WO2012163759A1 - Nozzle assembly for a fuel injector, and fuel injector - Google Patents

Abstract

The invention relates to a nozzle assembly for a fuel injector having a nozzle needle (1) which is guided with a reciprocating movement over at least one guide section (5, 6) in a high-pressure bore (2) of a nozzle body (3) for opening and closing at least one injection opening (4) and is loaded at least indirectly by the spring force of a closing spring (8), and having a restrictor-bore body (7) which is loaded by spring force in the axial direction. According to the invention, the restrictor-bore body (7) bears against the nozzle needle (1) and is loaded in the axial direction by the spring force of the closing spring (8). Furthermore, the invention relates to a fuel injector having a nozzle assembly of this type.

Description

 description

title

 The invention relates to a nozzle assembly for a fuel injector for injecting fuel into the combustion chamber of an internal combustion engine having the features of the preamble of claim 1. Furthermore, the invention relates to a fuel injector with such a nozzle assembly. State of the art

German Offenlegungsschrift DE 10 2009 001 704 A1 discloses a fuel injector for injecting fuel into a combustion chamber of an internal combustion engine with a generic nozzle assembly. The nozzle assembly comprises an axially adjustable injection valve element with a combustion chamber near

Section, which projects into a nozzle chamber, can flow into the fuel through a closing throttle. In order to provide a simple, tolerance and temperature-insensitive closing throttle formation and arrangement, the nozzle assembly further comprises a spring-loaded in the axial direction sleeve or disc, which is penetrated by the injection valve element and at least one throttle opening forming the closing throttle.

Based on the above-mentioned prior art, it is an object of the present invention to provide a functional and production-optimized nozzle assembly, in particular for directly switched diesel injection injectors.

The object is achieved by a nozzle assembly having the features of claim 1. Advantageous developments of the invention are specified in the subclaims. To solve the problem, a fuel injector with the features of claim 10 is also proposed. Disclosure of the invention

The proposed nozzle assembly comprises a nozzle needle, which is guided in a high-pressure bore of a nozzle body for releasing and closing at least one injection opening via at least one guide portion and at least indirectly acted upon by the spring force of a closing spring, and a spring-loaded in the axial direction throttle bore body. According to the invention, the throttle bore body bears against the nozzle needle and is acted upon in the axial direction by the spring force of the closing spring. The throttle body is thus biased axially corresponding to the nozzle needle in the closing direction, so that it requires only a closing spring for biasing the nozzle needle and throttle body. The spring force of the closing spring is transmitted via the throttle bore body to the nozzle needle. The closing spring is preferably received in a first pressure chamber, which is in communication with a high pressure source. The throttle bore body separates the first pressure chamber from a second pressure chamber, which communicates with the at least one injection port. Both pressure chambers are in turn connected via at least one throttle bore in the throttle bore body. The at least one throttle bore has the effect that in the first pressure chamber, a hydraulic pressure pi and in the second

Pressure chamber act a hydraulic pressure p ₂ , where pi> p ₂ . The hydraulic pressure i thus causes an additional hydraulic closing force, which supports the function of the closing spring. Preferably, the throttle bore body is formed like a piston and has an outer diameter D _1; which is larger than the outer diameter D _{2 of} the nozzle needle in the contact area with the throttle bore body. Due to the larger outer diameter, hydraulic active surfaces Ai and A ₂ are preferably formed on both end faces of the piston-like throttle bore body, which delimit the two pressure chambers, via the latter

Size ratio can be effected in the axial direction of an effective hydraulic force, which additionally acts on the throttle bore body including the nozzle needle. The ratio is preferably chosen such that the hydraulic effective area Ai delimiting the first pressure chamber is greater than the hydraulic effective area A ₂ delimiting the _second pressure chamber. The throttle bore body further has at least one throttle bore, which is preferably designed as an axial bore. An axial bore has the advantage over other throttle designs, such as inclined bores, that it has a lower temperature sensitivity. The formation of at least one throttle bore as an axial bore is possible because the outer diameter Di of the piston-like throttle body is greater than the outer diameter D _{2 of} the nozzle needle.

