US3779225A - Reciprocating plunger type fuel injection pump having electromagnetically operated control port - Google Patents

Abstract

A fuel injection system for an internal combustion engine of the type having a reciprocating piston pressure pump that includes an electromechanically operated relief or control valve that is arranged so that the face of the valve is not subjected to the pressurized fluid in the pumping chamber, thereby requiring less electromechanical energy to open and close the valve. In this type of arrangement it is now possible to control the opening and closing of the relief valve independently of the reciprocating motion of the piston which pressurizes the fuel in timed relation to rotation of the camshaft or crankshaft of an internal combustion engine.

Description

United States Patent 1191 Watson et al.

[ Dec. 18, 1973 RECIPROCATING PLUNGER TYPE FUEL 2,863 437 12/1958 Bessiere 123/32 AE INJECTION M HAVING 3,191,812 6/1965 Asaka et a1 123/139 AM 3.417.703 12/1968 Eckert et a1. 123/139 AQ ELECTROMAGNETICALLY OPERATED CONTROL PORT Primary ExaminerLaurence M. Goodridge 1 lnvemofsi Edwin waison Sidney, Assistant ExaminerCort Flint Harlan Fuller, DOYIBSIOWH, At10rneyRaymond J. Eifler et a1. [73] Assignee: The Bendix Corporation, Southfield,

Mich. [57] ABSTRACT [22] Filed; June 8 1972 A fuel injection system for an internal combustion engine of the type having a reciprocating piston pressure PP N04 260,882 pump that includes an electromechanically operated relief or control valve that is arranged so that the face [52 US. (:1. 123/139 E, 123/32 AE vaive is not subjected to the Pressurized fluid in 51 Int. Cl.F02d 5/00 Pumping chamber, thereby requiring less electio- [58] Field of Search 123/139 E, 139 AM, mechanical energy to P and close the valvein this 123/139 AK, 32A5 32 EA type of arrangement it is now possible to control the opening and closing of the relief valve independently [56] References Cited of the reciprocating motion of the piston which pressurizes the fuel in timed relation to rotation of the UNITED STATES PATENTS camshaft or crankshaft of an internal combustion enl,664.610 4/1928 French 123/32 AE gine 2077,25) 4/1937 Planiol 123/139 E 2,598,528 5/1952 French 123/32AE 6 Claims, 3 Drawing Figures T0 ENGINE CYLINDER 57 I 52 i 5G :2g 50g g 24 1 11 28 -1Lr|1%u11W l a z a f 10i k 5 l i 1t 6 0 27j 3 6 a tjarfla PATENTEDUEB 18 ms 3.779.225

sum 10F 2 TO ENGINE CYLINDER FIGURE I PATENTEDUEC 18 I975 3; 779.225

FIGURE 2 FIGURE 3 RECIPROCATING PLUNGER TYPE FUEL INJECTION PUMP HAVING ELECTROMAGNETICALLY OPERATED CONTROL PORT BACKGROUND OF THE INVENTION This invention relates to an internal combustion engine fuel injection system of the type having a source of fuel, a fuel pump for pressu'rizing the fuel, and one or more injectors or nozzle assemblies for injecting fuel into the engine cylinders. The invention is more particularly related to an improved pump of the type having a reciprocating piston for pressurizing fluid and a solenoid-operated control valve for controlling the amount of fluid dispensed by the pump.

Mechanical fuel injection systems for internal combustion engines generally include a fuel tank; the fuel pump that receives fuel from the tank and pressurizes the fuel; and one or more nozzle valve assemblies that receive the pressurized fuel and inject it into the engine cylinder. The fuel pump which pressurizes the fuel to be supplied to the engine cylinders may be of the rotary or reciprocating piston or plunger type. An example of a rotary injection fuel pump may be found in U.S. Pat. No. 3,489,091 entitled Rotary Distributor Pump, issued Jan. 13 1970 to P. Becker. Examples of fuel injection pumps that operate on the principle of a reciprocating piston or plunger may be found in U.S. Pat. Nos. 2,922,581 entitled Fuel Injection Apparatusissued Jan. 26, 1960 to L. J. Garday; 3,146,715 entitled Fuel Injection Pump, issued Sept. 1, 1964 to G. J. Knudson; and 3,190,561 entitled Fuel Injector, issued June 22, 1965 to H. I. Fuller et al.

