DE102007000198A1 - Injection pump e.g. for fuel injection system, has tubular body with hole and actuator which includes hole and cable wire feeds power to actuator - Google Patents

Abstract

The pump has a tubular body (4) with a hole (41). An actuator (2) which includes the hole and a cable wire (23), feeds power to the actuator. A nozzle (1) is opened and closed depending on the electrical signal on the actuator with fuel injected through the nozzle when the nozzle is open. A support element (8) is provided having a higher hardness than the cable wire. The support element and the cable wire have a limited bending conductor. A positioning element (7) is provided inside the intake hole (41) for the support element and relates to the hole in a radial direction of the intake hole.

Description

Technical area

The The present invention relates to an injection device, which has an opening and closing operation a nozzle controls using an actuator.

State of the art

A common one Fuel injection system is designed to be a high pressure fuel, which is accumulated in a common rail, in a combustion chamber of a corresponding cylinder of an internal combustion engine injected by an injector and feeds. The injector has a nozzle and a piezoactuator. This is at the nozzle an injection port opened by a needle and closed, and fuel is injected through the nozzle when the injection port is opened. Furthermore the piezo actuator controls an opening and closing operation the nozzle by controlling a pressure applied to the needle on one side that is the injection port is opposite (see for example JP-2002-257002 A).

Besides is there an injection device for a fuel injection system, the for an internal combustion engine is used which is attached to a vehicle is attached, wherein the injection device to a piezoelectric actuator from a nozzle side an injector body is mounted so that the requirement for miniaturization is met.

Especially be two wires for a power supply connected in advance to the piezo actuator. First, the wires are in one Insertion hole of the injector body inserted, and then the piezo actuator is inserted into the receiving bore so that the wires be pressed by the piezo actuator, so as to advance inside the injector body become. Then, the ends of the lead wires become a lead wire outlet hole guided, which is located at one end of the receiving bore.

There however, the wires are long and narrow, and since they also have a low hardness, can the wires be bent in a simple manner inside the mounting hole, when the lead wire and the actuator are mounted to the injector body become. Therefore, it is not easy to connect the lead wire to the lead wire outlet hole respectively, and thereby disadvantageously bad handling when mounting the wires and the piezoactuator to the injector body.

There Furthermore an area the receiving bore and a coating of the lead wires due of vibrations or the like are rubbed against each other, the Lead wire coatings wear out, and a conductive wire of the Conductor wire can be exposed, causing a short circuit becomes. About that In addition, there was a danger of breakage of the lead wires at one Joint between the wire and a connector due to the vibrations.

Presentation of the invention

Technical task

The The present invention has been made in view of the above Disadvantages created, and it is therefore the task of the present Invention, an operation in mounting a conductor wire and an actuator to an injector body to improve. It belongs too to the object of the present invention, a wear of a Limit coating of the conductor wire due to a vibration, and breakage of the conductor wire due to vibration limit.

Technical solution

Around to achieve the object of the present invention is an injection device provided that a tubular Injector body, one Actuator, having a lead wire and a nozzle, and she is through a support element and a positioning element. The tubular injector body has a receiving bore extending through the injector body in a longitudinal direction extends. The actuator is received in the mounting hole. One end of the lead wire is connected to the actuator for supplying a Performance added. The nozzle is according to a Current supply of the actuator opened and closed, wherein fuel is injected through the nozzle when the nozzle open is. The actuator and the lead wire are inserted into the mounting hole inserted from a first end of the receiving bore. Another end of the conductor wire extends through a Leitungsdrahtauslassloch, and it stands from this before, located at a second end of the mounting hole located. The support element has an end attached to the actuator. The support element has a higher one Hardness as the conductor wire. The support element supports the lead wire such that bending of the lead wire is limited becomes. The positioning element is inside the mounting hole provided at the second end thereof to the support member with respect to the Receiving bore in a radial direction of the receiving bore position.

