EP1026393A2 - Injector for the injection system of an internal combustion engine - Google Patents

Abstract

A fuel-injection unit injector includes a nozzle or jet body (700) having at least one outlet aperture (710) for injection of fuel into a combustion chamber of a combustion engine. The nozzle or jet needle (730) is axially displaceable in a central boring and either releases or interrupts the flow of fuel to the outlet aperture (710), depending on the axial position of the needle. A control unit (600) is arranged above the nozzle or jet (700), with a guide boring (620) provided for a transmission element (630,650) for transmission of the adjustment movement of an actuator (100) on to the jet needle (730). A high pressure channel (320,610) discharges into the space formed by the guide boring (620) and the jet or nozzle (700) boring.

Description

The invention relates to an injector according to the preamble of claim 1 for an injection system of an internal combustion engine.

Such injectors are generally known and usually exist of several modules arranged one above the other are, the individual modules braced axially against each other to each of the joints of neighboring modules to achieve a high pressure seal. The tension of the individual modules can, for example, by a union nut take place, which accommodates all modules of the injector and is screwed to the top of the injector head. Such injectors are under a high fuel pressure are operated and are used in particular in common rail systems used.

A module of the known injectors essentially consists from a nozzle body with outlet openings through which the Fuel being injected into a combustion chamber the internal combustion engine is injected. Between the injections the fuel flow to the outlet openings interrupted by a nozzle needle, which in the nozzle body is guided axially.

As a further module, a control unit is located above the nozzle body arranged in which the mechanical actuating movement an actuator is transferred to the nozzle needle to the outlet opening in the nozzle body depending on the To release or close the position of the actuator and thereby the injection of fuel by the actuator Taxes.

Fuel is supplied from the injection system through a high-pressure channel in the injector upper section essentially axially through the individual Module runs and finally in the nozzle body at the bottom End of the injector in a branch hole laterally in a Pressure chamber opens, from which the fuel to the Outlet openings flows.

However, a disadvantage of this guidance of the high-pressure duct is that that the nozzle body must be made relatively wide in order enough space for the high-pressure duct on the side Offer. The constructive design freedom for the nozzle body is in the known injectors through the guide of the high-pressure channel.

Another disadvantage of the known ones described above Injectors can be seen in the fact that at the mouth of the Tap hole in the pressure chamber of the nozzle body high notch stresses occur which the high pressure and swell strength of the nozzle body.

The invention is therefore based on the object of an injector to create a great high pressure and swell resistance having.

The invention is characterized by the characterizing features of the independent Patent claims resolved.

The invention includes the general technical teaching, the fuel in the lower part of the injector a separate high pressure duct, but via the already existing one lead central bore to the nozzle body, so that there is no separate high-pressure duct in this area can be. On the one hand, there is therefore the possibility to increase the wall thickness of the nozzle body to the To improve compressive strength. On the other hand, the Cross section of the nozzle body can be reduced to the design of the nozzle body to other design requirements adapt. In this way it is possible, for example, flatten the nozzle needle guide.

The high pressure channel therefore preferably opens above the Nozzle body in the area of the control unit in the side Guide hole of the control unit, which is connected to a corresponding Guide bore in the nozzle body connects so that the Fuel up to the outlet openings in the nozzle body can be forwarded. This makes the angle the High-pressure duct with the guide bore of the control unit, can be made enlarged, which increases the high pressure resistance in the area of the partition between the high pressure duct and the pilot hole increases.

The fuel is supplied in the lower area of the Injector preferably centered around the nozzle needle, wherein in the guide bore of the nozzle body preferably a nozzle needle guide is arranged, on the one hand, a mechanical Guidance of the nozzle needle causes and on the other hand forwarding of fuel in the axial direction between the nozzle needle and the wall of the guide hole. The Nozzle needle guide can for example consist of a hollow cylindrical Guide bushing exist in the wall axially continuous Channels or openings are arranged over which the Fuel is forwarded. In another variant of the Invention, however, the nozzle needle guide consists of several Webs arranged in the guide bore of the nozzle body are and protrude inwards, the webs on the Contact surface of the nozzle needle and this mechanically lead while the fuel in the grooves between the individual docks can be forwarded. The bridges can, however, also outside on the outer surface of the nozzle needle be molded and with their free ends on the outside of the inner wall the guide bore so that the fuel flow through the grooves between the individual webs can. In one embodiment of the invention, the Webs in the guide bore in the axial direction, which is advantageous simple and inexpensive manufacture of the nozzle needle guide enables. In another embodiment the webs, however, run spirally in the guide bore of the nozzle body or in the outer surface of the nozzle needle, which is more complex in terms of production technology, but one Scoring in the lateral surface of the nozzle needle or on the Inner wall of the guide hole or even seizing the Nozzle needle prevented. In addition, it is also possible a nozzle needle with a rectangular, preferably square Cross-section to use, the axially extending Edges of the nozzle needle on the outside of the inner wall of the guide bore fit and slide so that the fuel in Flow past the nozzle needle in the axial direction can.

