US3452727A

US3452727A - Fuel injection system and control transducer apparatus therefor

Info

Publication number: US3452727A
Application number: US687251A
Authority: US
Inventors: Hermann Hoelle; Wilhelm Kind; Hermann Scholl
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 1966-12-06
Filing date: 1967-12-01
Publication date: 1969-07-01
Anticipated expiration: 1986-07-01
Also published as: BE707585A; ES347969A1; DE1526508A1; DK118113B; DE1526508B2; SE335446B; NL6716516A; CH461882A; AT284552B; GB1186200A

Description

y 1, 1969 H. HOELLE ET'AL 3,452,727

FUEL INJECTION SYSTEMAND CONTROL TRANSDUCER- v APPARATUS THEREFOR FiledDeo. 1. 1967 Shegt of? FIGJ E L 5U .L, ,Y Dm E OOWC N WHKS w W En n q T Vnmn T NOIO L A mmm m ll 8 e e, HWHHW m July 1, 1969 H. HOELLE ETAL 3,452,727

FUEL INJECTION SYSTEM AND CONTROL TRANSDUCER APPARATUS THEREFOR 7 Filed Dec. 1, 1967' Sheet of 2 FIGA INVENTORS Hermann HOELLE Wilhelm KIND Hermann SCHOLL their ATTORNEY United States Patent Int. Cl. F02m 51/00 US. Cl. 123-32 8 Claims ABSTRACT OF THE DISCLOSURE A variable inductance transducer, responsive to the degree of vacuum in the intake manifold of an automotive type internal combustion engine is constructed by forming an embracing, toroidal core and winding therein with a central bore, mounting a core element axially movable therein, supported on one side by the movable wall of a vacuum diaphragm and On the other by a spring. To eliminate lateral movement and provide for axial holding of the core, even under severe shock and vibration conditions, the core is held in place by a pair of fiat leaf springs, having substantial stiffness in a radial direction and little resistance to deflection in an axial direction.

The present invention relates to a fuel injection system, and more particularly to a fuel injection system for auto motive type internal combustion engines, in which the injection time is electronically controlled and depends on the subatmospheric pressure in the intake manifold of the engine.

Fuel injection systems for automotive type internal combustion engines have been proposed, in which the fuel is supplied under pressure to fuel injection valves, located near the intake stubs of the cylinders. The opening times of the fuel injection valves are controlled by electronic circuitry, and vary in dependence on the position of a throttle controller, and thus on the vacuum in the intake manifold. A vacuum sensing device is connected to the intake manifold, which changes an operating parameter of the electronic circuit, such as the inductance of a circuit thereof, as the vacuum in the intake manifold changes.

The inductance of an inductive element is most easily changed by moving a core relative to an apertured coil. This motion is controlled by the vacuum in the intake manifold. It is important that the relationship between vacuum and eventual change of inductance of the inductive circuit remain constant during use, and is always the same regardless of a particular transducer element installed in the fuel injection system, in order to obtain the same amount of fuel injected for similar operating conditions and vacuum in the intake manifold. It has been found, however, that due to aging and differences in permeability, such reproducibility of result is difficult to obtain. The change in inductance of the inductive circuit may be in the range of from 1:3; this substantial change in inductance must be obtained with a very small core travel, in the order of about 3 mm.

It is accordingly an object of the present invention to provide a fuel injection system for internal combustion engines, and more particularly for automotive type internal combustion engines, which is rugged and unaffected by age, shock or vibration, provides for reproducible results regardless of the particular transducer installed in the system, and provides for the required change of inductance as determined by operating require ments.

3,452,727 Patented July 1, 1969 Subject matter of the present invention Briefly, in accordance with the present invention, a toroidal core, having toroidal windings thereon is formed with a central aperture in which a core element is axially movably located, with a small air gap between the core and the movable core element. The movable core element is held in position by a pair of flat leaf springs, maintaining the core readily movable in an axial direction, but preventing lateral vibration or shock and presenting substantial stiffness in a radial direction. The movement of the core is controlled by a vacuum chamber, connected to the intake manifold. It is held by a spring against the chamber.

Axial movement of the movable core element, under control of the vacuum chamber, requires little force. The flat leaf spring, however, prevents substantial resistance to lateral, or radial displacement. The air gap between the movable core element and the fixed core, which may be in the order of 0.1 to 0.5 mm. provides for a high reluctance gap which is large with respect to the reluctance of the iron core circuit, so that differences in permeability of materials used in different transducers have but little effect on the final inductance of the element.

A particularly advantageous form of leaf spring is a fiat leaf having a pair of outer frame branches and a central connecting leg, with openings formed thereinbetween so that the shape of the spring is similar to a pair of opposed, joint Es. Such a spring has high stiffness in the plane of the leaf, and little resistance to longitudinal movement transverse to the surface of the leaf.