Advantageous effects the invention

Short description of Illustrations of the drawings

The This invention, together with its additional features and advantages from the following description, the appended claims and the accompanying drawings can be seen, wherein:

1 shows a partial cross-sectional view of an injection device for a fuel injection system according to a first embodiment of the present invention;

2 FIG. 12 is a schematic cross-sectional view of a general internal configuration of FIG 1 shown injection device;

3 shows a cross-sectional view along a line III-III in the 1 ;

4 FIG. 12 is a cross-sectional view of a main portion in a mounting process of the injector according to FIG 1 ;

5 shows an appearance of a support element, which in the 1 is shown;

6 shows a view of a support element when viewed from one direction VI in the 5 is shown;

7 shows an enlarged cross-sectional view of a section VII , the Indian 1 is shown;

8th shows a cross-sectional view of a vicinity of a plug of an injection device according to a second embodiment of the present invention;

9 shows a cross-sectional view of a support member and a piezo actuator of an injection device according to a third embodiment of the present invention;

10 shows a cross-sectional view along a line XX in the 9 ;

11 shows a cross-sectional view of a support member and a piezo actuator of an injection device according to a fourth embodiment of the present invention; and

12 shows a cross-sectional view along a line XII-XII in the

11 ,

Best way to execute the invention

Way (s) to execute the invention

(First embodiment)

A first embodiment of the present invention will be described with reference to the accompanying drawings. The 1 shows a partial cross-sectional view of an injection device for a fuel injection system according to the first embodiment of the present invention. The 2 FIG. 12 is a schematic cross-sectional view of a general internal configuration of FIG 1 shown injection device.

First, with reference to the 1 and 2 a basic structure and an operation of the injection device will be described. The injector injects a high-pressure fuel accumulated in a common rail (not shown) into the cylinder of an internal combustion engine (specifically, a diesel engine, not shown). The injector has a nozzle 1 , a piezoactuator 2 and a dynamic pressure control mechanism 3 , This is where fuel passes through the nozzle 1 injected when a valve is open and the piezo actuator 2 contracts according to a charge and a discharge of an electric charge and expands (ie, excitation of the piezoactuator 2 ). Then the piezo actuator drives 2 the above dynamic pressure control mechanism 3 to a back pressure of the nozzle 1 to control.

The nozzle 1 has a nozzle body 12 , a needle 13 and a spring 14 , Here, the nozzle body has 12 an injection port 11 , and the needle 13 enters and out of engagement with or from a valve seat of the nozzle body 12 to the injection port 11 to open and close (ie to open and close the valve). In addition, the spring tenses 14 the needle 13 in a valve closing direction for closing the injection port 11 in front.

The piezoactuator 2 has a housing 21 which is configured of a stainless steel cylinder tube, and a plurality of piezoelectric elements 22 , Here are the piezoelectric elements 22 stacked together and in the housing 21 added. The piezoelectric elements 22 are with two wires 23 connected, and the wires 23 have top ends connected to connectors 91 a plug 9 joined to an end portion of an injector body 4 opposite to the nozzle 1 is appropriate. Then the piezoelectric elements become 22 with a power source (not shown) through the two wires 23 , the connections 91 and the like connected.

The wires 23 are by a support element 8th supported, which has a higher hardness than the lead wires 23 having. The support element 8th will be described later in detail.

The plug 9 has a first housing 92 and a second housing 93 , Here is the first case 92 made of a plastic that is integral with the connectors 91 formed by insert injection molding, and the second housing 93 consists of a plastic, which is integral with the first housing 92 is formed by injection molding. The first case 92 has in one piece a positioning element 7 that the support element 8th positioned. The support element 7 will be described later in detail. Hereby form the first housing 92 and the second housing 93 a plug housing according to the present invention.

The dynamic pressure control mechanism 3 has a valve body 31 who has a butt 32 picks up, a disc spring 33 and a valve element 34 with a bulging shape. This is the piston 32 according to the contraction and expansion of the piezo actuator 2 offset, and the disc spring 33 tenses the piston 32 to the piezo actuator 2 in front. In addition, the valve element 34 through the piston 32 driven. It should be noted that the valve body 31 is divided into several segments in practice, even if a valve body 31 as a component in the 2 is shown.

The injector body 4 is configured of a metal and has a generally cylindrical tubular shape. In addition, the injector body has 4 a receiving hole 41 extending through the injector body 4 extends from one end to the other end thereof in a longitudinal direction of the injector. The receiving bore 41 takes the piezo actuator 2 and the dynamic pressure control mechanism 3 on. In addition, the injector body is 4 in a holder 5 screwed, which has a generally cylindrical tubular shape, so that the nozzle 1 at the end portion of the injector body 4 is supported. For example, a second end of the receiving bore 41 according to the present invention, an upper end thereof according to 1 , and a first end of the receiving bore 41 according to the present invention is an opposite end thereof, the second end in the longitudinal direction of the receiving bore 41 is opposite.