The term control unit used above is in the scope to understand the invention in general and includes all modules above the nozzle body, alone or in conjunction with other modules, the actuation of the nozzle needle by the actuator enable. The high-pressure duct can therefore, for example even in a higher one within the injector Open module in the central hole, provided that Then fuel through the central bore up to the nozzle body can be continued. In the area below of the injector can be dispensed with a separate high pressure channel be, which increases the high pressure strength of the nozzle body is increased.

Due to the inventive leadership of the high pressure channel only down to the control unit, there are also no conventional ones Injectors occurring high notch voltages the mouth of the tap hole in the pressure chamber of the Nozzle body.

In addition, the guide of the high-pressure duct according to the invention offers sufficient in the lower area of the injector Space for a storage chamber during an injection process as a buffer for the injected Serves fuel. This will cause pressure drops when the nozzle is opened reduced and the resulting pressure waves damped.

The storage chamber can, for example, in the control unit are arranged by the guide hole in the control unit has a significantly larger cross section than that Push rod, which indirectly controls the control movement of the actuator transfers to the nozzle needle. Between the push rod and the wall of the guide hole then remains sufficient space for the temporary storage of fuel.

Instead, the storage chamber can also be located directly in the nozzle body be arranged, which has the advantage that the cached fuel mass closer to the outlet openings lies. In this case, the pilot hole points in the nozzle body a larger cross section than that Nozzle needle on so that sufficient to the side of the nozzle needle Space for the temporary storage of fuel remains.

Figur 1

als bevorzugtes Ausführungsbeispiel der Erfindung einen Injektor im Längsschnitt,

Figur 2

eine alternative Ausführungsform einer Düsennadelführung für den in Figur 1 dargestellten Injektor mit axial verlaufenden Stegen an der Innenseite der Führungsbohrung zur Führung der Düsennadel,

Figur 3

eine weitere erfindungsgemäße Ausführungsform einer Düsennadelführung für den in Figur 1 dargestellten Injektor mit spiralförmig verlaufenden Stegen zur Führung der Düsennadel,

Figur 4

eine erfindungsgemäße Ausführungsform einer Düsennadelführung mit außen an der Düsennandel angeformten Stegen sowie

Figur 5

ein weiteres Ausführungsbeispiel für eine erfindungsgemäße Düsennadelführung mit einem quadratischen Düsennadelquerschnitt.

Figur 6

ein weiteres Ausführungsbeispiel des Injektors aus Figur 1

Other advantageous developments of the invention are characterized in the subclaims or are shown in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. It shows:

Figure 1

as a preferred embodiment of the invention, an injector in longitudinal section,

Figure 2

2 shows an alternative embodiment of a nozzle needle guide for the injector shown in FIG. 1 with axially extending webs on the inside of the guide bore for guiding the nozzle needle,

Figure 3

1 shows another embodiment of a nozzle needle guide according to the invention for the injector shown in FIG. 1 with spirally extending webs for guiding the nozzle needle,

Figure 4

an embodiment of a nozzle needle guide according to the invention with webs formed on the outside of the nozzle needle and

Figure 5

a further embodiment for a nozzle needle guide according to the invention with a square nozzle needle cross section.

Figure 6

another embodiment of the injector of Figure 1

The injector shown in Figure 1 enables injection of fuel in a combustion chamber of an internal combustion engine and has several modules arranged one above the other 300, 400,500,600 and 700 with circular outer cross-section on, which are axially braced against each other high-pressure sealing at the joints of neighboring modules to reach. The bracing of the individual modules 300, 400,500,600 and 700 against each other is done by a Union nut that holds all modules 300, 400,500,600 and 700 and screwed to the top with an injector head is to which a fuel line from an injection system is connected, whereby to maintain clarity neither the union nut nor the injector head in the Drawing is shown.

A controllable actuator 100, preferably a piezoelectric one The actuator stands with a closing body 370 over a plunger 200 in operative connection. The plunger 200 is in a central Guide bore 310 of a servo body 300 out. The servo body 300 additionally has a fuel channel 320, a Return channel 330 and a central valve chamber 345.

