FR3050770A1 - FUEL INJECTOR - Google Patents

Abstract

A top guide assembly (42) adapted to be arranged in a fuel injector (10) and extending along a longitudinal axis (X), compressed between a nozzle body (16) and a valve body of control (20), the upper guide assembly (42) comprising a top guide member (56) having an upper cylindrical base comprising (60) comprising a cylindrical side face (64), a flat top face (66) adapted to be compressed against the valve body (20), a low planar face (68) adapted to be pressed against the nozzle body (16) and a longitudinal through bore (58) arranged to allow a needle (14) to slide. The injector (10) is arranged such that in use the nozzle body (16) is in electrical contact with the mass (M). The upper guide assembly (42) is electrically insulated between the nozzle body (16) and the valve body (20).

Description

FUEL INJECTOR

TECHNICAL FIELD The invention relates to a fuel injector provided with a device for detecting the position of the needle.

BACKGROUND OF THE INVENTION

A fuel injector conventionally comprises a needle controlled opening and closing depending on the pressure in a control chamber, which pressure is a function of the position of a control solenoid valve. These small displacements are carried out at high speed and, the regularly increased performances now require for an optimal control a feedback as to the real position of the needle. Devices are known in which a sensor is arranged on the injector, or an injector in which the surfaces of the body components are electrically insulated so that a measurement of electrical resistance can be made between two elements of the body of the injector. . These complex and expensive devices have not yet proven their industrial realism and should be offered a simple and effective device.

SUMMARY OF THE INVENTION

The present invention proposes to solve at least partially these problems by proposing a fuel injector comprising an injector body in which are arranged a movable needle between a fully open position and a closed position and a spring constantly urging the needle to the closed position, the injector being arranged so that in use the injector body is in electrical contact with the electrical ground. The injector is further provided with a device for locating the position of the needle in which an electrical circuit is closed when the needle is in the fully open position and also when the needle is in the closed position. The needle is then in electrical contact with the electrical mass, the circuit being open in any other intermediate position of the needle, the needle not being electrically grounded. The invention describes a high guide assembly adapted to be arranged in a fuel injector and extending along a longitudinal axis. The top guide assembly is compressed between a nozzle body and a control valve body. The top guide assembly includes a top guide member having an upper cylindrical base including a cylindrical side face, a high planar face adapted to be compressed against the valve body, a low planar face adapted to be compressed against the nozzle body and a longitudinal opening bore arranged to allow a needle to slide. The injector is arranged such that in use the nozzle body is in electrical contact with the ground. The top guide assembly is electrically insulated between the nozzle body and the valve body. The electrical isolation of the high guide member is defined by an insulating layer covering at least the portion of the faces of the cylindrical base in contact with the valve body and the nozzle body.

In a second embodiment, the high guide assembly further comprises a first washer arranged between the upper planar face and the valve body and a second washer arranged between the low plane face and the nozzle body.

In a third embodiment, the high guide member further comprises an electrically insulated ring covering the outer lateral face of the cylindrical base.

In a first and second embodiment the high guide member further comprises an electrically insulating coating.

In a fourth embodiment, the second washer comprises a flange rising along the longitudinal axis.

In a fifth embodiment, the top guide assembly comprises the first washer and the top guide member covered with an electrically insulating layer on the low planar face.

In a sixth embodiment, the high guide assembly comprises the second washer and the valve body comprises an insulating layer on the lower face with the exception of the area in contact with the upper end of the needle.

In addition, the washers and the ring are coated with an electrically insulating layer based on insulating material, such as for example ceramic, a polymer layer.

In addition the high guide member includes pin holes partially electrically insulated. The injector comprises a control valve assembly, a top guide assembly according to one of the previously described embodiments and a nozzle assembly, wherein the top guide assembly may include at least one locating pin fitted between the guide member. top and the valve body. The pin can also be electrically isolated from the upper guide member or electrically isolated only from the valve body. The pin comprises a metal core covered with an electrically insulating layer.

The pin can also be integrally made of plastic or any other insulating material.

BRIEF DESCRIPTION OF THE DRAWINGS Other features, objects and advantages of the invention will appear on reading the detailed description which follows, and with reference to the appended drawings, given by way of non-limiting example:

Figure 1 is an axial section of the injector according to the invention.

Figure 2 is an enlarged section of the invention according to the first embodiment. Figure 3 is an electrical diagram of the invention Figure 4 a section of the second embodiment.

Figure 5 and Figure 6 are top views of the washers according to the second embodiment.

Figure 7 is an isometric view of the top guide member.

Figure 8 is a section of the third embodiment.

Figure 9 is a section of the fourth embodiment.

Figure 10 is a section of the pin according to the invention.

Figure 11 is a section of the pin according to an alternative of the invention.