The nozzle body 12 , the injector body 4 and the valve body 31 form a high pressure channel 6a by which a high-pressure fuel from a common rail is always supplied. In addition, the injector body have 4 and the valve body 31 a low pressure channel 6b which is connected to a fuel tank (not shown).

A high pressure chamber 15 is on one side of the needle 13 to the injection port 11 between an outer peripheral surface of the needle 13 and an inner peripheral surface of the nozzle body 12 intended. The high pressure chamber 15 gets to the injection port 11 in contact when the needle 13 is displaced in a valve opening direction to the injection port 11 to open. In addition, the high pressure chamber 15 always with high pressure fuel through the high pressure channel 6a provided. The needle 13 has a dynamic pressure chamber 16 on one side, the injection port 11 opposite. The dynamic pressure chamber 16 is with the above spring 14 Mistake.

The valve body 31 has a high-pressure seat 35 and a low pressure seating surface 36 , Here is the high-pressure seat 35 provided in a channel for connection between the high pressure channel 6a in the valve body 31 and the dynamic pressure chamber 16 the nozzle 1 provides. In addition, the low-pressure seat is 36 provided in a channel for connection between the low pressure channel 6b inside the valve body 31 and the dynamic pressure chamber 16 the nozzle 1 provides. Furthermore, there is the above-mentioned valve element 34 between the high-pressure seat 35 and the low pressure seat surface 36 ,

In the configuration described above, as described in the 2 is shown, is the valve element 34 with the low-pressure seat 36 in the state in which the piezo actuator 2 contracts so that the back pressure chamber 16 with the high pressure channel 6a connected is. Thus, the back pressure chamber 16 supplied with fuel, which has a high pressure. Then tighten the fuel pressure in the back pressure chamber 16 and the spring 14 the needle 13 in the valve closing direction, to the injection port 11 close.

If, in contrast, the piezo actuator 2 is supplied with an electrical voltage and the piezo actuator 2 expanded, then the valve element 34 with the high-pressure seat 35 in contact so that the back pressure chamber 16 with the low pressure channel 6b connected is. Therefore, a pressure in the dynamic pressure chamber 16 low. Then the fuel pressure in the high pressure chamber is tensioned 15 the needle 13 in the valve opening direction, so that the injection port 11 is opened. Thus, fuel in a cylinder of the internal combustion engine through the injection port 11 injected.

Next, a specific configuration of the injector of the present embodiment will be described. The 3 shows a schematic cross-sectional view of a general my inner configuration in the 1 shown injection device. In addition, the shows 4 a cross-sectional view of a main portion in a mounting process of the injection device according to the 1 ,

Like this in the 3 and 4 is shown, has the receiving bore 41 of the injector body 4 three receiving holes 41a to 41c with a round columnar shape. A first receiving hole 41a the three receiving bores has an end opening at one end side of the injector body 4 on one side to the nozzle 1 , In addition, the first receiving bore extends 41a in the injector body 4 from the end side of the injector body 4 at the side to the nozzle 1 and it extends from the nozzle 1 path.

A second mounting hole 41b the three receiving holes has a diameter which is smaller than a diameter of the first receiving bore 41a , In addition, the second receiving bore extends 41b in the injector body 4 from an end portion of the first receiving bore 41a on one side opposite the nozzle 1 and it extends from the nozzle 1 path. In addition, the first mounting hole 41a coaxial with the second receiving bore 41b intended.

A third mounting hole 41c the three receiving holes is relative to the first receiving bore 41a and the second receiving bore 41b eccentrically provided. In addition, the third mounting hole 41c an end attached to one end side of the injector body 4 on one side opposite the nozzle 1 opens, and she has the other end, with the second receiving bore 41b connected is. Here are the three mounting holes 41a to 41c Longitudinal axes which are each parallel to the longitudinal axis of the injection device.

