Fuel injection valve supporting structure

Information

  • Patent Grant
  • 9212641
  • Patent Number
    9,212,641
  • Date Filed
    Thursday, February 14, 2013
    11 years ago
  • Date Issued
    Tuesday, December 15, 2015
    9 years ago
Abstract
In a fuel injection valve supporting structure, a contact surface being orthogonal to a center axis of a fuel injection valve and opposed to a fuel supply cap is formed in an intermediate portion of the fuel injection valve, a supporting member includes a base plate set on the contact surface and an elastic piece extending from the base plate, the elastic piece includes: a first elastic portion extending from the one end of the base plate and bent upwards in a U-shape; and a second elastic portion extending from the first elastic portion toward the other end while bending upwards, bringing its apex into pressure contact with the fuel supply cap, and making a tip end portion thereof slidably come into contact with the base plate, and a curvature radius of the second elastic portion is set larger than a curvature radius of the first elastic portion.
Description
BACKGROUND OF THE INVENTION

1. Field of the Invention


The present invention relates to an improvement of a fuel injection valve supporting structure in which: a nozzle portion at a front end portion of a fuel injection valve is fitted in an injection valve attachment hole of an engine; a fuel supply cap of a fuel distribution pipe supported by the engine is fitted on a fuel introduction portion at a rear end portion of the fuel injection valve; a supporting member for biasing the fuel injection valve toward the injection valve attachment hole is interposed between the fuel injection valve and the fuel supply cap.


2. Description of the Related Art


Such a fuel injection valve supporting structure is already known, as disclosed in Japanese Patent Application Laid-open No. 2004-245168.


With regard to such a conventional fuel injection valve supporting structure, a U-shaped plate spring as a supporting member is interposed between a fuel injection valve and a fuel supply cap. In this kind of fuel injection valve supporting structure, the support of the fuel injection valve may become unstable because: stress concentrates particularly on a bent portion of the U-shaped plate spring; and as a long time passes, the bent portion plastically deforms and the set load of the plate spring decreases.


SUMMARY OF THE INVENTION

The present invention has been made with the foregoing situation taken into consideration, and an object thereof is to provide a fuel injection valve supporting structure which is capable of: keeping a set load of a supporting member stable for a long period of time; and supporting a fuel injection valve stably.


In order to achieve the object, according to a first feature of the present invention, there is provided a fuel injection valve supporting structure in which: a nozzle portion at a front end portion of a fuel injection valve is fitted in an injection valve attachment hole of an engine; a fuel supply cap of a fuel distribution pipe supported by the engine is fitted on a fuel introduction portion at a rear end portion of the fuel injection valve; a supporting member for biasing the fuel injection valve toward the injection valve attachment hole is interposed between the fuel injection valve and the fuel supply cap, wherein a contact surface is formed in an intermediate portion of the fuel injection valve, the contact surface being orthogonal to a center axis of the fuel injection valve and opposed to the fuel supply cap, the supporting member includes a base plate set on the contact surface and an elastic piece extending from one end of the base plate, the elastic piece includes a first elastic portion and a second elastic portion, the first elastic portion extending from the one end of the base plate and bent upwards in a U-shape, the second elastic portion extending from the first elastic portion toward an opposite end of the base plate while bending upwards, bringing an apex of the second elastic portion into pressure contact with a front end surface of the fuel supply cap, and making a tip end portion of the second elastic portion slidably come into contact with an upper surface of the base plate, and a curvature radius of the second elastic portion is set larger than a curvature radius of the first elastic portion. Here, the contact surface corresponds to a first contact surface 5 of an embodiment of the present invention, which will be described later.


With the first feature of the present invention, stress produced on each elastic piece when setting the supporting member can be dispersed to the first and second elastic portions, and stress which tends to concentrate particularly on the first elastic portion having the smaller curvature radius can be eased. Accordingly, it is possible to keep a predetermined set load of the elastic piece for a long period of time, and to stabilize the support of the fuel injection valve.


Moreover, even if the first elastic portion having the smaller curvature radius may plastically deform, elastic force of the second elastic portion, which is supported by the two portions, can maintain each elastic piece's biasing function of biasing the fuel supply cap. For this reason, plastic deformation of the first elastic portion will not hinder the support of the fuel injection valve.