The return channel 330 projects laterally into the guide bore 310 and is connected to a fuel tank. The pilot hole 310 goes over a conically opening first Valve seat 350 into the valve chamber 345. In the valve chamber 345, the closing body 370 is introduced, which together with the first valve seat 350 in the closed state forms a high pressure resistant seal. The closing body 370 is mushroom-shaped, the stem of the closing body 370 is surrounded by a valve spring 390 which is in the valve chamber 345 is arranged and on the closing body 370th exerts a spring force directed towards the first valve seat 350.

The valve chamber 345, the closing body 370, the valve spring 390 and the first valve seat 350 form a servo valve 340, which is actuated by the actuator 100 via the plunger 200. By opening the actuator 100 from the idle state the servo valve 340, creating a hydraulic connection (Drain) between the valve chamber 345 and the fuel tank via the guide bore 310 and the return channel 330 becomes. On the one opposite the guide bore 310 Side, the valve chamber 345 is a throttle body 400 limited to the servo body 300 in the axial direction connects.

The throttle body 400 has a fuel channel 430, one Drain channel 420 and an inlet channel 410 on the fuel channel 430 connects to the control chamber 440 and one Inlet throttle 415, which has the fuel flow in the control chamber 440 is restricted. The drain channel 420 points an outlet throttle 425 on that the fuel outflow from the Control chamber 440 limited.

The intermediate body axially adjoining the throttle body 400 500 has a central piston guide 510, in which in in the axial direction, a control piston 520 is guided, the Control piston 520 its axial deflection on a pressure piston 650 transmits that in a storage chamber Guide bore 620 in a control body 600 axially is slidably arranged and guided. The plunger 650 is preloaded by a spiral spring 660 and is thereby pressed down in the idle state. Furthermore the intermediate body 500 has a leakage line 550, led to the return channel 330 via the leakage liquid becomes.

The fuel channel 320 runs axially through the servo body 300, the throttle body 400, the intermediate body 500 and opens finally via a feed hole 610 in the control body 600 in the guide bore 620 which the fuel during of an injection process, so that in the lower area of the control body 600 no separate fuel channel as required in the upper modules of the injector.

This routing of the fuel channel 320 offers the advantage that the nozzle body 700 can be considerably narrower, since no space is required for the fuel channel on the side. The shape of the nozzle body 700 can therefore be freely adapted to others design requirements can be adjusted.

In addition, the guide bore 620 serves in the control body 600 as a storage chamber for the temporary storage of Fuel, which is what occurs with conventional injectors Pressure drops when opening the nozzle and following Pressure waves are largely avoided.

Starting from the intermediate body 500, the feed bore 610 first runs parallel to the guide bore 620, then angled in the direction of the guide bore 620 and cuts it at an angle a. The feed bore 610 consists of two bores which intersect in the control unit 600, one opening of which opens into the end face of the control unit 600 and the other of which opens into the guide bore 620 of the control unit 600.
The angled feed bore 610 is manufactured inexpensively by drilling from the upper end face of the control body 600 and the guide bore 620 of the control body 600. The greater the angle a, the greater the compressive strength of the control body 600 in the region of the intermediate wall between the feed bore 610 and the guide bore 620. The angle a is preferably in the range from 10 ° to 25 °.

A nozzle body 700 is located below the control body 600 arranged in a central bore in which a nozzle needle 730 is arranged axially displaceable, the nozzle needle 730 with a rigid push rod 630 in operative connection stands, which is firmly connected to the pressure piston 650. The Nozzle needle 730 is supported in a nozzle needle guide 740, arranged in the bore in the nozzle body 700 is, the nozzle needle guide 740 the bore cross section only partially closes, so that the fuel from the as Storage chamber serving guide bore 620 in the control body 600 through a guide recess 750 in the nozzle needle guide 740 and the bore in the nozzle body 700 at least an outlet opening 710 can flow through which the Fuel in the combustion chamber of the internal combustion engine with the nozzle open is injected.

The nozzle body 700 has a tapered valve seat 720 on that to the tapered tip the nozzle needle 730 is adapted so that the nozzle needle 730 and the valve seat 720 together form a valve that the Exit openings 710 depending on the axial position the nozzle needle 730 either releases or closes. An axially upward in the direction of the throttle body 400 Movement of the nozzle needle 740 opens the valve 720, 730; an opposite downward movement closes that Valve 720, 730. The nozzle needle 730 has changes in diameter on that by the fuel pressure an axial, of which second valve seat 720 directed restoring force on the Actuate nozzle needle 730.