Then take the first mounting hole 41a the piezo actuator 2 on, and the second mounting hole 41b and the third mounting hole 41c take the lead wires 23 and the support element 8th on. The positioning element 7 is located on an opposite side of the third mounting hole 41c opposite the nozzle 1 ,

The plug 9 has a lead wire outlet hole 94 that the end portions of the lead wires 23 receives. The lead wire outlet hole 94 is in line with fasteners 95 arranged with which the lead wires 23 to the connections 91 be joined.

In addition, the piezo actuator has 2 a seat 25 with an oblique shape attached to the case 21 is trained. Here is the seat 25 with a graduated section 45 between the first mounting hole 41a and the second receiving bore 41b in contact so that the piezo actuator 2 with respect to the injector body 4 is positioned and it is on the injector body 4 attached. Next is the support element 8th described. The 5 shows an appearance of the in the 1 shown supporting element, and the 6 shows a view of the support element 8th when viewed from one direction VI in the 5 ,

The support element 8th is made of a material with a lower hardness than metal (for example, a plastic such as nylon), so that wear of coatings of the lead wires 23 is limited. In addition, the support element 8th designed so that it has a shape and a thickness such that the support element 8th a higher hardness than the lead wires 23 Has.

Like this in the 5 and 6 is shown, has the support element 8th a secured section 81 with a round columnar shape at one end, and the secured section 81 has a through hole inside 82 that the wires 23 receives. A first guide section 83 with a round columnar shape is continuous with the secured section 81 provided, and a second guide section 84 with a generally flat shape is continuous with the first guide portion 83 intended. The secured section 81 and the first guide section 83 are provided coaxially with each other, and the second guide portion 84 is eccentric with respect to the secured section 81 and the first guide section 83 intended.

When the injector body 4 is viewed in the longitudinal direction of the injector, then has a connecting portion (an overlap region) between the second receiving bore 41b and the third mounting hole 41c a generally oval shape (see 3 ). A cross-sectional shape and dimensions of the second guide section 84 of the support element 8th are designed so that the second guide section 84 of the support element 8th can be received within the connection area of the oval shape. Here, the connection area is defined so that the second mounting hole 41b and the third mounting hole 41c through the connection area are in communication with each other.

Two grooves 85 are on outer circumferential surfaces of both guide sections 83 . 84 for picking up the lead wires 23 provided, and the grooves 85 extend in a longitudinal direction of the support element 8th , The grooves 85 are with the through hole 82 in connection.

One of the grooves 85 leads to the corresponding chenden outer peripheral surface of both guide sections 83 . 84 in a direction that differs 180 ° from that direction in which the other of the grooves 85 empties. In other words, one of the grooves will open 85 and the other of the grooves 85 radially outward in a direction of a major axis of the connecting portion having the oval shape, that between the second receiving bore 41b and the third mounting hole 41c is formed, in the state in which the support element 8th and the piezo actuator 2 on the injector body 4 are mounted (see 3 ). Besides, the two grooves 85 arranged in the direction of the major axis of the connecting portion with the oval shape, between the second receiving bore 41b and the third mounting hole 41c is formed, in such a way that a distance L1 between the two grooves 85 as big as possible.

Like this in the 4 shown has the housing 21 of the piezoactuator 2 a tube element 24 with a round tubular shape, which is the secured section 81 receives. Here, the tube element has 24 an end portion that is crimped so that the support element 8th on the piezo actuator 2 is secured.

Next is the support element 7 described. The 7 shows an enlarged view of a section VII in the 1 ,

Like this in the 7 is shown, is the positioning element 7 on one side of the third mounting hole 41c opposite the nozzle 1 , The positioning element 7 has a plate section 71 extending in a longitudinal direction of the third receiving bore 41c extends (hereinafter referred to as an axial direction of a receiving bore).

Like this in the 3 is shown here has the connection area between the second receiving bore 41b and the third mounting hole 41c the oval shape when the injector body 4 in the axial direction of the injector (ie, the direction of the longitudinal axis of the injector), and a non-connecting portion of the third receiving bore 41c that does not work with the second mounting hole 41b has a sickle shape. Besides, the plate section has 71 a cross section perpendicular to the longitudinal axis of the receiving bore, wherein the cross section is approximately with the sickle shape of the non-connecting portion of the third receiving bore 41c is congruent with the second receiving bore 41b not in contact. Then there is the plate section 71 corresponding to the non-connection area of the third mounting hole 41c with the sickle shape, not with the second mounting hole 41b is in communication.