In addition, since the curvature radius of the second elastic portion is set larger than the curvature radius of the first elastic portion, the height of each elastic piece is minimized as much as possible, and the supporting member can be easily attached to a narrow space between the first contact surface of the fuel injection valve and the fuel supply cap.


According to a second feature of the present invention, in addition to the first feature, the tip end portion of the second elastic portion is curved away from the base plate.


With the second feature of the present invention, when the supporting member is set between the fuel injection valve and the fuel supply cap, the tip end portion of the second elastic portion, which is curved in the direction which is away from the base plate, can slide over the base plate smoothly in response to the bending of the first and second elastic portions of the elastic piece. For this reason, no forced stress occurs on any of the first and second elastic portions. Accordingly, the first and second elastic portions always exert the predetermined set load appropriately, and can contribute to the stable support of the fuel injection valve.


According to a third feature of the present invention, in addition to the first or second feature, the base plate includes a U-shaped cutout for receiving the fuel injection valve, and the elastic piece is divided into a pair of portions which are arranged side-by-side with a space in between, the space being for receiving the fuel injection valve.


With the third feature of the present invention, since the base plate is set on the contact surface with the fuel injection valve received by the U-shaped cutout in a center portion of the base plate, a larger area can be secured for the placement of the base plate on the contact surface. In addition, since the pair of elastic pieces extending from the one end of the base plate elastically come into pressure contact with the front end surface of the fuel supply cap while receiving the fuel injection valve between the pair of elastic pieces, reaction force produced by the press of the pair of elastic pieces against the fuel supply cap can be made to work on the fuel injection valve along the center axis of the fuel injection valve. Accordingly, the fuel injection valve can be stably supported without being tilted.


The above and other objects, characteristics and advantages of the present invention will be clear from detailed descriptions of the preferred embodiment which will be provided below while referring to the attached drawings.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a partial longitudinal sectional front view showing a fuel injection valve supporting structure for a multi-cylinder engine according to an embodiment of the present invention;



FIG. 2 is an enlarged sectional view taken along a line 2-2 in FIG. 1;



FIG. 3 is a sectional view taken along a line 3-3 in FIG. 2; and



FIG. 4 is a perspective view independently showing a supporting member which has been shown in the other drawings.





DESCRIPTIONS OF THE PREFERRED EMBODIMENT

An embodiment of the present invention will be described below based on the attached drawings.


As shown in FIG. 1 and FIG. 2, first of all, multiple fuel injection valves I capable of injecting fuel to combustion chambers Ec of multiple cylinders and a fuel distribution pipe D configured to distribute the fuel to the fuel injection valves I are attached to a cylinder head Eh of a multi-cylinder engine E. In addition, a supporting member S is interposed between each fuel injection valve I and the fuel distribution pipe D in order that the fuel injection valve I should not be displaced in its axial direction or about a center axis A. Detailed descriptions of the structure will be provided hereinbelow.


Each fuel injection valve I is formed from a cylindrical nozzle portion 2, an electromagnetic coil portion 3 and a fuel introduction portion 4 which are coaxially continuous with one another from a front end toward a rear end of the fuel injection valve I. When electricity is supplied to the electromagnetic coil portion 3, the fuel injection valve I is designed to open a valve inside the nozzle portion 2, and to inject the fuel, which is introduced by the fuel introduction portion 4 from the fuel distribution pipe D, into the corresponding combustion chamber Ec.


In the fuel injection valve I, outer diameters of the nozzle portion 2, the fuel introduction portion 4, and the electromagnetic coil portion 3 are larger in this order. Accordingly, the electromagnetic coil portion 3 has the largest outer diameter. A power supply coupler 14 is integrally projectingly provided to a side surface of the electromagnetic coil portion 3. An annular seal/cushion member 8 in close contact with a front end surface of the electromagnetic coil portion 3 is attached to an outer periphery of the nozzle portion 2. An O-ring 9 is attached to a seal groove 4a in an outer periphery of the fuel introduction portion 4.