In a further embodiment, the nozzle needle 730 forms one unit with the push rod 630 and the plunger 650, wherein the pressure piston 650 in the guide bore 620 of the Control body 600 is axially guided and not additionally in a nozzle needle guide 740 stored, which by manufacturing costs be reduced.

The following is the function of the injector shown described in detail, referring to the above description of the construction of the injector.

When the servo valve is opened, fuel flows from the valve chamber 345 via the return channel 330 into the fuel tank. Through the inlet throttle 415 and the outlet throttle 425 fuel flow is limited, so not enough Fuel can flow to the fuel pressure in the Hold control chamber 530. The reduced pressure in the control chamber 530 leads to a deflection of the nozzle needle 730 from second valve seat 720 away and thus at the beginning of the injection process. The actuator 100 pulls itself into its rest position the closing body 370 returns because of the pressure difference between the valve chamber 345 and the return passage 330 and because of the restoring force of the valve spring 390 at first Valve seat 350 back and interrupts the hydraulic Connection between the valve chamber 345 and the return channel 330 (closed position). It flows through the inlet throttle 415 Fuel from the fuel passage 320 into the control chamber 530 and the valve chamber 345, whereby the high pressure in the control chamber 530 is rebuilt. This will make the Nozzle needle 730 pressed onto the second valve seat 720 so that the injection process through the exit holes 710 ends becomes.

FIG. 2 shows a cross section through the nozzle body 700 in the height of the nozzle needle guide 740 along the line A-A Figure 1 with a further embodiment of the nozzle needle guide 740. For simplification, the same will be used in this illustration Reference numerals as used in Figure 1, so that largely reference can be made to the associated description. In contrast to the embodiment described above however, the nozzle needle guide 740 consists of a plurality of axially extending webs 760 on the nozzle body 700 are integrally formed in the guide bore and radially after protrude inside, so that the webs 760 inside on the outer surface the nozzle needle 730 and thereby the nozzle needle 730 lead while the fuel in the grooves 770 between the individual webs 760 in the axial direction to the outlet openings 710 can flow. The axial arrangement of the Stege 760 also offers manufacturing advantages, so that the nozzle needle guide 740 can be manufactured inexpensively.

Figure 3 shows a further embodiment of a nozzle needle guide 740, in which several webs 780 in the bore of the Nozzle body 700 protrude radially inward and thereby guide the 730 nozzle needle. In contrast to the one described above In this embodiment, the webs 780 run here however spiral in the guide bore, which is production-related is more complex, but a scoring or even seizing the nozzle needle 730 in the nozzle needle guide 740 largely prevented. The fuel flows here also spirally through grooves 790 between the individual webs 780 and thus passes the nozzle needle to the outlet openings 710. Alternatively, the spiral webs 780 also on the outside of the lateral surface of the Nozzle needle must be formed and with its free ends on the outside the inner wall of the guide bore, which is manufacturing technology is much easier.

FIG. 4 shows another embodiment in cross section a nozzle needle guide, which largely corresponds to that in FIG shown nozzle needle guide matches, so that in the Representation the same reference numerals are used. In contrast to the embodiment shown in Figure 2 A nozzle needle guide, however, the webs 760 are here on the outside molded on the outer surface of the nozzle needle 730 what manufacturing technology is much easier. The fuel however, this also flows in the axial direction into the Grooves 770 between the webs 760.

Figure 5 shows another embodiment of a Nozzle needle guide according to the invention, in which the nozzle needle 730 has a substantially square cross section, where the cross-sectional corners or the axially extending edges the nozzle needle 730 are flattened and outside on the inner wall the guide bore so that the fuel can flow laterally past the nozzle needle 730.

Figure 6 shows another embodiment, the difference 1 in the area of the control unit 600 High pressure channel 320,611,612 has in the control unit 600 runs essentially parallel to the guide bore 620 and in the area of the high pressure-resistant sealing surface, which by the end faces of the control unit 600 and of the nozzle body 700 is formed, in an inlet groove 612 opens out, which runs parallel to the high pressure-resistant sealing surface and above the nozzle needle 730 in the guide bore 620 or the bore of the nozzle body 700 opens. The inlet groove 612 is in the nozzle body and / or the control unit in Formed a longitudinal groove or of longitudinal grooves introduced and forms a fuel channel.

The introduction of a geometrically corresponding longitudinal groove 612 into the control unit 600 and the nozzle body is advantageous for the tightness of the sealing surface since the material of the nozzle body 700 and the control unit 600 when the fuel pressure changes stretches in the same ratio.

The invention is not limited in its execution the preferred embodiments given above. Rather, a number of variants are conceivable, which of the solution shown, even if fundamentally different Makes use of explanations.