Fuel pumps of the reciprocating piston type generally include a housing; a piston mounted for reciprocating movement within the housing, the piston cooperatively linked to the crankshaft or camshaft of an internal combustion engine so that rotation of the camshaft causes reciprocation of the piston within the pump housing; and a pressure chamber, one wall of which is the face of the reciprocating piston, the pressure chamber having an inlet port, a relief (bypass) port and an injection port. In all of the reciprocating type pumps the piston includes a passageway (generally a groove or passage in the piston) that periodically links the pressure chamber to the relief port during the stroke of the piston. The shape and arrangement of the passage and the piston are designed so that radial adjustment of the piston (by rotating the piston) from one position to another affects the periodic linking of the relief port to the pressure chamber, thereby controlling injection time and hence the volume of fuel injected into an engine cylinder. Therefore, the quantity of fuel injected into the engine is determined by radially adjusting (rotating) the reciprocating pistons which are mechanically linked to the camshaft of the engine. Because the piston is mechanically linked to the camshaft, the point in time at which fuel is injected into the engine cylinders is generally fixed with respect to the degree of rotation of the camshaft from a common reference point.

Another limitation and disadvantage associated with fuel pumps of the reciprocating piston type is that the reciprocating piston determines the beginning of the injection cycle, i.e., the piston starts the beginning of the injection cycle when it closes the inlet port and the piston begins to build up pressure in the pressure chamber until the pressure reaches a point that causes the injection port to be opened and fuel to be injected into the engine cylinder. In most systems, once a reciprocating fuel pump is installed, the reciprocating piston is mechanically linked to the engine camshaft or crankshaft so that the inlet port always closes when the camshaft reaches the same degree of rotation. A common approach of making the closing of the inlet port vary with respect to the degree of rotation of the camshaft is to introduce a mechanical translator between the engine camshaft and the pump piston. However, mechanical translators (timing advance mechanisms) are both bulky and expensive, which of course is undesirable for commercial fuel injection systems. Another solution to the problem was to eliminate the reciprocating piston and employ a solenoid-operated injector which is electronically controlled by sophisticated switching circuitry. However, this type of system requires an extremely high pressure pump, more expensive electromechanical and electrical components, and very complex injectors.

Therefore, to control the amount of fuel injected into an internal combustion engine over a wide range of engine speeds, inventors have attempted to modify the fuel pump of the reciprocating piston type in a manner so as to control the inlet port opening and closing. Having failed to do this in an economical and practical way, the art has turned toward electronic fuel injection systems which do not employ a fuel pump of the reciprocating piston type and which are relatively expensive and complex.

SUMMARY OF THE INVENTION This invention provides a mechanical fuel injection control system that utilizes a reciprocating piston type fuel pump that is capable of varying the amount of fuel injected into the engine cylinder at fixed and/or at different speeds of rotation of the engine cam and/or crank-shaft.

The invention is a fuel injection pump for an internal combustion engine characterized by an electromechanically operated control or relief valve assembly (27) that is controlled independently of a reciprocating piston (31) in the pump that pressurizes the fluid. The invention is also characterized by an electromechanical relief (control) valve (20) that has a valve face (23) that is not subject to the pressure in a pressure chamber so that the valve requires less electromechanical energy to open and close.

In one embodiment of the invention the fuel injection system for an internal combustion engine of the type having a camshaft comprises: a pump housing (I) having a pressure chamber (10) that communicates with an inlet passage (6), a relief passage (3) and an injection passage (15), the injection passage communicating with the engine; means for supplying fuel to the pumping chamber through said inlet passage; means for closing the injection passage (15), the closing means including biasing means (52), for keeping the injection passage closed until a predetermined fuel pressure is attained in the pumping chamber; means (30) responsive to the rotation of the engine camshaft or crank shaft for periodically pressurizing the fuel in the chamber (10) whereby fuel entering the chamber through the inlet passage periodically flows out of the pumping chamber through the relief (bypass) passage; and electro-mechanical valves means (27) operative to open and close the relief passage (3) at predetermined intervals in response to at least one operating parameter of the engine whereby each time the relief (bypass) passage (3) is closed and fuel is being pressurized, the fuel pressure in the pumping chamber attains a predetermined pressure level at which the injection passage is opened, thereby injecting fuel into the engine. This type of pump assembly makes it possible to open and close the relief passage independently'of the reciprocating motion of theplunger 31.

Accordingly, it is an object of this invention to pro vide a fuel injection pump of a reciprocating piston type wherein the control of the relief valve is independent of the reciprocating piston.

