EP1406006A1 - Fuel injection valve - Google Patents

Abstract

The device has a piezoelectric or magnetostrictive actuator (2) that actuates a valve closure body (22) on a valve needle (15) via a hydraulic coupler (10). The closure body interacts with a valve seat surface (23) to form a seal seat. The coupler has sender and receiver pistons (9,12) in a guide sleeve (13) and separated by a coupler gap (11). The sender piston (9) and/or receiver piston (12) have a choke bore (19) forming a filling valve (18) for the coupler gap together with a valve body (20) and a valve seat (21).

Description

State of the art

The invention is based on a fuel injector according to the genus of the main claim.

EP 0 477 400 A1 describes an arrangement for an in Adaptive mechanical acting stroke direction Tolerance compensation for a displacement transformer piezoelectric actuator for a fuel injector known. The actuator acts on a master piston that is connected to a hydraulic chamber. About the Pressure increase in the hydraulic chamber becomes a slave piston which moves a mass to be driven, to be positioned emotional. This mass to be driven is, for example Valve needle of a fuel injector. The The hydraulic chamber is filled with a hydraulic fluid. With an expansion of the actuator and compression of the Hydraulic fluid in the hydraulic chamber flows a little Part of the hydraulic fluid with a defined leak rate. In the resting phase of the actuator, this hydraulic fluid added.

DE 195 00 706 A1 describes a hydraulic one Known displacement transformer for a piezoelectric actuator, where a master piston and a slave piston in one common axis of symmetry are arranged and the Hydraulic chamber is arranged between the two pistons. In the hydraulic chamber, a spring is arranged, which Pushes master cylinder and slave piston apart, whereby the master piston in the direction of the actuator and the slave piston in one working direction towards a valve needle be biased. If the actuator is on the master cylinder transmits a lifting movement, this lifting movement is carried out by the Pressure of a hydraulic fluid in the hydraulic chamber on the Transfer slave piston because the hydraulic fluid in the Hydraulic chamber can not be compressed and only one low proportion of hydraulic fluid due to annular gaps between master piston and a guide bore and Slave piston and a pilot hole during the short Period of a stroke can escape.

In the idle phase when the actuator does not exert any pressure on the Master cylinder exerted by the spring of the master piston and the slave piston pressed apart. By the The resulting negative pressure penetrates through the annular gap Hydraulic fluid in the hydraulic chamber and fills it back on. As a result, the path transformer turns up automatically on linear expansion and pressure-related Strains of a fuel injector.

A disadvantage of this known prior art is that during a discharge period in which Hydraulic chamber there is no high pressure Hydraulic fluid can evaporate. However, there is a gas compressible and builds only with a strong one Volume reduction a correspondingly high pressure. The Master cylinder can now be pressed into its guide hole be, without there being a power transmission to the Master piston comes.

This is particularly dangerous with a Fuel injector used to inject gasoline serves as fuel when the gasoline also serves as Hydraulic fluid is used. This danger is increased again a direct injection fuel injector for Petrol after turning off a hot internal combustion engine. The fuel injection system now loses its pressure. It the gasoline evaporates particularly easily. At a This can be done by restarting the internal combustion engine cause that the stroke movement of the actuator no longer on a Valve needle is transmitted and the fuel injector not working.

A further disadvantage is that cavitation of the Fuel can come when the spring has a high tension exercises on the master cylinder and slave cylinder and the Movement of the actuator to its starting position very quickly he follows. The negative pressure that forms in the hydraulic chamber can then lead to cavitation and the resulting damage lead on components.

Advantages of the invention

The fuel injector according to the invention with the has characteristic features of the main claim in contrast, the advantage that a filling valve, which a Throttle bore in a master piston or slave piston of the hydraulic coupler, a valve seat and one with it cooperating valve body includes the fast Filling the coupler gap between the encoder and the Slave piston allows without the above mentioned disadvantages arise.

By the measures listed in the subclaims advantageous developments and improvements in Main claim specified fuel injector possible.

The valve body is advantageously in one with the Actuator in non-positive connection Gimbaled actuator so that offsets can be compensated.