As shown in the figure, the plate section has 71 a first beveled surface 72 on one side opposite the nozzle 1 , Here, the first beveled surface 72 it is inclined with respect to the longitudinal axis of the receiving bore (ie the longitudinal axis of the receiving bore) and is continuous with the plate portion 71 educated. In addition, the support element 8th an end portion corresponding to the first beveled surface 72 is in contact. This allows the support element 8th with respect to the third mounting hole 41c be positioned in a radial direction (hereinafter referred to as a radial direction of a receiving bore). The first beveled surface 72 has an end portion on one side opposite to the nozzle 1 , which is in line with the line wire outlet hole 94 is arranged.

The plate section 71 has a second beveled surface 73 on one side to the nozzle 1 which is inclined with respect to the longitudinal axis of the receiving bore, and it is continuous with the plate portion 71 educated. In addition, the support element 8th designed so that it has the pointed end portion, with the second beveled surface 73 comes into contact before the end portions of the lead wires 23 the lead wire outlet hole 94 in a process for inserting the piezoactuator 2 , the lead wires 23 and the like in the receiving bore 41 to reach. In particular, an overall length of the lengths of the plate portion 71 and the first beveled surface 72 in the axial direction of the receiving bore longer than a length of the lead wires 23 coming from the second guide section 84 of the support element 8th protrude. For example, the other end of the conductor wire is standing 23 from the support element 8th in the direction of the longitudinal axis of the receiving bore 41 before, from the nozzle 1 away, and the other end of the conductor wire 23 has a length that is shorter than a length of the positioning element 7 extending from the lead wire outlet hole 94 in the direction of the longitudinal axis of the receiving bore 41 to the nozzle 1 extends.

Next is the mounting of the support element 8th to the piezo actuator 2 and the mounting of the support element 8th and the piezoactuator 2 to the injector body 4 described.

First, the wires 23 in the through hole 82 inserted. Next is the secured section 81 in the case 21 inserted, and then the lead wires 23 into the grooves 85 inserted. Here are the end portions of the wires 23 out of the grooves 85 about 10 mm free. After that, the En dabschnitt of the housing 21 so crimped that the support element 8th with the piezo actuator 2 is integrated.

Next is the integrated support element 8th that is integral with the piezo actuator 2 is, to the injector body 4 mounted as described below.

Like this in the 4 is shown, the first end portions of the lead wires 23 and the support element 8th into the receiving hole 41 from the opening portion on the side of the receiving bore 41 to the nozzle 1 inserted. After that, the piezo actuator becomes 2 into the receiving hole 41 pressed to insert it in it. Here are the wires 23 (except the end portions of the lead wires 23 ) through the support element 8th supported with the high hardness, and the end portions of the lead wires 23 not by the support element 8th are short and have lengths of about 10 mm. Therefore, the bending of the lead wires 23 be limited while the piezo actuator 2 into the receiving hole 41 is pressed. While the piezo actuator 2 into the receiving hole 41 As a result, the lead wires can be pressed 23 and the support element 8th at the same time inside the locating hole 41 be carefully advanced.

In a state where the piezo actuator 2 is pressed so that it reaches a position such that the seat 25 of the piezoactuator 2 with the graduated section 45 of the injector body 4 is in contact, are the end portions of the lead wires 23 also advanced so as to be close to the opening portion of the receiving bore 41 opposite the nozzle 1 to reach.

While the piezo actuator 2 and the like in the receiving bore 41 can be inserted, this can be the support element 8th inside the mounting hole 41 be inclined as indicated by a dashed line in the 7 is shown. In this case, the support element 8th be offset from a normal position in the radial direction of the receiving bore, and therefore, a position of the end portions of the lead wires 23 with respect to the lead wire outlet hole 94 be offset from a normal position thereof. However, in the present embodiment, the position of the end portions of the lead wires 23 with respect to the lead wire outlet hole 94 reset to the normal position, as described below.

Here, in the present embodiment, the normal position of the support member corresponds 8th in the radial direction of the receiving bore the connection area (overlap area) with the oval shape between the second receiving bore 41b and the third mounting hole 41c when the injector body 4 in the axial longitudinal direction of the injector.