Furthermore, it is proposed that the throttle bore body cooperate to guide the nozzle needle with a guide portion of the nozzle body. In addition to a first guide portion, which is preferably formed as a stepped bore in the nozzle body high pressure bore and cooperates with a portion of the nozzle needle having an enlarged diameter, the throttle bore body can cooperate with an axially spaced from the first guide portion formed second guide portion. The leadership of the nozzle needle can be optimized so that the axial distance between the two guide sections is selected as large as possible. According to one embodiment of the invention, the throttle bore body is located not only on the nozzle needle, but is integrally connected to the nozzle needle. The connection can be made for example by means of laser welding. In addition, alternatively or additionally, a non-positive or positive connection can be provided. The one-piece connection of the throttle bore body with the nozzle needle, the assembly of the nozzle assembly can be simplified because fewer components are to be inserted into the nozzle body. The centering of the nozzle needle is preferably carried out via the guide sections. According to a further preferred embodiment of the invention, the throttle bore body is penetrated by the nozzle needle, wherein the throttle bore body penetrating portion of the nozzle needle has an outer diameter D ₃ , which is smaller than the outer diameter D _{2 of} the nozzle needle. The ratio of the outer diameter D ₃ <D ₂ ensures a hydraulic effective area ratio Ai> A ₂ and thus an additional hydraulic force acting in the axial direction. By the nozzle needle through the throttle bore body through sets, the nozzle needle can be connected directly or indirectly via a plunger body with an actuator for actuating the nozzle needle. For example, the actuator may have an actuator ram, which is supported directly or indirectly on the nozzle needle.

Advantageously, the portion of the nozzle needle passing through the throttle body is a plunger body integrally connected to the nozzle needle. The connection can be made for example by means of laser welding. Alternatively or additionally, a non-positive and / or positive connection can be selected. In the integrally connected to the nozzle needle plunger body may be the Aktorstößel or operatively connected to the Aktorstößel further plunger body. Since usually the outer diameter of the Aktorstößels is smaller than the outer diameter D _{2 of} the nozzle needle is selected to effect a gain of the actuator force, it is further ensured that the hydraulic effective area ratio at the throttle body A- _\ A ₂ is greater. In conventional, especially directly connected injectors, actuator plunger and nozzle needle are usually designed as two components, which must be assembled consuming during assembly. The proposed one-piece design therefore makes assembly easier.

According to an alternative embodiment of the invention, it is provided that the portion of the nozzle needle passing through the throttle bore body or the plunger body integrally connected to the nozzle needle is mounted radially floating in the throttle bore body. By the radially floating bearing bending loads on the nozzle needle or the plunger body can be prevented, which can be initiated for example due to lack of coaxiality of the components during assembly of the nozzle assembly in the nozzle needle or the plunger body. The radially floating mounting can take place, for example, by providing an annular gap between the throttle bore body and the section of the nozzle needle or the plunger body passing through the throttle bore body. Preferably, the annular gap has a maximum outer diameter which is smaller than the outer diameter D _{2 of} the nozzle needle. The annular gap is thus covered by an end face or a radially extending shoulder of the nozzle needle. In radially floating storage of the nozzle needle in Drosseibohrungskörper is possibly no longer sufficient guidance of the nozzle needle guaranteed. In order to ensure a further guidance or centering of the nozzle needle, it is proposed according to a development that the section of the nozzle needle or the tappet body passing through the nozzle bore body is centered via an intermediate disk axially attached to the nozzle body. Preferably, the washer has an annular centering portion received in the nozzle body to facilitate assembly of the nozzle assembly. To the intermediate disc, a holding body is preferably attached axially and clamped axially with the nozzle body via a nozzle retaining nut. Alternatively, instead of the intermediate disk, the holding body may also be provided with an annular centering section, so that the assembly of nozzle assembly and holding body is simplified when the intermediate disk is omitted.

The fuel injector for injecting fuel into the combustion chamber of an internal combustion engine which has been proposed for solving the problem posed in the introduction comprises a nozzle assembly according to the invention and an actuator assembly for actuating the nozzle needle. Preferably, the nozzle needle via the Aktorbaugruppe is directly operable. Direct actuation of the nozzle needle is understood here to mean an actuation in which the actuator force, for example via a hydraulic coupler, is possibly amplified. The proposed nozzle assembly allows a fuel injector which is particularly compact in the axial direction and is also easy to assemble. Furthermore, the functions guide / centering of the nozzle needle, closing throttle, sealing of the pressure chambers before / after the closing throttle and / or support of the spring force can be realized by a simple and therefore cost-effective component. The component may have a throttle stepping for different application areas and be maintained according to the principle of a modular system. To assemble the component, the nozzle needle is connected to the plunger body and the closing spring and the Drosseibohrungskörper pushed onto the plunger body. Thereafter, the plunger body is inserted into the washer or a holding body. Finally, the nozzle body is connected to the intermediate disc and / or the holding body via a nozzle retaining nut. Preferred embodiments of the invention are explained below with reference to the accompanying drawings. These show:

1 shows a longitudinal section through a first nozzle assembly according to the invention and

Figure 2 is a partial longitudinal section through a second nozzle assembly according to the invention. Detailed description of the drawings

The nozzle assembly shown in Figure 1 comprises a nozzle needle 1, which is guided in a high-pressure bore 2 of a nozzle body 3 in a liftable manner. By way of the lifting movement of the nozzle needle 1, at least one injection opening 4 can be opened and closed, above which it is at high pressure

Fuel in the combustion chamber of an internal combustion engine (not shown) can be injected. The nozzle needle 1 is actuated via an actuator assembly, not shown. Preferably, the actuation of the nozzle needle 1 is carried out directly, possibly with the interposition of a hydraulic coupler. The actuator assembly may include, for example, a magnetic actuator or a piezoelectric actuator.

