JPH04325769A - Fuel injector used for internal combustion engine - Google Patents

Abstract

PURPOSE: To provide an advanced retainer which is easily and accurately formed at a low cost, is easily and accurately connected with an injector body during manufacture, and can prevent leakage on an interface between the injector body and a silicon valve. CONSTITUTION: An injector body 12 has a first portion 14 with an inlet for communicating with a fuel source and a second portion 16 having an outlet for ejecting fuel from the injector. A silicon nozzle 40 is positioned adjacent to the second portion 16 for dispersing fuel. The nozzle 40 is retained against the second portion 16 by a retainer 50. The retainer 50 includes a side portion 52 and a base portion 54 extending at an angle relative to the side portion 52 for applying a spring-biased force against the nozzle 40 to retain the nozzle, thereby the retainer can be easily and accurately manufactured and an interface 56 between the nozzle 40 and the injector body 12 can be sealed from fuel leakage.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates generally to fuel injectors having silicone nozzles, and more particularly to fuel injectors having a retainer that applies a spring biasing force to the silicone nozzle to hold it against the fuel injector body.

0002

BACKGROUND OF THE INVENTION Fuel injectors using silicone nozzles to meter and spread fuel as it is ejected are known in the prior art. Retainers for securing silicone nozzles to fuel injector bodies are also known in the art. For example, U.S. Pat. No. 4,768,751 discloses a retainer that threadably engages the injector body to retain the valve plate and nozzle plate at the bottom of the injector body. A disc spring is provided within the retainer and applies an upward force to the valve plate and nozzle plate. Because the retainer is threaded into the injector body, accurately determines when the retainer is properly positioned on the injector body to ensure proper upward force on the valve plate and nozzle plate. It is extremely difficult to do so. This cage is therefore highly impractical from a manufacturing point of view. Additionally, the need to use disc springs increases cost.

It is also known to use a retainer having side walls and a bottom wall extending 90° to the side walls to retain the silicon nozzle relative to the injector body. The bottom wall holds the silicon nozzle against the injector body without applying a spring biasing force to the silicon nozzle. Thus, as fuel is injected from the injector, the fuel pressure applied to the silicone nozzle tends to force the silicone nozzle away from the injector body, thereby causing fuel to leak from the intermediate surface between the silicone nozzle and the injector body. Local deformation and temperature changes also cause the silicon nozzle to separate from the injector body, which also causes leakage from the interface between the nozzle and the injector body.

0004

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to be easily and accurately formed at low cost, to be easily and accurately connected to an injector body during manufacture, and to be able to connect the injector body to a silicone valve. There is a need for an improved retainer that can prevent leakage at the intermediate plane of the retainer.

[0005]

SUMMARY OF THE INVENTION This need is solved by the present invention having a side wall and a bottom wall extending at an acute angle to the side wall, the bottom wall being made of silicone when initially attached to the injector body. deformed relative to the nozzle. Therefore,
The bottom wall may apply a spring biasing force against the silicon nozzle to retain the silicon nozzle against the injector body, thereby substantially sealing the intermediate surface between the silicon nozzle and the injector body. According to one feature of the invention, a fuel injector for use in an internal combustion engine includes an injector body having a first portion having an inlet communicating with a fuel source, a second portion having an outlet for ejecting fuel from the body, and It has an internal passage that communicates the inlet and the outlet. A fuel valve arrangement is located within the internal passageway to control fuel injection from the outlet. A nozzle arrangement is located adjacent the second section to meter and diffuse the fuel as it is ejected from the outlet. A retainer device is coupled to the injector body and retains the nozzle device against the second portion. The retainer device has sides and a base, the base extending at an angle to the sides and applying a spring biasing force against the nozzle device to retain the nozzle device against the second portion, thereby retaining the nozzle device against the second portion. Leakage from an intermediate surface between the nozzle device and the second portion is substantially sealed.

Preferably, the nozzle arrangement comprises at least one silicon nozzle plate that is substantially square and has one or more openings. Preferably, the base of the retainer arrangement is at an acute angle to the side of the injector body to apply a spring biasing force to the nozzle arrangement. The base of the retainer device is deformed relative to the nozzle device before the retainer is connected to the injector body and a spring bias is generated. The retainer device can be welded or crimped or snapped onto the injector body. In a first embodiment of the invention, the sides of the retainer device have a generally cylindrical upper portion having a first inner diameter, a generally cylindrical lower portion having a second inner diameter, and an intermediate connecting portion interposed therebetween. The silicone nozzle plate is disposed within the cylindrical lower portion, and the second inner diameter of the lower portion is approximately equal to each diagonal of the silicone nozzle plate. As such, the silicon nozzle plate is held in place under the second portion of the injector body and is prevented from moving laterally within the retainer arrangement.