DESCRIPTION OF PREFERRED EMBODIMENTS

To facilitate and clarify the following description, the top-down orientation is chosen arbitrarily and, words and phrases such as "above, below, above, below, up, down ..." can be used without any intention to limit the invention.

According to FIGS. 1 and 2, there is described a first embodiment of the invention relating to a fuel injector 10, here a diesel injector, although the invention is entirely transferable to a gasoline injector or any other fuel or any other fuel. other liquid form. The description will detail the elements of the invention and will remain more succinct and general as to the surrounding elements. The injector 10 extends along a longitudinal axis X and comprises from bottom to top, according to the conventional and non-limiting sense of the figures, a nozzle assembly 12 comprising a needle 14 arranged in a nozzle body 16, a valve assembly 18, the valve body 20 and the actuator body 24 are held together by a nut 26 injector 10 which bears on a shoulder 28 of the nozzle body 16 as described in FIG.

As described in FIG. 1, the nut 26 is screwed onto the actuator body 24, the valve body 20 being arranged between the two other bodies which are the nozzle bodies 16 and the actuator body 24. The three bodies 16, 20, 24 together form the body of the injector 10.

As described in FIG. 2, the actuator 22 comprising the actuator body 24 which is arranged above the control valve assembly 18. The actuator body 24 comprises a conduit 30 arranged so that align with a conduit 30 opening from the control valve body 20. The conduit 30 of the actuator body 24 extends upwardly into an upper portion of the actuator body 24 where a connector (not shown) is provided.

As shown in Fig. 2, the check valve assembly 18 includes a valve control chamber 32 arranged in the valve body 20 in which a magnetic armature assembly 34 and control rod 36 attached to each other are arranged. 'other. As described in FIG. 1, the control valve assembly 18 is arranged below the actuator 22.

According to FIG. 2, the nozzle body 16 comprises an inner axial bore 38 extending from an upper end 40 where a top guide assembly 42 is arranged compressed between a valve body 20 and the nozzle body 16, until a lower end which is arranged a low guide assembly 44 and closing in a point so as to form a seat 46 of conical nozzle body comprising injection holes 48 and arranged to receive the needle 14 of the injector 10. In the upper part of the nozzle body 16, a control chamber of the needle 50 is defined between the upper guide assembly 42, the needle 14 and the valve body 20.

According to Figure 2, the needle 14 is arranged axially sliding in the bore 38 of the nozzle body.

As described in FIGS. 1 and 2, the injector 10 is provided with a fuel circulation circuit which makes it possible to supply high pressure fuel via a high pressure circuit from an inlet orifice (not shown) arranged in a upper part of the injector 10 to the injection holes 48 arranged in a lower part of the injector 10.

As described in FIGS. 1 and 2, when the actuator 22 is electrically powered, it attracts the magnetic armature 34 and the valve stem 36 which are secured together, thereby opening the evacuation channel (not shown) and allows the fuel enclosed in the control chamber 50 to evacuate to a low pressure circuit (not shown). Then the pressure decreases in the control chamber 50 and the needle 14 moves in the bore 38 of the nozzle body to an open position PO in which a lower end 43 of the needle moves away from the seat 46 of the body. nozzle. As a result, an upper end 45 of the needle contacts a lower face 47 of the valve body.

When the actuator 22 is not powered, the magnetic armature assembly 34 and control rod 36 is pushed by a valve spring 52 to a position which prevents the fuel from flowing to the evacuation channel which is closed. , which retains the high-pressure fuel that gets there. Then the pressure in the control chamber 50 rises and the needle 14 is pushed down by a needle spring 54 and the lower end 43 of the needle is in contact with the seat 46 of the nozzle body and the upper end 45 of the needle is remote from the lower face 47 of the valve body. The injector 10 further comprises a device for detecting the extreme positions of the needle 14 in the injector.

As described in FIG. 2, the device is an electrical circuit making it possible to carry out an electrical measurement XI between a terminal of the connector (not shown) and the mass M to which the nozzle body 16, the valve body 20, the actuator body 24 and injector nut 26.

When the needle 14 is in the closed position PF, the electrical circuit comprises an electrical connection which extends from the lug (not shown) to the needle spring 54, then the needle spring 54 itself, then the needle 14 to the lower end 43 of the needle and finally the nozzle body 16 from the nozzle body seat 46 to the mass M.

When the needle 14 is in the open position PO, the electrical circuit comprises an electrical connection which extends from the terminal (not shown) to the spring 54, then the spring 54 itself, then the needle 14 to the upper end 45 of the needle, then the upper guide assembly 42 and finally the valve body 20 from the lower face 47 of the valve body which is in contact with the upper end 45 of the needle to the mass M.