To guide the nozzle needle 1, two guide sections 5, 6 are formed in the nozzle body 3, which cooperate leading with corresponding portions of the nozzle needle 1. In the region of the guide section 5, which is formed in the vicinity of a nozzle seat 13, the nozzle needle 1 has a section with an enlarged diameter, via which the nozzle needle 1 is guided in the guide section 5. The enlarged diameter portion of the nozzle needle 1 has outer peripheral side polished portions to form flow passages for the fuel. The polished sections are preferably uniformly distributed over the circumference of the nozzle needle 1. Another guide section 6 is arranged at an axial distance from the guide section 5. Here, the guide section 6 cooperates with a throttle bore body 7, which is supported on a radially extending shoulder of the nozzle needle 1. The throttle bore body 7 has an outer diameter Di, which is greater than the outer diameter D _{2 of} the nozzle needle 1 in the contact region with the throttle body 7 is. As a result, the guiding function of the throttle body 7 is ensured.

According to an alternative embodiment of the invention, the throttle bore body 7 may also be formed integrally with the nozzle needle 1. The throttle body 7 is then formed by an enlarged diameter portion of the nozzle needle 1 or a throttle body 7 integrally connected to the nozzle needle 1. The compound can be chosen such that a force, shape and / or material bond is effected.

In the throttle bore body 7, at least one throttle bore 9 designed as an axial bore is formed. By way of the at least one throttle bore 9, a first pressure chamber, which is in communication with an inlet bore 16, and a second pressure chamber, which is in communication with the at least one injection aperture 4, are hydraulically connected in such a manner that the hydraulic fluid flows

Pressure pi in the first pressure chamber is greater than the hydraulic pressure p ₂ in the second pressure chamber. The hydraulic pressure pi in the first pressure chamber thus causes a force acting in the closing direction of the nozzle needle 1 on the throttle body 7 force, which acts to assist the needle closure. The effect can be further enhanced by the hydraulic active surfaces formed on the throttle body 7. In the present case, the active hydraulic surfaces are designed in such a way that the hydraulic effective area delimiting the first pressure chamber is greater than the hydraulic effective area A ₂ delimiting the second pressure chamber. In the closing direction of the throttle bore body 7 is further acted upon by the spring force of a closing spring 8, on the one hand on the throttle bore body

7 on the other hand on a holding body 15 and an arranged between the holding body 15 and the nozzle body 3 intermediate disc 1 1 is supported. In the intermediate disc 1 1 or in the holding body 15 and the inlet bore 16 is formed, which connects the first pressure chamber with a high-pressure source. The intermediate plate 1 1 and the holding body 15 is axially attached to the nozzle body 3 and with this via a nozzle retaining nut (not shown) axially braced. The abutting end faces form sealing surfaces 14, via which the first pressure chamber is sealed against high pressure in relation to the environment. The second guide portion 6 extends substantially to the sealing surfaces 14 in order to ensure the largest possible axial distance between the two guide sections 5, 6, whereby the guide of the nozzle needle. 1 is optimized. The guide portion 6 is limited only by the fact that the recorded in the first pressure chamber closing spring 8 limits the stroke of the throttle body 7. The throttle body 7 is penetrated by a plunger body 10 which is integrally connected to the nozzle needle 1. The connection 18 may in turn be a positive, positive and / or cohesive connection 18. The plunger body 10 has an outer diameter D ₃ , which is smaller than the outer diameter D _{2 of} the nozzle needle 1 is selected. This ensures a hydraulic effective area ratio Ai> A ₂ . The plunger body 10 serves the

Active connection of the nozzle needle 1 with the actuator assembly, not shown, wherein the active compound can also be produced via a coupler body and / or a coupler volume. In the embodiment of a nozzle assembly according to the invention shown in Figure 1, the functions guide / centering, closing throttle, sealing the pressure chambers before / after the closing throttle and support the spring force in a single component realized. This component is also easy and inexpensive to produce. Furthermore, the assembly of the nozzle assembly is simplified. Over the two axially spaced guide portions 5, 6 an optimal guidance of the nozzle needle 1 in the nozzle body 3 is ensured. Furthermore, the hydraulic active surfaces Ai and A ₂ formed on the throttle body 7 cause due to their size ratio an additional hydraulic force acting in the axial direction. The same applies with respect to the at least one throttle bore formed in the throttle body 7 7, which is preferably designed as an axial bore. In this way, a function and production optimized nozzle assembly is created.