An annular and flat first contact surface 5 facing the fuel introduction portion 4 side is formed in a boundary portion between the electromagnetic coil portion 3 and the fuel introduction portion 4. A pair of flat second contact surfaces 6 opposed to each other with a plane C interposed in between is formed of a cutout-shape in an outer peripheral surface of the electromagnetic coil portion 3. In this respect, the plane C includes the center axis A of the fuel injection valve I and a center line B of the coupler 14.


Meanwhile, each cylinder head Eh is provided with: an injection valve attachment hole 10 whose inner end is opened to a ceiling surface of the corresponding combustion chamber Ec; and an annular recessed portion 11 surrounding an outer opening end of the injection valve attachment hole 10. The nozzle portion 2 of the fuel injection valve I is fitted in the injection valve attachment hole 10, and the seal/cushion member 8 is housed in the recessed portion 11.


Furthermore, the fuel distribution pipe D is placed along a direction in which the multiple cylinders of the engine E are arranged. The fuel is designed to be delivered with pressure from an end of the fuel distribution pipe D by means of a fuel pump, which is not illustrated. Multiple fuel supply caps Da which are arranged coaxial with the multiple fuel injection valves I fitted in the multiple injection valve attachment holes 10 are projectingly provided to one side surface of the fuel distribution pipe D. Each fuel supply cap Da is fitted on the outer periphery of the fuel introduction portion 4 of the corresponding fuel injection valve I. At this time, the O-ring 9 is in close contact with an inner peripheral surface of the fuel supply cap Da. A flat third contact surface 7 in parallel with the center axis A of the corresponding fuel injection valve I is formed on an outer side surface of each fuel supply cap Da. A bracket Db is fixedly provided to a base portion of each fuel supply cap Da. The bracket Db is fixedly attached to a support column 12 by a bolt 13, the support column 12 being provided upright on an upper surface of the cylinder head Eh.


As shown in FIG. 2 to FIG. 4, the supporting member S is made by pressing a steel plate, and includes a base plate 15, a pair of elastic pieces 16, a pair of turn stopper pieces 17, and a positioning piece 18.


The base plate 15 is set while overlapping the first contact surface 5. A U-shaped cutout 19 capable of receiving the fuel introduction portion 4 of the fuel injection valve I is provided in a center portion of the base plate 15. The pair of elastic pieces 16 capable of elastically coming into pressure contact with a front end surface of the corresponding fuel supply cap Da are formed in one end, which is an opposite side from the U-shaped cutout 19, of the base plate 15, so as to be integrally connected. The two elastic pieces 16 are arranged with a space capable of receiving the fuel introduction portion 4 of the corresponding fuel injection valve I therebetween.


Each elastic piece 16 is formed from: a first elastic portion 16a extending upwards from the one end of the base plate 15, and bent like the letter U lying horizontally; and a second elastic portion 16b extending towards the other end of the base plate 15 while curving upwards from the first elastic portion 16a, and bringing a tip end portion 16ba thereof into pressure contact with an upper surface of the base plate 15. A curvature radius R2 of the second elastic portion 16b is set sufficiently larger than a curvature radius R1 of the first elastic portion 16a (see FIG. 4).


Furthermore, while each elastic piece 16 is set free, a distance L1 (see FIG. 4) from an apex of the second elastic portion 16b to an undersurface of the base plate 15 is set larger than a distance L2 (see FIG. 2) from the first contact surface 5 to the front end surface of the fuel supply cap Da. For this reason, once the base plate 15 and the elastic pieces 16 are inserted between the first contact surface 5 and the fuel supply cap Da, each elastic piece 16 makes the apex of the second elastic portion 16b elastically come into pressure contact with the front end surface of the fuel supply cap Da while bending the first and second elastic portions 16a, 16b. Thereby, a predetermined set load for pressing the front end surface of the fuel supply cap Da is given to the first and second elastic portions 16a, 16b.


While the first and second elastic portions 16a, 16b are bending, the tip end portion 16ba of the second elastic portion 16b is capable of sliding over an upper surface of the base plate 15. The front end portion 16ba thereof is formed in a shape which is curved in a direction that is away from the base plate 15, that is to say, upwards, to smoothen the sliding thereof. For this reason, when the supporting member S is set there, no forced stress occurs on any of the first and second elastic portions 16a, 16b. Accordingly, the first and second elastic portions 16a, 16b can always exert the predetermined set load appropriately.