In a second embodiment of the invention, the second portion of the injector body has a recess for receiving a silicon nozzle plate. The base of the injector body serves to hold the nozzle plate in the recess by applying a spring bias to the nozzle plate. According to a second feature of the invention, the fuel injector includes a first portion having an inlet communicating with a fuel source, an outlet for ejecting fuel from the injector, and a second portion having an internal passageway communicating the inlet and the outlet. having an injector body with a section. A fuel valve arrangement is located within the internal passageway to control fuel injection from the outlet. A silicone nozzle arrangement is located adjacent the second portion of the injector body to meter and diffuse fuel as it exits the outlet. A retainer device is coupled to the injector body and retains the silicon nozzle device against the second portion. The retainer device has sides and a base, the base extending at an angle to the sides and applying a spring biasing force against the nozzle device to retain the nozzle device against the second portion, thereby retaining the nozzle device. Fuel leakage from an intermediate surface between the device and the second part is substantially sealed.

The sides of the retainer device have an upper portion, a lower portion and an intermediate connecting portion interposed therebetween as described with respect to the first embodiment with the first feature of the invention. Otherwise, the second part of the injector body is recessed to receive a silicon nozzle as described with respect to the second embodiment of the first aspect of the invention. According to a preferred embodiment of the invention, it is an object of the invention to provide a retainer device that can be easily and accurately connected to the injector body during manufacture. Another object of the present invention is to apply a spring bias force to the silicone nozzle to retain the silicone nozzle in the fuel injector body, thereby substantially sealing fuel leakage from the interface between the silicone nozzle and the fuel injector body. be. Yet another object of the invention is to provide a side wall with a retainer having an inner diameter approximately equal to the diagonal of the silicone nozzle, the retainer retaining the silicone nozzle in position below the injector body and lateral to the silicone nozzle within the retainer. The object of the present invention is to provide a retainer that substantially prevents directional movement.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the fuel injector of the present invention is indicated generally by the numeral 10 in FIG. fuel injector 10
has a first upper portion 14 and a second lower portion 16. First portion 14 has an inlet 18 that communicates with a fuel source (not shown). The second portion 18 has a substantially flat bottom wall 17
and an outlet 20 for spouting fuel from the main body 12. Injector body 12 further has an internal passageway 22 communicating between inlet 18 and outlet 20. Internal passage 2 of injector body 12
A needle valve 30 is installed within 2 and serves to control the amount of fuel that is ejected from the outlet 20. The needle valve 30 is the needle 3
2 and a valve seat 34, when in the closed position the valve seat 34
A needle 32 is seated on the . A conventional solenoid-type actuator and return spring arrangement (not shown) is provided within the injector body 12 to raise and lower the needle 32 within the internal passageway 22 to eject fuel from the outlet 20. Otherwise, a piezoelectric drive, such as that disclosed in U.S. Pat. can do.

As shown in FIGS. 1 and 2, a silicone nozzle device 40 having two silicone nozzle plates 42 and 44 joined together is held against the bottom wall 17 of the injector body 12 so that the fuel can flow through the outlet. Meter and diffuse as it ejects from 20. The top plate 42 has four orifices 42a.
However, the bottom plate 44 has only one orifice 44a. Orifices 42a and 44a serve to guide the fuel as it flows through nozzle plates 42 and 44. Silicone nozzle plates 42 and 44 are substantially similar to those disclosed in U.S. Pat. No. 4,828,184;
Reference is made to this disclosure here. It is also within the scope of the invention to use only one nozzle plate instead of two nozzle plates 42 and 44.

A retainer 50 is provided to retain the silicon nozzle plates 42 and 44 against the bottom wall 17 of the injector body 12. Retainer 50 has sides 52 and a base 54 , with base 54 extending at an acute angle to sides 52 . Preferably, cage 50 is manufactured by stamping from stainless steel. However, the retainer 50 can also be made from beryllium copper or from a polymeric material. Retainer 50 is pressurized and attached to and coupled to injector body 12 . The retainer 50 can be welded or crimped or snapped onto the injector body, as shown in FIG. Because the retainer 50 is installed under pressure, the base 54 is deformed relative to the bottom silicon plate 44 such that the spring biasing force is applied by the base 54 to the silicon plate 42.
and added to 44. Deformation of base 54 slightly increases angle Φ. Because the base 54 extends at an acute angle Φ with respect to the sides 52 and because the retainer 50 is pressurized to the injector body 12, spring bias is almost always maintained on the plates 42 and 44, thereby causing the upper plate to 42 and the intermediate surface 56 of the bottom wall 17 is substantially sealed against fuel leakage.

The sides 52 of the retainer include a generally cylindrical upper portion 52a having a first inner diameter D1, a generally cylindrical lower portion 52b having a second inner diameter D2, and an intermediate portion 52c interposed therebetween. has. Silicon nozzle plate 42
and 44 is a cylindrical lower portion 52 as shown in FIGS.
It is set within b. Second inner diameter D of lower portion 52b
2 is approximately equal to the diagonal of silicon nozzle plates 42 and 44. Thus, the lower portion 52b of the retainer 50 acts to hold the silicone nozzle plates 42 and 44 in position below the second portion 16 of the injector body 12 such that the nozzle plates 42 and 44 remain within the retainer 50. Prevent it from moving sideways.