The structure, organization, and operation of the invention Will now be described more specifically with reference to the accompanying drawings, wherein:

FIG. 1 is a schematic representation of a fuel injection system in accordance with the present invention, a more full disclosure of which is contained in application Ser. No. 680,068, filed Nov. 2, 1967, and assigned to the assignee of the present invention;

FIG. 2 is a longitudinal section along line IIII of FIG. 3 of a vacuum transducer in accordance with the present invention;

FIG. 3 is a sectional view through the vacuum transducer along line III-III of FIG. 2; and

FIG. 4 is a partial longitudinal sectional view of the transducer along line IV-IV of FIG. 3.

The fuel injection system will be briefly explained with reference to FIG. 1. A 4-cylinder internal combustion engine 10 has intake manifold 12. Electromagnetic fuel injection valves 13 are located at the inlet stu-bs of the individual cylinders connecting with inlet manifiold 12. The injection valves 13 are supplied with fuel by fuel lines 14, connecting to a fuel distributor 15 into which fuel is pumped from a tank 17 by a pump 16, to be supplied under pressure to the injection valves 13. An over-pressure valve, not shown, provides for constant pres *sure in the distribution chamber 15, so that the time during which any injection valve 13 is open corresponds to a predetermined amount of fuel. Injection valves 13 each include an electric magnet which, upon being supplied with current, opens the valve. An electronic control consisting essentially of a multivibrator 18 and an amplifier 19 controls the time during which current is supplied to the electromagnetic valves, and thus the opening time during which fuel can be injected. Multivibrator 18 is controlled from an impulse source 22 having a contact 23 operated by a double-rise cam 24 and driven in synchronism with the speed of the engine, for example from the cam shaft thereof, as schematically indicated by the chain-dotted line. Thus, multivibrator 18 will supply two pulses for each revolution of the cam shaft in order to open the injection valves 13.

The time T during which the injection valves 13 are open, that is the time during which a pulse is supplied to valves 13 by the multivibrator 18 is governed by the vacuum in inlet manifold 12. A transducer 25 is connected to the inlet manifold by means of a connecting line 34. Transducer 25 includes an inductive element which changes in inductance in dependence on the vacuum in the inlet manifold. The vacuum Within the inlet manifold 12 is controlled by a throttle controller 26. If the vacuum is high, that is when throttle 26 is closed, the impulse period T will be short, thus causing injection of only little fuel. When the throttle 26 is opened, so that the vacuum drops, the impulse periods increase and thus larger amounts of fuel will be injected.

The pressure transducer, see FIGS. 2-4, has a pair of

housing parts

30, 31, which are arranged in interlocking relationship and sealed against each other by an O-ring 32, so that the interior 33 of the housing is hermetrically closed. Connection line 34 (FIG. 4) connects the interior 33 over a check valve 35 which has a throttle opening 36 therein, with the intake manifold 12. The check valve is so arranged that its opens at a pressure differential of over 0.05 kg./cm.

A cross piece 37, held in position at the junction of the two

housing parts

30, 31 secures a core body 38. Core 38 has a cross-sectional aspect of a double U, and preferably is in toroidal form. It encloses coil 39, which has a pair of separate windings forming part of the multivibrator circuit 18. Core 38 is formed with

bores

42, 43 at its end faces. An iron core element 44 is located in the bore to be axially movable. Core element 44 is slightly smaller than the bore to provide for a radial air gap and for radial play. The upper end (with respect to FIG. 2) of the core element 44 has screw connection with a leaf spring 45. The lower part of core 44 is provided with a frustoconical portion 41 and connected to a shaft or stub 46 of non-magnetic material, such as brass. A leaf spring 47 is connected, for example by a screw connection, with the stub 46.

Leaf spring 47 is identical with leaf spring 45, and seen best in FIG. 3. The plan view of the spring corresponds to approximately a pair of facing Es. Such a spring provides substantial resistance against radial movement of the core element 44, but on the other hand provides but little stiffness or resistance against axial movement of the core element. This is important because, when used with an automotive type internal combustion engine, vibration and shock forces act on the iron core 44. The arrangement in accordance with the present invention provides for steady and sure guidance of core 44, without the necessity of providing a bearing in the

bores

42, 43. Thus, core element 44 can move axially without bearing friction and change its position with respect to coil 39 even at small changes of pressure in the manifold 12. A radial gap of from 0.1 to 0.5 mm. between the core elrnent 44 and iron core 38 decreases the effects of changes in permeability of core 38 and core element 44 on the inductivity of coil 39.

Leaf spring 47, and its matching leaf spring 45, each have a pair of outer or frame

legs

49, 50 and a centrally connecting leg 48. As best seen in FIG. 3, both

leaf springs

47 and 45, respectively, are connected by means of their central leg 48 with core element 44. The

outer frame portions

49, 50 are screwed to cross

plates

37, and 55, respectively, with intervening spacers 53, 54 (FIG. 4).

Spacers

53, 54 have been omitted from the showing in FIG. 2 for simplicity. Cross plate 45, is in turn, connected to core 38.

The core element 44 is pressed against a pair of evacuated

chambers

58, 59, by means of a spring 56, the other end of which bears against an adjustable screw cap 57, screwed into housing part 30.