It is another object of this invention to provide a control valve assembly for the relief (bypass) port'of the pressure chamber wherein the axial movement of the valve is not biased by pressurized fluid within the pumping chamber.

It is still another object of this invention to eliminate the need for bulky and expensive mechanical timing devices between an internal combustion engine and a fuel injection'pump.

It is yet another objectof this invention to provide a control valve for a pressure chamber that permits a maximum flow rate to be obtained over a minimum amount of valve travel.

It is still another object of this invention to combine a novel means to control the amount and duration of fuel delivery with a fuel pump of known characteristics, thereby improving the versatility of fuel injector pumps of the reciprocating piston type.

It is also an object of this invention to provide a means for controlling fuel quantity and timing by utilizing a solenoid-operated control valve responding to one or more engine parameters.

The above and other objects and features of the invention wlll become apparent from the following detailed description taken in conjunction with the accompanying drawings and claims which form a part of this specification.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 illustrates a fuel pump for an internal combustion engine that incorporates the principles of this invention.

FIG. 2 is an enlarged partial diagrammatic view showing the valve portion of the solenoid and the reciprocating plunger.

FIG. 3 is a diagrammatic top view of the pressure chamber taken along lines III--III in FIG. 2.

DETAILED DESCRIPTION OF THE DRAWINGS Referring now to the drawings, FIG. 1 illustrates a fuel injection pump ll of the type having a reciprocatingpiston assembly 30 for pressurizing the fuel in response to rotation of an internal combustion engine (not shown), a solenoid-operated relief orcontrol valve assembly 27 that is controlled independently of the reciprocatingpiston assembly 30, and an injection ordelivery valve assembly 50 that communicates with the engine cylinder.

The reciprocatingpiston assembly 30 comprises: acan follower 32 that follows the camshaft or crankshaft of an internal combustion engine (not shown); aspring assembly 33 which maintains thecam follower 32 in contact with the camshaft; and apiston 31 which reciprocates in the bore ofhousing 60.

Theelectromegnetic valve assembly 27 comprises: a coil ofwire 24 which receives power from a source (not shown); and a valve orsolenoid core 20 which is axially movable in response to energization of thecoil 24.Spring 28biases valve 20 axially in the open position so that energization of thesolenoid coil 24 is required to close thevalve 20. Themovable valve 20 includes ahollow portion 21, the purpose of which is to decrease the mass of the core so that less electromagnetic energy is required to move thevalve 20. Thevalve 20 includes anend face 23 which terminates within thehousing 60. An important feature of thevalve 20 is theannular groove 2 therein whichlinks relief passage 3 with thebore 10 in the housing when thevalve 20 is extended to its farthest position from thecoil 24. Obviously, portions of thecore 20 not required to be responsive to the solenoid can be fabricated from materials other than iron.

Thepump assembly 1 further includes a source orsupply chamber 5 which supplies fuel to a-pressurechamber 10 through (inlet)passage 6. Thesupply chamber 5 also communicates with thepressure chamber 10 through (relief)passage 3 and the passage formed by theannular groove 2 of thevalve 20 when thevalve 20 is in the position shown.

In the FIGURE shown,passage 6 is closed because of the position ofpiston 31 and therelief passage 3 is open because of the position of thesolenoid valve 20. Therefore, theinlet passage 6 of thepressure chamber 10 is closed and therelief passage 3 is open, preventing pressurizing of the fuel inchamber 10 by thepiston 31.

Thefuel injection pump 1 further includes aninjection valve assembly 50 which includes: a delivery valve 51; a valve seat 49 for receiving valve 51; aspring assembly 52 for maintaining the valve 51 in a closed position until a predetermined pressure is attained inchamber 10, the valve 51 and valve seat 49 being disposed in achamber 15 that communicates withpassages 56 and 57 that lead to the engine cylinder. The valve 51 is shown in the closed position which prevents fuel inpressure chamber 10 from communicating with the fluid inchamber 15 and thereby injecting fuel into the engine. The valve 51 is biased closed byspring 52 so that valve 51 does not open until the pressure in thepassage 10 reaches a predetermined pressure level which is much greater than any pressure level of the fluid in thesupply chamber 5. FIG. 1 illustrates the pressurizingpiston 31 at the top of its stroke and the solenoid valve positioned so that thepumping chamber 10 communicates with thesupply chamber 5 throughpassage 3 so that the pressure inchamber 10 is not appreciably greater than the pressure within thesupply chamber 5.