5-7, a second embodiment of the fuel injector of the present invention is designated at 10'. fuel injector 1
0' has an injector body 12' that is substantially similar to the injector body 12 shown in FIGS. However, the second portion 16' of the injector body 12' has a recess 19 for receiving the nozzle arrangement 40'. The nozzle arrangement 40' meters the fuel and disperses it in a spray as it exits the outlet 20'. As best shown in FIG. 8, the nozzle arrangement 40' includes at least one orifice 42a'.
There is only one nozzle plate 42' having a diameter. The nozzle arrangement 40' may otherwise include two nozzle plates, as already described with respect to the first embodiment of the invention.

A retainer 50' is provided to retain the silicon nozzle plate 42' within the recess 19. Retainer 50
' has generally cylindrical sides 52' and a base 54';
The base 54' extends at an acute angle α to the sides 52' (see FIG. 7). The retainer 50' is pressurized and the injector body 1
2' is attached and connected. The retainer 50' may be welded to the injector body 12' as shown in FIG. 5, or it may be crimped or snapped onto the injector body 12'. base 54'
extends at an acute angle to the side 52' and the retainer 50'
is pressurized and attached to the injector body, the applied force is maintained against plate 42' at most of the time, thereby ensuring that the intermediate surface 56' between plate 42' and lower wall 17' is substantially free of fuel. Sealed against leaks.

The fuel injector according to the present invention includes a silicon nozzle retainer that applies a spring bias force to the silicon nozzle to hold it against the injector body. The retainer is easy to manufacture at low cost and can be easily and accurately connected to the injector body during manufacture. Because the retainer applies a spring bias force to the silicone nozzle to hold it against the injector body, the intermediate surface between the silicone nozzle and the injector body is substantially sealed from fuel leakage. Although the invention has been described on the basis of preferred embodiments, it goes without saying that modifications and changes can be made without departing from the scope of the invention as defined by the claims.

[0016]

According to the present invention, the retainer device has a side portion and a base portion, and the base portion extends at an angle with respect to the side portions, so that the base portion applies a spring biasing force to the nozzle device to retain it. Therefore, it can be manufactured easily and accurately, and leakage of fuel from the intermediate surface between the nozzle device and the injector body is prevented.

[Brief explanation of drawings]

FIG. 1 is a partially sectional side view of a first embodiment of the fuel injector of the present invention.

FIG. 2 is an enlarged view of a second portion of the injector body shown in FIG. 1;

FIG. 3 is a top view of the cage shown in FIG. 1 with a silicon nozzle installed therein;

4 is a cross-sectional view taken generally along line 4-4 of FIG. 3 but with the silicon nozzle removed from the retainer; FIG.

FIG. 5 is a partially sectional side view of the lower portion of the second embodiment of the fuel injector of the present invention.

FIG. 6 is a top view of the retainer shown in FIG. 5;

FIG. 7 is a cross-sectional side view taken generally along line 7-7 of FIG. 6;

FIG. 8 is a plan view of the silicon nozzle device shown in FIG. 5;

[Explanation of symbols]

10 Fuel injector 12 Injector body 14 First part 16 Second part 18 Entrance 19 Recess 20 Exit 22 Internal passage 32 Fuel valve 40 Silicon nozzle 42 Nozzle plate 44 Nozzle plate 50 Cage 52 Side part 54 Base 56 Intermediate surface

Claims (2)

[Claims] 1. A first part having an inlet communicating with a fuel source; a first part having an outlet for injecting fuel from an injector;
and an injector body including an internal passage communicating the inlet and the outlet, a fuel valve device installed in the internal passage to control fuel injection from the outlet, and a fuel valve device installed adjacent to the second part to allow fuel to flow through the injector. a nozzle device for dispersing fuel when ejected from the outlet; and a retainer device connected to the injector body to hold the nozzle device against the second portion, the retainer device having side and a base portion extending at an angle to the side portions and applying a spring biasing force to the nozzle device to retain the nozzle device against the second portion, thereby retaining the nozzle device and the second portion; A fuel injector for use in an internal combustion engine, which substantially seals an intermediate surface between the second part and the second part to prevent fuel from leaking. 2. A first portion having an inlet communicating with a fuel source; a first portion having an outlet for ejecting fuel from an injector;
and an injector body including an internal passage communicating the inlet and the outlet, a fuel valve device installed in the internal passage and controlling fuel injection from the outlet, and an injector body adjacent to the second portion of the injector body. a silicone nozzle device installed at the outlet for metering and dispersing the fuel as it is ejected from the outlet;
and a retainer device coupled to the injector body to hold the silicone nozzle device against the second portion, the retainer device having a side and a base, the base being connected to the side. and retains the nozzle arrangement against the second portion by applying a spring biasing force to the nozzle arrangement such that the intermediate surface between the nozzle arrangement and the second portion is in contact with the fuel. A fuel injector that virtually seals against leakage.