In these two extreme positions PO, PF, the electrical circuit is closed and an electrical measurement can be made, said measurement being significant of an extreme position. An injection cycle includes a main opening during which the needle travels the entire displacement between the two extreme positions.

According to Figure 3, the injector 10 is shown schematically according to an electrical circuit comprising, between the lug (not shown) and the mass M, the needle 14 schematically as a switch in parallel which is placed an insulation resistance Ri. The insulation resistance Ri has a value typically greater than 100 kOhms, so that in the closed position PF the electrical resistance of the circuit is zero or very low and, in the open position PO, the electrical resistance of the circuit is equal to the resistance of the circuit. Ri insulation.

As depicted in FIG. 2, the electrical circuit is now detailed in the portion of the top guide assembly 42 of the nozzle assembly of the injector. The surfaces of the needle 14 which may be in contact with the nozzle body 16 are electrically insulated.

In a first embodiment, as described in FIGS. 1 and 2, the upper guide assembly 42 comprises a high guide member 56, as in FIG. 2, comprising a bore 58 opening axially and passing through an upper cylindrical base 60 and a lower cylindrical sleeve. 62. The cylindrical base 60 extends downwards in a cylindrical lower sleeve 62 according to FIG. 2 along the longitudinal axis X. The upper guide assembly 42 is compressed between the nozzle body 16 and the valve body of FIG. 20. The cylindrical base 60 of the high guide member comprises a cylindrical side face 64, a high planar face 66 adapted to be pressed against the valve body 20, and a low planar face 68 adapted to be compressed against the nozzle body 16. The needle 14 of the injector is arranged sliding in the bore 58 of the upper guide member. The injector 10 is arranged so that in use the nozzle body 16 is in electrical contact with the mass (M). The upper guide assembly 42 is electrically isolated from the nozzle body 16 and the valve body 20. The electrical insulation of the upper guide member 56 is defined by an insulating layer 57 covering at least a portion of the faces 64, 66, 68. contact with the valve body 20 and the nozzle body 16. The insulating layer 57 has a thickness of between 1 and 5 microns. In a first alternative to the embodiment, the insulating layer 57 may also completely cover the upper guide member 56. The insulating layer 57 may be based on basic oxide, silicon carbide or aluminum oxide, for example. In a second alternative to the embodiment, an insulating layer may be deposited on the faces of the nozzle body 16 in contact with the upper guide member 56 and on the lower face 47 of the valve body with the exception of the zone in contact with the the upper end 45 of the needle.

In a second embodiment as described in FIGS. 4, 5, 6 and 7, the top guide assembly 42 is electrically isolated from the nozzle body 16 and the valve body 20. The top guide assembly 42 includes a guide member 56, a first washer 70 extending transversely to the main axis X and arranged between the upper face 66 of the upper guide member and the valve body 20, a second washer 72 extending transversely to the main axis X and arranged between the low plane face 68 of the upper guide member 56 and the nozzle body 16. The upper guide member 56 further comprises the electrical insulating layer 57. The electrically insulating layer 57 is at least in contact with the nozzle body 16. The insulating layer 57 of the high guide member has a thickness of between 1 and 5 micrometers. The first washer 70 is arranged below a lower face 47 of the valve body and comprises three orifices 76, 78, 80 corresponding to a high-pressure inlet 76, also known as the HP inlet, and to the two guide orifices 78, 80 for receiving additionally two pins 82,84 orientation electrically isolated. The two washers 70, 72 comprise an electrically insulating layer 74 completely covering the surface of the washers 70, 72. The two washers 70, 72 are made from a core 73 of metallic material such as steel or titanium with the insulating layer 74. The insulating layer 74 may be based on basic oxide, silicon carbide or aluminum oxide for example.

In a third embodiment as described in FIG. 8, the top guide assembly 42 is electrically insulated between the nozzle body 16 and the valve body 20. The top guide assembly 42 includes a top guide member 56, the first washer 70 extending transversely to the main axis X and arranged between the upper face 66 of the upper guide member and the valve body 20, the second washer 72 extending transversely to the main axis X and arranged between the low plane face. 68 of the upper guide member and the nozzle body 16 and an outer ring 86 mounted externally on the lateral face 64 of the outer cylindrical base 60. The ring 86 is covered with the electrically insulating layer 74.

In a fourth embodiment as described in FIG. 9, the upper guide assembly 42 comprises a high guide member 56, the first washer 70, the second washer 72 comprising a rim 88 rising along the longitudinal axis X. The rim 88 is to cover the lower flat face 68 and a portion of the lateral face 64 of the cylindrical base 60. In an alternative to the fourth embodiment (not shown), the upper guide assembly 42 includes the first washer 70 comprising a downward flange along the longitudinal axis X and the second washer 72.

In a fifth embodiment (not shown), the top guide assembly 42 includes the first washer 70 and the top guide member 56 covered with an electrically insulating layer on the low planar face 68.