Like this in the 7 is shown, first reaches the end portion of the support member 8th with the second beveled surface 73 in contact before the end sections of the wires 23 the lead wire outlet hole 94 to reach. As the end portion of the support element 8th along the second beveled surface 73 is slidably advanced, then the position of the support element 8th be gradually corrected in the radial direction of the receiving bore. In a state where the end portion of the support member 8th through the second beveled surface 73 passes through, changes the plate section 71 the position of the support element 8th in the radial direction of the receiving bore to the normal position, and finally determines the contact of the end portion of the support member 8th with the first bevelled surface 72 the position of the support element 8th in the radial direction of the receiving bore. In this way, the end portions of the lead wires 23 reliably to the lead wire outlet hole 94 be guided, since the position of the end portions of the lead wires 23 with respect to the lead wire outlet hole 94 is reset to the normal position, and then the lead wire outlet hole leads 94 the end portions of the lead wires 23 to the connecting elements 95 ,

Then, the end portions of the lead wires become 23 to the connecting elements 95 and then the second housing 93 as it is in the 1 is shown formed by injection molding.

In the current embodiment, the lead wires 23 through the support element 8th With the high hardness, the bending of the lead wires becomes 23 limited, while the piezo actuator 2 and the like to the injector body 4 to be assembled. In addition, since the support element 8th concerning the receiving bore 41 is positioned in the radial direction, the position of the end portions of the lead wires 23 with respect to the lead wire outlet hole 94 set (reset) to the normal position. Thus, the end portions of the lead wires 23 reliably to the lead wire outlet hole 94 be guided. Therefore, the bending of the lead wires 23 limited, and also the lead wires 23 reliably to the lead wire outlet hole 94 be guided. This combination can handle the assembly of the actuator 2 and the like to the injector body 4 improve.

In addition, since the end portion of the support element 8th with the first bevelled surface 72 is in contact is on the support element 8th a force applied in the radial direction of the receiving bore. As a result, a wobble of the support element 8th be reliably limited. Therefore, the wear of the coatings of the lead wires becomes 23 due to the vibrations is limited, and also the breaking of the wires 23 limited due to the vibrations.

In addition, since the support element 8th is made of the plastic, the wear of the coatings of the lead wires 23 due to abrasion against the support element 8th more limited than in that case where the support element 8th consists of the metal, which has a higher hardness than the plastic.

As well as the two grooves 85 with respect to each other in the direction of the major axis with the oval shape of the connecting portion (overlapping area) between the second receiving bore 41b and the third mounting hole 41c are arranged, the distance L1 between the two grooves 85 be set as large as possible. As a result, a distance between the two terminals 91 to which the two wires 23 be joined, be set large, and therefore will be a mutual overlay of the connectors 91 reliably limited.

Second Embodiment

A second embodiment of the present invention will be described. The 8th shows a cross-sectional view of a vicinity of a plug of an injection device according to the second embodiment. Here, equivalent components of the second embodiment that are equivalent or similar to the components in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

Like this in the 8th is shown, the injector body 4 a fourth mounting hole 41d with a round tube shape on one side opposite the nozzle 1 , The fourth mounting hole 41d is with the third mounting hole 41c connected, and it is eccentric with respect to the third mounting hole 41c intended.

The positioning element 7 is separate from the first housing 92 of the plug 9 intended. In addition, the positioning element has 7 a shaft section 74 with a round columnar shape, in the fourth mounting hole 41d is included. The shaft section 74 has a lead wire through hole 75 including an end portion of the first beveled surface 72 on one side opposite the nozzle 1 with the lead wire outlet hole 94 combines.

If in this way the positioning element 7 a separate element (different element) from the first housing 92 is, then, even if, for example, the plug 9 to the injector body 4 must be mounted at a different angle, this be handled by either only the positioning element 7 or the first housing 92 will be changed.

(Third Embodiment)

A third embodiment of the present invention will be described. The 9 shows a cross-sectional view of a support member and a piezo actuator of an injection device according to the third embodiment, and the 10 shows a cross-sectional view along a line XX in the 9 , Here, equivalent components of the third embodiment, which are equivalent or similar to the components in the first embodiment, are denoted by the same reference numerals, and description thereof will be omitted.