The throttle bore ensures that the Coupler gap can be filled quickly enough without too much pressure of the hydraulic medium to one unintentional opening of the fuel injector can lead.

The valve seat is ring-shaped in a simple manner and can on the valve body or on the encoder or Slave piston be arranged.

In a further advantageous embodiment, the Sealing seat of the filling valve on the slave piston and the Valve body on the valve needle of the Fuel injector trained. This is a very simple and therefore inexpensive variant of the Filling valve.

The master and slave pistons of the hydraulic coupler are advantageously hollow cylindrical, which reduces their mass and the switching dynamics of the Fuel injector is positively influenced.

drawing

Fig. 1

eine schematische Darstellung des abspritzseitigen Teils eines ersten Ausführungsbeispiels eines erfindungsgemäßen Brennstoffeinspritzventils;

Fig. 2

ein zweites Ausführungsbeispiel eines erfindungsgemäßen Brennstoffeinspritzventils entsprechend einer Variante im Bereich II in Fig. 1; und

Fig. 3

eine schematische Darstellung des mittleren Teils eines dritten Ausführungsbeispiels eines erfindungsgemäßen Brennstoffeinspritzventils.

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description. Show it:

Fig. 1

a schematic representation of the spray-side part of a first embodiment of a fuel injector according to the invention;

Fig. 2

a second embodiment of a fuel injector according to the invention according to a variant in area II in Fig. 1; and

Fig. 3

is a schematic representation of the middle part of a third embodiment of a fuel injector according to the invention.

Fig. 1 shows a schematic section through the spray-side part of a first embodiment of a fuel injector 1 according to the invention.

The fuel injection valve 1 comprises an actuator 2, which is preferably a piezoelectric actuator 2 is trained. The actuator 2 is to protect against Tensile load and chemical influence of the fuel in encapsulated a sleeve 3. That from the sleeve 3, the actuator 2 and one clamped in the sleeve 3 against the actuator 2 Preload spring 4 existing component can be pre-assembled and then into a housing 5 of the fuel injection valve 1 be introduced. The fully assembled component is through a support ring 6 fixed in the housing 5.

An actuating element 7 on which the actuator 2 supports, reaches through the sleeve 3 in one Actuating direction of the actuator 2. The actuating element 7 and the sleeve 3 are against by means of a corrugated tube seal 8 flowing through the fuel injector 1 Fuel sealed. The actuating element 7 extends into a master piston 9 of a hydraulic coupler 10 of the fuel injector 1. The master piston 9 is executed hollow cylindrical, which in particular the Advantage of saving weight and resulting one has better switching dynamics of the fuel injector 1.

Downstream of the master piston 9 is forming a Coupler gap 11 is arranged a slave piston 12, which also to improve the switching dynamics in hollow cylindrical shape is executed. The components of the hydraulic coupler 10 are in a guide sleeve 13 arranged, which by means of a compression spring 14 relative to the Master piston 9 is clamped. The hydraulic coupler 10 can effect a stroke ratio depending on the requirement, as is the case in the illustrated embodiment , or only implement the stroke of actuator 2 1: 1. As Hydraulic medium is used in the embodiment of the Fuel injector 1 flowing fuel.

A valve needle 15 is connected to the slave piston 12 non-positively connected. It extends into Outflow direction in a valve group 16, which in any, the requirements of that Fuel injector 1 of sufficient type can.

A valve closing body 22 is located on the valve needle 15 formed, which with a valve seat 23 to a Sealing seat interacts. A closing spring 24 acts the valve needle 15 against an outflow direction, so that the fuel injector 1 in the non-excited state of the Actuator 2 is kept closed.

In the first embodiment shown in FIG. 1 is the fuel injector 1 in the form of an outward opening fuel injector 1 executed. The Valve group 16 can, for example, by means of a Union nut 17 on the housing 5 of the Fuel injector 1 must be fixed. The valve group 16 is located in a nozzle body 26 through a Seal 27 against a cylinder head, not shown is sealed. Connects to the nozzle body 26 on the inlet side to a flange 28, which by means of a seal 29 is sealed against the housing 5. One between the Union nut 17 and the flange 28 inserted Adjustment disc 30 is used to adjust the width of the Coupling gap 11.

