23) in the injector body (2) is mounted with axial guide (22), - that the nozzle needle (9) in the region of the control surface (17) having end portion (25) in a guide sleeve (26) is mounted with axial guide (27), - That the guide sleeve (26) radially bounded the control chamber (38) and at an intermediate plate (28) is fixedly arranged, which limits the control chamber (38) axially, - That the nozzle needle (9) exactly two such joint portions (19), wherein the one hinge portion (19) in the needle tip (11) associated end portion (23) and the other hinge portion (19) in the control surface (17) associated End portion (25) is formed. Injector according to one of claims 2 to 4,
characterized, - that the nozzle needle (9) in the region of the needle tip (11) having end portion (23) in the injector body (2) is mounted with axial guide (22), in that a sealing sleeve (31) with axial guidance is mounted on the nozzle needle (9) in the region of an end section (25) having the control surface (17), - That the sealing sleeve (31) the control chamber (38) radially bounded and axially against an intermediate plate (28) which limits the control chamber (38) axially, - That the nozzle needle (9) has exactly one such joint portion (19) formed in the needle tip (11) associated end portion (23). Injector according to claim 5 or 6,
characterized,
that a closing pressure spring (33) is provided which is supported at one end on the nozzle needle (9) and on the other hand on the sealing sleeve (31) or on the guide sleeve (26) or on the intermediate plate (28). Injector according to one of claims 5 to 7,
characterized,
in that the control device (13) is designed to control the pressure in a coupling space (29) which is hydraulically coupled to the control chamber (38) and indirectly controls the pressure in the control chamber (38). Injector according to one of claims 1 to 8,
characterized, - That the nozzle needle (9) in one piece and from the needle tip (11) to the control surface (17) is made in one piece, or - That the nozzle needle (9) is assembled from at least two components which are axially fixed together. Injector according to one of claims 1 to 9,
characterized, - that the injector body (2) contains a needle chamber (18), in which the nozzle needle (9) is arranged, - That the feed path (7) through the needle chamber (18) is passed.

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