The support element 8th of the present embodiment incorporated in the 9 and 10 is shown is formed by insert injection molding. First, in particular, the piezoelectric actuator 2 and the wires 23 placed at predetermined positions of an injection mold, and then a plastic for injection molding in the injection mold is poured so that the support element 8th is trained. Here are the holes 87 Markings formed by pins in the injection molding tool for positioning the lead wires 23 are provided during injection molding.

Also because the wires 23 that of the piezo actuator 2 protrude, in the support element 8th except the end portions of the lead wires 23 are embedded, rubbing off the coatings of the lead wires 23 with respect to the injector body 4 limited metal, and therefore the wear is limited.

(Fourth Embodiment)

A fourth embodiment of the present invention will be described. The 11 shows a cross-sectional view of a support member and a piezo actuator of an injection device according to the fourth embodiment, and the 12 shows a cross-sectional view along a line XII-XII in the 11 , Here are equivalent Components of the present embodiment that are equivalent or similar to the components of the third embodiment are denoted by the same reference numerals, and description thereof will be omitted.

Like this in the 11 and 12 shown, takes the case 21 of the piezoactuator 2 a sealing cap 100 on, which consists of a plastic, the entry of a plastic for injection molding in the housing 21 during insert-injection molding. The wires 23 extend from the piezo actuator 2 , passing through a through hole in the interior of the sealing cap 100 pass through, leaving them from the piezoactuator 2 protrude and expose to the outside. Around the ends of the wires 23 during insertion injection molding is a positioning element 110 made of a plastic at the end portions of the lead wires 23 appropriate.

In addition, the piezo actuator becomes 2 on which the sealing flap 100 is mounted, placed in an injection mold, and the positioning element 110 that the wires 23 is placed in the injection mold. Thereafter, a plastic for injection molding is poured into the injection mold to the support element 8th train.

(Other embodiment)

In the first and second embodiments described above, the tube member becomes 24 that on the case 21 of the piezoactuator 2 is formed, so crimped that the support element 8th on the piezo actuator 2 is attached. However, the secured section 81 of the support element 8th alternatively in the tube element 24 of the housing 21 be pressed in so that the support element 8th on the piezo actuator 2 is attached.

In addition, in each of the embodiments described above, the piezoactuator drives 2 the dynamic pressure control mechanism 3 for controlling a back pressure of the nozzle 1 an electromagnetic solenoid as an actuator alternatively the dynamic pressure control mechanism 3 for controlling the back pressure of the nozzle 1 can drive.

additional Advantages and modifications will be apparent to those skilled in the art in a simple manner seen. The invention in its broader terms Therefore, not to the specific details that are presented equipment and the illustrated examples shown and described are.

An injection device has a tubular injector body ( 4 ), an actuator ( 2 ), a conductor wire ( 23 ) and a nozzle ( 1 ), and it is by a support element ( 8th ) and a positioning element ( 7 ). The support element ( 8th ) has an end attached to the actuator ( 2 ), wherein the support element ( 8th ) a higher hardness than the conductor wire ( 23 ), and the support element ( 8th ) supports the conductor wire ( 23 ) such that bending of the conductor wire ( 23 ) is limited. The positioning element ( 7 ) is inside the receiving bore ( 41 ) provided at a second end thereof to the support element ( 8th ) with respect to the receiving bore ( 41 ) in a radial direction of the receiving bore ( 41 ).

Claims (11)