The pair of turn stopper pieces 17 are integrally connected to two outer side surfaces of the base plate 15, respectively. Each turn stopper piece 17 formed in the shape of the letter T which is turned upside down includes: a vertical portion 17a extending downwards from the corresponding outer side surface of the base plate 5 in a bending manner; and a horizontal portion 17b extending from a lower end of the vertical portion 17a along the U-shaped cutout 19. The pair of turn stopper pieces 17 are capable of holding the electromagnetic coil portion 3 between and by the pair of turn stopper pieces 17 while bringing their horizontal portions 17b into contact with the respective second contact surfaces 6. Elasticity for biasing the horizontal portions 17b inwards is given to roots of the respective vertical portions 17a to make the pair of turn stopper pieces 17 elastically hold the electromagnetic coil portion 3 between and by the pair of turn stopper pieces 17. Moreover, two end portions 17ba of each horizontal portion 17b are formed in a way that curves outwards.


What is more, the positioning piece 18 vertically standing upwards from an interstice between the pair of elastic pieces 16 is integrally connected to the one end of the base plate 15. The positioning piece 18 is capable of coming into contact with the third contact surface 7 of the fuel supply cap Da.


Next, descriptions will be provided for operations of the embodiment.


When the fuel injection valves I are attached to the engine E, first of all, the fuel supply caps Da of the fuel distribution pipe D are fitted on the fuel introduction portions 4 of the fuel injection valves I, respectively. Subsequently, an assembled body including the fuel distribution pipe D, the fuel injection valves I and the supporting members S is made up by inserting each supporting member S between the first contact surface 5 of the corresponding fuel injection valve I and the corresponding fuel supply cap Da from an outside of the fuel injection valve I, which is on an opposite side from the coupler 14, while putting an opening portion of the U-shaped cutout 19 of the corresponding base plate 15 in the front.


Thereafter, the nozzle portions 2 of the fuel injection valves I of the assembled body are inserted into the injection valve attachment holes 10 of the cylinder head Eh, respectively. The seal/cushion members 8 in close contact with the front end surfaces of the electromagnetic coil portions 3 are housed in the recessed portions 11, respectively. Afterward, the brackets Db are fixedly attached to the support columns 12 of the cylinder head Eh by the bolts 13, while adding compression load to the support members S, respectively.


In each supporting member S, the base plate 15 is set on the first contact surface 5 with the fuel introduction portion 4 of the fuel injection valve I received by the U-shaped cutout 19, and concurrently the pair of elastic pieces 16 elastically bring the apexes of the second elastic portions 16b into pressure contact with the front end surface of the fuel supply cap Da by bending the first and second elastic portions 16a, 16b, while receiving the fuel introduction portion 4 between the elastic pieces 16. Reaction force produced by the pressure contact presses the base plate 15 against the first contact surface 5. Thus, the fuel injection valve I is elastically held between and by the cylinder head Eh and the fuel supply cap Da with the supporting member S and the seal/cushion member 8 interposed between the cylinder head Eh and the fuel supply cap Da.


Moreover, since the base plate 15 is set on the first contact surface 5 with the fuel introduction portion 4 received by the U-shaped cutout 19 situated in the center portion of the base plate 15, a larger area can be secured for the placement of the base plate 15 on the first contact surface 5. In addition, since the pair of elastic pieces 16 extending from the one end of the base plate 15 elastically come into contact with the front end surface of the fuel supply cap Da while receiving the fuel introduction portion 4 between the pair of elastic pieces 16, the reaction force produced by the press of the elastic pieces 16 against the fuel supply cap Da can be made to work on the fuel injection valve I along the center axis A of the fuel injection valve I. Accordingly, the fuel injection valve I can be stably supported without being tilted.