According to the invention, the hydraulic coupler 10 has a Filling valve 18, which for the rapid filling of the Coupling gap 11 when operating the fuel injector 1 cares. The filling valve 18 is in the embodiment from a throttle bore 19 in the master piston 9 and one Valve body 20 in the actuator 7, which the Throttle bore 19 in the closed state of the filling valve 18 covers. The valve body 20 has an annular Valve seat 21, which is turned off, for example the valve body 20 can be produced. Throttle bore 19 can alternatively or additionally also in the slave piston 12 be trained.

Due to the special shape of the valve body 20 in Partial spherical shape with a corresponding guide in one spherical recess 25 in the actuating element 7 becomes a gimbal mounting of the valve body 20 achieved which can serve to offset the actuating element 7 compensate. In this way, malfunctions of the Filling valve 18 due to manufacturing tolerances or thermal Processes excluded.

The filling valve 18 is when the Fuel injector 1 is actuated when the actuator 2 contracts. If the actuator 2 is no longer a Applied to excitation voltage, it pulls quickly together so that the valve needle 15 and the slave piston 12 and the master piston 9, which over the Actuating element 7 is actuated by the actuator 2, the Follow actuator 2 movement. The actuator 7 with the valve body 20 arranged therein lifts from the annular valve seat 21, so that fuel in the Coupler gap 11 flows and which during the operation of the Fuel injection valve 1 occurring leakage loss is balanced. The filling of the coupler gap 11 by the throttle bore 19 continues until the Compression spring 14 again against the master piston 9 Valve body 20 presses and the throttle bore 19 is closed becomes.

The quick fillability of the coupler gap 11 contributes to this an improved switching dynamics of the Fuel injector 1 at. The filling can take place considerably faster than through leakage gaps.

The fact that the filling is faster than the Leakage gap occurs, but through the throttle bore 19 is throttled, this can be prevented Fuel injector 1 during the reverberation of the Actuator 2 opens again unintentionally.

Characterized in that the master piston 9 via the throttle bore 19th can also form an air cushion in the Assembly of the hydraulic coupler 10 can be avoided because the air can escape immediately through the throttle bore 19. The air is removed via the leakage gap usually very slowly.

Fig. 2 shows a second embodiment of a Fuel injection valve 1 according to the invention in area II 1. Components already explained in FIG. 1 are provided with the same reference numerals. The cutout shows the area of the hydraulic coupler 10 with the Master piston 9 and slave piston 12.

In contrast to the first shown in Fig. 1 Embodiment in which the valve seat 21 of the Filling valve 18 on the valve body 20 of the filling valve 18 is formed, the valve seat 21 is in the position in FIG. 2 illustrated second embodiment now on the master piston 9 in the form of an annular, the throttle bore 19th surrounding essay trained. It is advantageous in particular the simple design of the valve body 20 of the filling valve 18, which is approximately spherical is formed and thus also in a simple manner enables offset gimbal guidance. The mode of operation corresponds to that in the description of FIG. 1 already explained above has been.

Fig. 3 shows a third embodiment of a Fuel injector according to the invention 1. Already in 1 and 2 components are explained with the same Provide reference numerals. The section shows the area of the hydraulic coupler 10 with the master piston 9 and Slave piston 12.

In contrast to those shown in Figs. 1 and 2 Embodiments in which the filling valve 18 in Shape of a spherical valve body 20 with a Valve seat 21 is formed, the filling valve 18 is now with the valve needle 15 and one on the slave piston 12 trained valve seat 21. The valve body 20 is formed in one piece with the valve needle 15 and has lateral surface grindings 33. It is advantageous in particular the simple design of the valve body 20 the filling valve 18.

The principle of operation of refilling the coupler gap 11 is analogous to that of the above described embodiments, the operation of the Filling valve 18, however, has differences.

When actuating actuator 2, it presses over the Actuator 7, the master piston 9 of the hydraulic Coupler 10 in the outflow direction of the fuel. The Master piston 9 indicates this movement via the coupler medium the slave piston 12 further. Since the valve needle 15 in Valve seat 21 abuts the slave piston 12, that will Fuel injector 1 thereby opened.