FIG. 2 shows a modification of the embodiment of FIG. 1. In contrast to the embodiment of Figure 1, in the present case, the nozzle needle 1 and the throttle bore body 7 are designed as separate components. This allows a radially floating mounting of the nozzle needle 1 in the region of the guide section 6. Due to the radially floating mounting of the nozzle needle 1, a bending stress of the nozzle needle 1 is avoided in the absence of coaxiality of the components zueinan-. Also in the embodiment of Figure 2, the nozzle needle 1 is integrally connected to a plunger body 10, wherein the plunger body 10 further is received in the washer 1 1 and the holding body 15. The nozzle needle 1 thus experiences on the integrally connected plunger body 10, a further guide or centering, which can lead to a bending stress of the nozzle needle 1 in the absence of coaxiality of the components plunger body 10, nozzle needle 1 and throttle bore body 7. This can be counteracted by the nozzle needle 1 or the plunger body 10 integrally connected to the nozzle needle 1 being mounted radially floating in the throttle bore body 7. For radially floating mounting of the nozzle needle 1 and the plunger body 10, an annular gap 17 is formed in the throttle body 7 in the present case. The annular gap 17 is covered to the side of the second pressure chamber by an annular end face of the nozzle needle 1, so that no additional flow channel is provided, via which fuel can flow from the first pressure chamber into the second pressure chamber. To facilitate the centering of the nozzle needle 1 and the plunger body 10, an annular centering 12 is formed on the washer 1 1 and on the holding body 15, with which the washer 1 1 and the holding body 15 is inserted into the high-pressure bore 2 of the nozzle body 3 can be. In this respect, a guide or centering of the nozzle needle 1 is further ensured in a seat remote area on the washer 1 1 and the holding body 15.

Claims

claims

1 . Nozzle assembly for a fuel injector with a nozzle needle (1) which in a high-pressure bore (2) of a nozzle body (3) for releasing and closing at least one injection opening (4) via at least one guide portion (5, 6) guided in a liftable and at least indirectly by the spring force a closing spring (8) is acted upon, and a spring-loaded in the axial direction Drosseibohrungskörper (7),

characterized in that the Drosseibohrungskörper (7) against the nozzle needle (1) and in the axial direction of the spring force of the closing spring (8) is acted upon.

2. Nozzle assembly according to claim 1,

characterized in that the Drosseibohrungskörper (7) is piston-like and has an outer diameter D ₁ , which is greater than the outer diameter D ₂ of Düsennadei (1) in the contact area with the Drosseibohrungskörper (7).

3. Nozzle assembly according to claim 1 or 2,

characterized in that the Drosseibohrungskörper (7) has at least one throttle bore (9), which is designed as an axial bore.

4. Nozzle assembly according to one of the preceding claims,

characterized in that the Drosseibohrungskörper (7) for guiding the nozzle needle (1) with a guide portion (6) of the nozzle body (3) cooperates.

5. Nozzle assembly according to one of the preceding claims,

characterized in that the Drosseibohrungskörper (7) with the Düsennadei (1) is integrally connected.

6. Nozzle assembly according to one of the preceding claims,

characterized in that the throttle bore body (7) is penetrated by the nozzle needle (1), wherein the throttle bore body (7) passing through section of the nozzle needle (1) has an outer diameter D ₃ , which is smaller than the outer diameter D _{2 of} the nozzle needle (1). is.

7. Nozzle assembly according to one of the preceding claims,

characterized in that the throttle bore body (7) passing through the portion of the nozzle needle (1) is a plunger body (10) which is integrally connected to the nozzle needle (1).

8. nozzle assembly according to claim 6 or 7,

characterized in that the throttle body (7) passing through the section of the nozzle needle (1) or the plunger body (10) radially floating in the throttle body (7) is mounted.

9. nozzle assembly according to any one of claims 6 to 8,

characterized in that the portion of the nozzle needle (1) or the plunger body (10) passing through the throttle bore body (7) is centered via an intermediate disc (11) mounted axially on the nozzle body (3), preferably one in the nozzle body (3). has received annular centering portion (12).

10. Fuel injector for injecting fuel into the combustion chamber of an internal combustion engine with a nozzle assembly according to any one of the preceding claims and an actuator assembly for actuating the nozzle needle (1), wherein the nozzle needle (1) via the Aktorbaugruppe is preferably directly operable.