The supporting member S is inserted into the interstice between the first contact surface 5 and the fuel supply cap Da until the fuel introduction portion 4 comes into contact with an inner end of the U-shaped cutout 19. During the insertion, while sliding over the second contact surfaces 6 of the two sides of the electromagnetic coil portion 3, the horizontal portions 17b of the pair of turn stopper pieces 17 of the supporting member S are elastically in contact with the second contact surfaces 6 thereof in a way that the second contact surfaces 6 are held between and by the horizontal portions 17b. In this respect, since the two end portions 17ba of each turn stopper piece 17 are each formed in the outwardly-curved shape, the outwardly-curved surfaces of the two end portions 17ba exert a guidance function of guiding the corresponding one of the second contact surfaces 6 to a center portion of the horizontal portion 17. For this reason, the center portions of the horizontal portions 17b can be smoothly set into predetermined positions on the second contact surfaces 6, respectively. In addition, the slidable surfaces of the horizontal portions 17b over which the second contact surfaces 6 slide are smooth, and accordingly cause the second contact surfaces 6 no damage. Furthermore, when the supporting member S is detached from the fuel injection valve I, the two end portions 17ba of each horizontal portion 17b cause the corresponding one of the second contact surfaces 6 no damage, either. Moreover, since the horizontal portions 17b come into pressure contact with the second contact surfaces 6 by means of the elasticity of the vertical portions 17a, it is possible to inhibit the rotational vibration of the fuel injection valve I.


What is more, since the pair of turn stopper pieces 17 come into contact with the pair of second contact surfaces 6 formed on the outer periphery of the electromagnetic coil portion 3 whose outer diameter is the largest in the fuel injection valve I, it is possible to prevent the turn of the fuel injection valve I by means of relatively small contact force, and accordingly to stabilize the direction in which the fuel is injected from the nozzle portion 2.


When the fuel introduction portion 4 comes into contact with the inner end of the U-shaped cutout 19, the positioning piece 18 of the supporting member S almost simultaneously comes into contact with the third contact surface 7 of the fuel supply cap Da. This contact and the contact of the turn stopper pieces 17 with the respective second contact surfaces 6 restrict the position of the fuel injection valve I about the center axis A of the fuel injection valve I with respect to the fuel supply cap Da. Accordingly, the fuel injection valve I becomes stable at the position.


In addition, each elastic piece 16 is formed from: the first elastic portion 16a connected to the one end portion of the base plate 15, and having the smaller curvature radius R1; and the second elastic portion 16b extending from the first elastic portion 16a, making the tip end portion 16ba slidably come into contact with the upper surface of the other end portion of the base plate 15, and having the larger curvature radius R2. For this reason, the second elastic portion 16b is supported by the base plate 15 via both the front end portion 16ba and the first elastic portion 16a. Thus, since stress produced on each elastic piece 16 when setting the supporting member S is dispersed to the first and second elastic portions 16a, 16b, stress which tends to concentrate particularly on the first elastic portion 16a having the smaller curvature radius R1 can be eased. Accordingly, it is possible to keep the predetermined set load of the elastic piece 16 for a long period of time, and to stabilize the support of the fuel injection valve I.


Moreover, even if the first elastic portion 16a having the smaller curvature radius R1 may plastically deform, the elastic force of the second elastic portion 16b, which is supported by the two portions, can maintain each elastic piece 16's biasing function of biasing the fuel supply cap Da. For this reason, plastic deformation of the first elastic portion 16a will not hinder the support of the fuel injection valve I.


What is more, since the curvature radius R2 of the second elastic portion 16b is set larger than the curvature radius R1 of the first elastic portion 16a, the height of each elastic piece 16 is minimized as much as possible, and the supporting member S can be easily attached to the narrow space between the first contact surface 5 and the fuel supply cap Da.


Although the foregoing descriptions have been provided for an embodiment of the present invention, the present invention is not limited to the embodiment. Various design changes can be made within the scope not departing from the gist of the present invention. For example, the present invention can be applied to a structure in which the fuel injection valve I is attached to an air intake system of the engine.