During this process, the coupler gap 11 is emptied, the coupler gap 11 between the master piston 9 and slave piston 12 so smaller. Pulls off after injection Fuel from the fuel injector 1 through Shutdown of the excitation of the actuator 2 Actuator 7 back during the closing movement, lifts the valve needle 15 from the sealing seat 21 of the slave piston 12. By the force of one between the master piston 9 and the Slave piston 12 arranged disc spring 31 is the Refill the coupler gap 11 with coupler medium initiated. Fuel flows over the Surface grindings 33 on the valve needle 15 and on the Valve needle 15 formed valve body 20 over and through the filling hole 19 into the coupler gap 11. As soon as the valve needle 15 in the sealing seat 21 is the Refill completed.

The valve needle 15 is during the closing process by the closing spring 24, which is between the Nozzle body 26 and one formed on the valve needle 15 Flange 32 is clamped again in the sealing seat 21 pressed and the fuel injector 1 thereby closed.

The invention is not shown on the Embodiments limited and also for any other designs of fuel injection valves 1 are suitable. In particular, any combination of the individual Features possible.

LIST OF REFERENCE NUMBERS

1

Fuel injector

2

actuator

3

shell

4

biasing spring

5

casing

6

support ring

7

actuator

8th

Bellows seal

9

master piston

10

hydraulic coupler

11

coupler gap

12

slave piston

13

guide sleeve

14

compression spring

15

valve needle

16

valve group

17

Nut

18

Filling

19

throttle bore

20

valve body

21

valve seat

22

Valve closing body

23

Valve seat

24

Return spring

25

recess

26

nozzle body

27

poetry

28

flange

29

poetry

30

Focusing

31

Belleville spring

32

flange

33

Flächenanschliffe

Claims (14)

Fuel injection valve (1), in particular fuel injection valve (1) for fuel injection systems of internal combustion engines, with a piezoelectric or magnetostrictive actuator (2) which actuates a valve closing body (22) formed on a valve needle (15) via a hydraulic coupler (10) Valve seat surface (23) cooperates to form a sealing seat, the hydraulic coupler (10) having a master piston (9) and a slave piston (12), which are arranged in a guide sleeve (13) and spaced apart by a coupler gap (11),
characterized in that the master piston (9) and / or the slave piston (12) has a throttle bore (19) which, together with a valve body (20) and a valve seat (21), forms a filling valve (18) for the coupler gap (11) , Fuel injection valve according to claim 1,
characterized in that the valve body (20) is arranged in an actuating element (7). Fuel injection valve according to claim 2,
characterized in that the actuating element (7) is in a non-positive connection with the actuator (2). Fuel injection valve according to one of Claims 1 to 3,
characterized in that the valve body (20) is gimbal-mounted in the actuating element (7). Fuel injection valve according to claim 4,
characterized in that the valve body (20) is partially spherical and engages in a spherical recess (25) of the actuating element (7). Fuel injection valve according to one of Claims 1 to 5,
characterized in that the valve seat (21) is formed on the valve body (20). Fuel injection valve according to one of Claims 1 to 5,
characterized in that the valve seat (21) is formed on the master piston (9) or the slave piston (12) of the hydraulic coupler (10). Fuel injection valve according to claim 7,
characterized in that the valve seat (21) surrounds the throttle bore (19) in a ring. Fuel injection valve according to one of Claims 1 to 8,
characterized in that the master piston (9) and the slave piston (12) of the hydraulic coupler (10) are hollow-cylindrical. Fuel injection valve according to claim 1,
characterized in that the valve body (20) is formed in one piece with the valve needle (15) of the fuel injection valve (1). Fuel injection valve according to claim 10,
characterized in that the valve body (20) has surface grindings (33). Fuel injection valve according to claim 10 or 11,
characterized in that the valve body (20) interacts with a valve seat (21) formed on the slave piston (12) of the hydraulic coupler (10). Fuel injection valve according to claim 12,
characterized in that the throttle bore (19) is arranged on the inflow side of the valve seat (21) in the slave piston (12). Fuel injection valve according to one of Claims 10 to 13,
characterized in that a disc spring (31) is arranged between the master piston (9) and the slave piston (12).

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