In a sixth embodiment (not shown), the upper guide assembly 42 comprises the second washer 72 and the valve body 20 covered with an electrically insulating layer on the lower face 47 with the exception of the contact area. the upper end 45 of the needle.

For the six embodiments, according to FIGS. 7, 10 and 11, the electrical insulation must be ensured in contact with the valve body 20. The upper guide assembly 42 comprises the upper guide member 56 which is provided with two orifices 90 eccentric arranged in the high plane face 66 to additionally receive the two pins 82,84 for positioning the control valve body 20. The pins 82, 84 are provided to be inserted into force in the two orifices 90. According to FIG. 10, the orientation pin 82, 84 comprises a metal core 85 entirely covered with a layer 74 electrically insulated. The core 85 of the orientation pin 82, 84 may also be of electrically insulated plastic material, or of metal material overmolded with an electrically insulated plastic material, or an electrically insulated wood-based material. According to FIG. 11, the orientation pin 82, 84 comprises a metal core 85 covered at least on a portion of the surface of the electrically insulated layer 74 which is arranged to be in contact with the upper guide assembly 42 (not shown ). The portion of the pin 82,84 surface in contact with the valve body 20 is not coated with an electrically insulated coating.

The following references have been used in the description: injector 12 nozzle assembly 14 needle 16 nozzle body 18 control valve assembly 20 valve body 22 actuator 24 actuator body 26 nut 28 shoulder 30 conduit 32 control chamber 34 magnetic armature 36 control rod 38 bore of nozzle body 40 upper end 42 guide assembly top 43 lower end of needle 44 lower guide assembly 45 upper end of needle 46 nozzle body seat 47 lower face of valve body 48 injection holes 50 guide chamber top 52 valve spring 54 needle spring 56 high guide member 57 insulating layer of upper guide member 58 bore of upper guide assembly 60 upper base of upper guide assembly 62 lower sleeve 64 lateral face 66 high flat face 68 low flat face 70 first washer 72 second washer 73 washer core 74 insulating layer

76 hole HP 78 guide hole of the first washer 80 guide hole of the first washer 82 pin orientation 84 pin 85 pin core 86 cylindrical outer ring 88 flange 90 guide member hole top 100 calculator X Axis longitudinal XI Electrical measurement PO Open position PF Closed position M electrical ground

Claims (11)

A top guide assembly (42) adapted to be arranged in a fuel injector (10) and extending along a longitudinal axis (X), compressed between a nozzle body (16) and a nozzle body (16). control valve (20), the upper guide assembly (42) comprising a top guide member (56) having an upper cylindrical base including (60) a cylindrical side face (64), a high planar face (66) adapted to be compressed against the valve body (20), a low planar face (68) adapted to be pressed against the nozzle body (16) and a longitudinal through bore (58) arranged to allow a needle (14) to slide, injector (10) being arranged so that in use the nozzle body (16) is in electrical contact with the mass (M), characterized in that the upper guide assembly (42) is electrically isolated between the body of the nozzle nozzle (16) and the valve body (20). 2. High guide assembly (42) according to the preceding claim wherein the electrical insulation of the upper guide member (56) is defined by an insulating layer (57) covering at least the portion of the faces (64,66, 68) of the cylindrical base (60) in contact with the valve body (20) and the nozzle body (16). 3. A top guide assembly (42) according to claim 1 or 2 further comprising a first washer (70) arranged between the upper planar face (66) and the valve body (20) and a second washer (72) arranged between the low plane face (68) and the nozzle body (16). The upper guide assembly (42) of claim 3, wherein the top guide member (42) further comprises an electrically insulated ring (86) covering the outer side surface (64) of the cylindrical base (60). The top guide assembly (42) of claim 2 or 3, wherein the top guide member (56) further comprises an electrically insulating layer (57). The upper guide assembly (42) of claim 2 or 3, wherein the second washer (72) comprises a flange (88) extending along the longitudinal axis (X). The high guide assembly (42) of claim 4, wherein the washers (70,72) and the ring (86) are coated with an electrically insulating layer (74). 8. A top guide assembly (42) according to any one of the preceding claims, wherein the top guide member (56) comprises pin holes (82,84) electrically insulated. Injector (10) comprising a control valve assembly (18), a top guide assembly (42) according to any one of the preceding claims, and a nozzle assembly (12), wherein the top guide assembly (42) ) comprises at least one locating pin (82,84) fitted between the top guide member (56) and the valve body (20), characterized in that the pin (82,84) is electrically insulated from the valve body ( 20). Injector (10) according to claim 9, wherein the pin (82,84) comprises a metal core (85) covered with the electrically insulating layer (74). Injector (10) according to claim 9, wherein the pin (82,84) is made of plastic.