Claims
  • 1. A fuel injection valve supporting structure in which: a nozzle portion at a front end portion of a fuel injection valve is fitted in an injection valve attachment hole of an engine;a fuel supply cap of a fuel distribution pipe supported by the engine is fitted on a fuel introduction portion at a rear end portion of the fuel injection valve;a supporting member for biasing the fuel injection valve toward the injection valve attachment hole is interposed between the fuel injection valve and the fuel supply cap, whereina contact surface is formed in an intermediate portion of the fuel injection valve, the contact surface being orthogonal to a center axis of the fuel injection valve and opposed to the fuel supply cap,the supporting member includes a flat base plate having a first end and a second end, and is set on the contact surface and the supporting member includes an elastic piece extending from one end of the base plate, the base plate having an upper surface which is formed flat over its second end,wherein the base plate includes a U-shaped cutout for receiving the fuel injection valve, and the elastic piece is divided into a pair of portions, namely a first elastic portion and a second elastic portion, which are arranged side-by-side with the U-shaped cutout in between, the first elastic portion extending upwards from the first end of the base plate and bent in a U-shape, the second elastic portion extending toward the second end of the base plate while curving upwards from the first elastic portion, the second elastic portion having a curved tip portion that is in continuous slideable contact with the upper surface of the base plate, and the tip portion having an end portion that curves upwards away from the base plate, and an apex of the second elastic portion is in pressure contact with a front end surface of the fuel supply cap, and when the supporting member is set between the fuel injection valve and the fuel supply cap, the tip portion of the second elastic portion is slidably abuted against the flat upper surface of the base plate in response to bending of each of the elastic pieces, anda curvature radius of the second elastic portion is set larger than a curvature radius of the first elastic portion.
Priority Claims (1)
Number Date Country Kind
2012-040732 Feb 2012 JP national
US Referenced Citations (31)
Number Name Date Kind
2365785 Tinnerman Dec 1944 A
4993390 Ono et al. Feb 1991 A
5074269 Herbon et al. Dec 1991 A
5136999 Bassler et al. Aug 1992 A
5390638 Hornby Feb 1995 A
5394850 Murphy et al. Mar 1995 A
5803052 Lorraine et al. Sep 1998 A
5820168 De Giacomoni Oct 1998 A
5893351 Akutagawa et al. Apr 1999 A
5970953 Lorraine Oct 1999 A
6042154 Gensert Mar 2000 A
6276339 Shebert, Jr. Aug 2001 B1
6322306 Dutton Nov 2001 B1
6481420 Panasuk Nov 2002 B1
6668803 McClean et al. Dec 2003 B1
6846023 Ebinger Jan 2005 B2
6863053 Suzuki Mar 2005 B2
7063075 Berger et al. Jun 2006 B2
7210462 Scheffel May 2007 B2
7373926 Eckbauer May 2008 B2
7581530 Scheffel Sep 2009 B2
7765984 Fuerst et al. Aug 2010 B2
7802559 Furst Sep 2010 B2
8408184 Marc et al. Apr 2013 B2
8707930 Bolz et al. Apr 2014 B2
20090056674 Furst et al. Mar 2009 A1
20100218743 Marc Sep 2010 A1
20120247426 Roseborsky Oct 2012 A1
20130192565 Roseborsky Aug 2013 A1
20130220276 Nakamura Aug 2013 A1
20140231551 Serra Aug 2014 A1
Foreign Referenced Citations (15)
Number Date Country
102046958 May 2011 CN
10163030 Jul 2003 DE
EP 1544455 Jun 2005 DE
102004046072 Apr 2006 DE
102004046072 Apr 2006 DE
EP 1892408 Feb 2008 DE
102010017725 Jan 2012 DE
1892408 Feb 2008 EP
2492489 Aug 2012 EP
2004-245168 Sep 2004 JP
2010-168964 Aug 2010 JP
2010-168965 Aug 2010 JP
EP 2492489 Aug 2012 KR
03038267 May 2003 WO
03054383 Jul 2003 WO
Non-Patent Literature Citations (2)
Entry
Official Communication dated Feb. 12, 2015 issued in the corresponding Japanese Patent Application 2012-040732.
Official Communications dated Dec. 2, 2014 issued in the corresponding Chinese Patent Application No. 201310061224.9.
Related Publications (1)
Number Date Country
20130220277 A1 Aug 2013 US