Claims (18)

Injector for an injection system of an internal combustion engine, with a nozzle body (700) at least one outlet opening (710) for injecting fuel into a combustion chamber of the internal combustion engine and a central bore in which a nozzle needle (730) is axially displaceable, which either releases or interrupts the fuel flow to the outlet openings (710) depending on their axial position, a control unit (600) being arranged above the nozzle body (700) a guide bore (620) for a transmission element (630, 650) for transmitting the actuating movement of an actuator (100) to the nozzle needle (730) and a high pressure duct (320, 610, 611) which opens into the space formed by the guide bore (620) of the control unit (600) and the bore of the nozzle body (700). Injector according to claim 1,
characterized by
that the cross section of the guide bore (620) in the control unit (600) is at least in part of the length of the guide bore (620) substantially larger than the cross section of the push rod (630) in order to provide an intermediate buffer in the control unit (600) during the injection process serving storage chamber. Injector according to claim 1 or 2,
characterized by
that the cross section of the bore in the nozzle body (700) is at least in part of the length of the bore substantially larger than the cross section of the nozzle needle (730) in order to form in the control unit (600) a storage chamber which serves as an intermediate buffer during the injection process. Injector according to one of the preceding claims,
characterized by
that a partial cross section of the two guide bores (620) in the control unit (600) and in the nozzle body (700) remains free in order to supply fuel from the mouth of the high-pressure channel (320) in the control unit (600) through the two guide bores (620) to allow the outlet opening (710) in the nozzle body (700). Injector according to one of the preceding claims,
characterized by
that the guide bore (620) in the control unit (600) has the same cross section as the core cross section of the nozzle needle (730). Injector according to one of the preceding claims,
characterized by
that the cross section of the nozzle needle (730) is smaller than the cross section of the guide bore of the nozzle body (700), wherein a nozzle needle guide (740) is arranged in the guide bore of the nozzle body (700), which transmits fuel between the nozzle needle (730) and the wall of the guide bore of the nozzle body (700). Injector according to one of the preceding claims,
characterized by
that the nozzle needle guide (740) consists essentially of several webs (760, 780) which are arranged on the wall of the guide bore of the nozzle body (700) and protrude inwards, the fuel in the grooves (770, 790) between the webs (760, 780) can flow. Injector according to one of claims 3 to 6,
characterized by
that the nozzle needle guide (740) consists essentially of several webs, which are integrally formed on the outside of the nozzle needle (730) and rest with their free ends on the outside of the inner wall of the guide bore of the nozzle body, the fuel in the grooves (770, 790) between the webs (760, 780) can flow. Injector according to claim 7 or 8,
characterized by
that the webs (760) extend axially in order to enable simple manufacture. Injector according to claim 7 or 8,
characterized by
that the webs (780) run spirally to prevent scoring in the lateral surface of the nozzle needle (730) or in the inner wall of the guide bore of the nozzle body (700) or seizure of the nozzle needle (730) in the nozzle needle guide (740). Injector according to one of claims 3 to 6,
characterized by
that the nozzle needle (730) has a substantially rectangular cross section, the axially running edges of the nozzle needle (730) abutting the outside of the inner wall of the guide bore of the nozzle body (700), so that the fuel laterally in the axial direction on the nozzle needle (730) can flow past. Injector according to claim 11,
characterized by
that the axially extending edges of the nozzle needle (730) are flattened. Injector according to one of the preceding claims,
characterized by
that the outer cross section of the nozzle body (700) is significantly smaller than the outer cross section of the control unit (600). Injector according to one of the preceding claims,
characterized by
that the high pressure channel (320, 610, 611) opens into the guide bore (620) of the control unit (600). Injector according to one of the preceding claims,
characterized by
that the high-pressure channel (320, 610) is designed as a feed bore (610), which consists of two channels that intersect in the control unit (600), one opening in the end face of the control unit (600) and the other opening in the guide bore (620) of the control unit (600) opens. Injector according to claim 15,
characterized by
that the feed bore (610) intersects the guide bore (620) of the control unit (600) at an angle (a) which is in the range from 10 ° to 25 °. Injector according to one of claims 1 to 13
characterized by
that the high pressure channel has an inlet bore (611) and an inlet groove (612), the inlet groove is introduced into the nozzle body and / or the control unit, runs parallel to the abutting end faces of the nozzle body and the control unit and forms a channel between them, at one end the inlet bore opens and the other end of which opens into the guide bore (620) of the control unit (600) and / or the bore of the nozzle body (700). Injector according to claim 17,
characterized by
that the inlet bore runs essentially parallel to the guide bore (620) of the control unit (600).

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