An injector comprising: a tubular injector body ( 4 ) with a receiving bore ( 41 ) extending through the injector body ( 4 ) extends in a longitudinal direction; an actuator ( 2 ), which in the receiving bore ( 41 ) is included; a conductor wire ( 23 ), one end of which is connected to the actuator ( 2 ) is added to supply a power; a nozzle ( 1 ), which according to an energization of the actuator ( 2 ) is opened and closed, whereby a fuel through the nozzle ( 1 ) is injected when the nozzle ( 1 ), wherein: the actuator ( 2 ) and the conductor wire ( 23 ) in the receiving bore ( 41 ) from a first end of the receiving bore ( 41 ) are inserted; and another end of the conductor wire ( 23 ) through a lead wire outlet hole ( 94 ) and projecting therefrom, which at a second end of the receiving bore ( 41 ), and the injection device is characterized by: a support element ( 8th ) having an end connected to the actuator ( 2 ), wherein: the supporting element ( 8th ) a higher hardness than the conductor wire ( 23 ) having; and the support element ( 8th ) the conductor wire ( 23 ) such that bending of the conductor wire ( 23 ) is limited; and a positioning element ( 7 ), which is located inside the receiving bore ( 41 ) is provided at the second end thereof to the support element ( 8th ) with respect to the receiving bore ( 41 ) in a radial direction of the receiving bore ( 41 ). Injection device according to claim 1, wherein: the positioning element ( 7 ) a first beveled surface ( 72 ), which with respect to a longitudinal axis of the receiving bore ( 41 ) is inclined; and the support element ( 8th ) has an end portion at its side to the second end of the receiving bore ( 41 ), wherein the end portion with the first beveled surface ( 72 ) is in contact with the support element ( 8th ) with respect to the receiving bore ( 41 ) in to position the radial direction. An injector according to claim 2, wherein: the lead wire outlet hole (10) 94 ) on one side of the first beveled surface ( 72 ) to the second end of the receiving bore ( 41 ) is located. Injection device according to one of claims 1 to 3, wherein: the positioning element ( 7 ) a plate section ( 71 ), which extends in a direction of a longitudinal axis of the receiving bore ( 41 ) and between an inner wall surface of the receiving bore ( 41 ) and the support element ( 8th ) is arranged; the plate section ( 71 ) a second beveled surface ( 73 ) at its side to the first end of the receiving bore ( 41 ), wherein the second beveled surface ( 73 ) with respect to the longitudinal axis of the receiving bore ( 41 ) is inclined; and the support element ( 8th ) has an end portion at its side to the second end of the receiving bore ( 41 ), wherein the end portion on the second beveled surface ( 73 ) slides in such a way that a position of the support element ( 8th ) with respect to the receiving bore ( 41 ) in the radial direction during a process for inserting the actuator ( 2 ) and the conductor wire ( 23 ) in the receiving bore ( 41 ) is corrected. Injection device according to claim 4, wherein: the support element ( 8th ) is designed so that the end portion of the support element ( 8th ) with the second bevelled surface ( 73 ) comes into contact before the other end of the conductor ( 23 ) the lead wire outlet hole ( 94 ) during the process of inserting the actuator ( 2 ) and the conductor wire ( 23 ) in the receiving bore ( 41 ) reached. Injection device according to one of claims 1 to 5, further comprising: a plug ( 9 ) located on one side of the injector body ( 4 ) to the second end of the receiving bore ( 41 ), with the plug ( 9 ) has a connection ( 91 ) connected to the conductor wire ( 23 ) is joined; and a connector housing ( 92 . 93 ), the connection ( 91 ), wherein the plug housing ( 92 . 93 ) in one piece with the positioning element ( 7 ) is trained. Injection device according to one of claims 1 to 5, further comprising: a plug ( 9 ) located on one side of the injector body ( 4 ) to the second end of the receiving bore ( 41 ), with the plug ( 9 ) has a connection ( 91 ) connected to the conductor wire ( 23 ) is joined; and a connector housing ( 92 . 93 ), the connection ( 91 ), wherein the plug housing ( 92 . 93 ) a separate element from the positioning element ( 7 ). Injection device according to claim 4, wherein: the other end of the conductor wire ( 23 ) of the support element ( 8th ) in the direction of the longitudinal axis of the receiving bore ( 41 ) protrudes from the nozzle ( 1 ), and wherein it has a length which is shorter than a length of the positioning element ( 7 ) extending from the lead wire outlet hole (FIG. 94 ) in the direction of the longitudinal axis of the receiving bore ( 41 ) to the nozzle ( 1 ) extends. Injection device according to claim 1, wherein the lead wire ( 23 ) one of two wires ( 23 ). Injection device according to claim 6, wherein: the conductor wire ( 23 ) one of two wires ( 23 ); and the connection ( 91 ) one of two connections ( 91 ), which in each case to a corresponding conductor wire of the two lead wires ( 23 ) are joined. Injection device according to claim 7, wherein: the conductor wire ( 23 ) one of two wires ( 23 ); and the connection ( 91 ) one of two connections ( 91 ), which in each case to a corresponding conductor wire of the two lead wires ( 23 ) are joined.