Vacuum chambers

58, 59 themselves are held against the housing part 31 by means of an adjustment screw 62. As best seen in FIG. 2, vacuum to be movably connected with respect to adjustment screws 62 and the brass stub 46 carrying core 44, in order to provide a floating self-aligning arrangement which does not place any radial load on leaf springs 45, and additionally greatly simplifying assembly of the entire transducer unit.

Upper housing element 30 has an electrical connector 65 located therein, air-tight and connected to the respective terminals of coil 39.

Operation Core element 40 is pressed against the

vacuum chambers

58, 59 by means of spring 56. If the vacuum in the intake manifold 12, and hence in the chamber 33 is high,

vacuum chambers

58, 59 expand due to their inherent resiliency, and core element 44 is pressed upwardly (with respect to FIG. 2), thus decreasing inductivity of the coil 39. The amount of fuel injected by the system of FIG. 1 is correspondingly decreased. Upon opening of throttle 26, the vacuum in intake manifold 12, and hence in chamber 33 decreases. If the vacuum drops sharply, the check valve 35 may open. The increased pressure Within chamber 33 compresses

vacuum chambers

58, 59, and core element 44 is moved downwardly, with respect to FIG. 2, by action of the spring 56. This increases the inductivity of the coil 39 and the injection period of valves 13 likewise increases.

The functional relationship between vacuum in chamber 33 and inductivity of coil 39 can further be adjusted by forming the core element 44 other than cylindrically, for example by grinding off a portion of its circumference at its lower end, so that the cross-sectional area at one end of the core element 44 will be different from that at the other end thereof, as shown at the frustoconical portion 41. Various structural changes and modifications, as determined by the requirements of particular applications or uses may be made Without departing from the inventive concept.

We claim:

1. Fuel injection system for internal combustion engines comprising electronic pulse source means synchronized with the rotation of said engine controlling the operation of said valves to inject fuel into said engine;

and transducer means connected to the intake manifold of the engine to sense the vacuum thereof and control the operating parameters of said electronic means, said transducer means comprising a fixed core having a central bore;

windings linking the magnetic circuit of said fixed core, a movable iron core located in said bore for axial displacement therein and having a radial air gap with respect to said core;

a pair of leaf springs retaining said core element in said bore, said leaf springs being mounted to provide substantial stiffness against radial displacement of said core element in said bore and having little stiffness with respect to axial displacement of said core element, at least one of said leaf springs being in the form of a flat leaf having an outer frame and a central connecting leg with openings between said frame and said leg;

and vacuum means connected to the intake manifold of said engine to sense the vacuum thereof and in motion transmitting engagement with said movable core element.

2. System as claimed in claim 1, wherein a pair of leaf springs is provided, each leaf spring having an outer frame and a central connecting leg;

said outer frames being secured to said fixed core and said central connecting legs being secured to said movable core element. I

3. Sensing and controlled transducer assembly for

autochambers

58, 59 are provided with bearing points 63, 64 motive engine fuel injection systems adapted to be con.-

nected to the intake manifold of the engine, said assembly comprising a housing; said housing being formed with a connec tion opening for connection to said manifold;

a circular core having an axial opening therein;

windings located in said core;

a core element located in said axial opening, with clearance, and movable axially of said windings therein;

a vacuum chamber located in said housing and having a movable wall, said movable wall and said core element being in motion transmitting contact with each other;

and a pair of leaf springs having their fiat surface located transversely to the axis of said axial opening and centering said core element in said opening for free axial movement with respect thereto while restraining lateral excursions of said element in said opening, said leaf springs having outer frame portions and a central leg portion, with openings between said frame and said leg portions, said frame portions being secured to opposite sides of said core, and said central leg portions being secured to opposite sides of said axially movable core element.

4. Assembly as claimed in claim 3, wherein said leaf springs have outer frame portions and a central connecting leg portion, with openings between said frame and said leg portions; and said frame portions are secured to opposite sides of said core, said central leg portions being secured to opposite sides of said axially movable core element.

5. Assembly as claimed in claim 3, wherein at least one of said leaf springs is in the form of a flat leaf having an outer frame and a central connecting leg with openings between said frame and said leg.

6. Assembly as claimed in claim 3, wherein the crosssectional area of said core element is different at one end from the cross-sectional area at the other end.

7. Assembly as claimed in claim 6, wherein said core element is provided with a substantially frustoconical portion at its end extending into said axial opening.

8. Assembly as claimed in claim 3, wherein at least one evacuated chamber is supported within said housing, said evacuated chamber having a movable wall bearing against said core element; and

resilient means biasing said core element into engagement with the movable wall of said evacuated chamber.

References Cited UNITED STATES PATENTS 2,918,911 12/1959 Guiot 12332 3,068,849 12/1962 Thorner 123103 3,338,221 8/1967 School.

LAURENCE M. GOODRIDGE, Primary Examiner.

US. Cl. X.R. 123 119, 1.39