FIG. 2 is an enlarged cross-sectional diagrammatic view of the pump assembly shown in FIG. 1. In this diagrammatic view thesupply chamber 5 communicates with thepressure chamber 10 only through theinlet passage 6 because theiron core 20 of the solenoid valve has been moved to a position to block therelief passage 3 that would otherwise communicate with thepressure chamber 10. This diagrammatic view illustrates that aspiston 31 rises to point A, it closes the inlet port connected to thesupply chamber 5, thereby allowing the fuel in thechamber 10 to be pressurized as the volume of the chamber decreases. When the pressure of the fluid inchamber 10 reaches a predetermined pressure value, valve 51 (FIG. 1) opens, allowing fluid to flow around thevalve body 20 through the injector valve assembly (50, FIG. 1) and to the internal combustion engine (not shown). Another feature of the invention which can be seen in FIG. 2 is the fact that theface 23 of thevalve 20 is not subject to the pressure inchamber 10. If theelectromagnetic valve face 23 terminated withinchamber 10, it would be subject to pressures that would require additional electromagnetic force to move thevalve body 20. Further, since the movement of thevalve 20 is independent of the operation of thereciprocating piston 31, control and injection of fuel into an engine cylinder may be started and stopped at any point in time regardless of the angle of rotation of the camshaft. This is an important feature of this invention in that prior art reciprocating type fuel injection pumps were not capable of obtaining this feature.

FIG. 3 is a diagrammatic view looking into pressure chamber along lines [IL-Ill in FIG. 2. This FIGURE illustrates the shape of thepressure chamber 10 that allows pressurized fluid to flow around thevalve body 20. The valve body is shown in the open position so that fluid in thepressure chamber 10 may flow through the bypass orrelief passage 3 to thesupply chamber 5. This view further illustrates how axial movement of thevalve 20 in an axial direction opens and closes the communicating link between thepressure chamber 10 and thebypass passage 3. This FIGURE further illustrates that the face of thevalve 20 is not at any time located within thepressure chamber 10 and therefore is not subjected to any axial forces caused by the fluid in the chamber when thevalve 20 is closed or open. Movement of thebody 20 in either axial direction is in the order of .005 inches or less, allowing a maximum flow rate to be obtained in a minimum amount of time.

, OPERATION Referring now to the drawings, and more particularly to FIGS. 1 and 2, thefuel pump 1 operates as follows: a sensing device (not shown) senses one of the operating parameters of the internal combustion engine (not shown) to control the axial movement of the solenoid core orvalve 20. The control signal has the effect of causing thebody 20 to oscillate at various magnitudes and/or frequencies. Simultaneously with the movement of theiron core 20, thepiston 31 reciprocates in response to the action of thespring 33 andcam follower 32 which is following the rotating camshaft of the internal combustion engine. Once thepiston 31 has risen to a point in the bore of thehousing 60 past thepassage 6, fluid in thechamber 10 will or will not be pressurized, depending upon the location of theiron core 20. If theiron core 20 is in the position shown in FIG. 2, there is no communicating link between thechamber 10 and thesupply chamber 5, as the location of annular groove 22 is such thatpassageway 3 does not communicate withpressure chamber 10. Therefore, pressure in thechamber 10 will increase until the delivery valve 51 opens, allowing fuel to pass throughpassage 57 and to the engine cylinder. Fuel will continue to flow throughpassage 57 until either the relief port opens or thepiston 31 reverses direction, which increases the volume ofchamber 10, decreasing the pressure in thechamber 10 and thereby causing the valve 51 to close.

Since the movement of thevalve 20 is controlled independently of the movement of the reciprocating pis-'ton 31, it is possible to open and/or close the communicating link between thepressure chamber 10 and thesupply chamber 5 at any particular point during the upward stroke of thepiston 31. Therefore, it can now readily be appreciated that the injection of fuel into the engine may be controlled by the electromagnetically operatedvalve 20 which in turn is controlled independently of thereciprocating piston 31. Therefore, the quantity of fuel injected into the engine is a function of the interval of time between the opening and closing of therelief passage 3 by the movement ofvalve 20.

In other words, when the relief port is closed (no communicating link betweenpressure chamber 10 and supply chamber 5), thepiston 31 will pressurize fuel in thechamber 10 causing it to open injection valve 51 and inject fuel into the engine. However, at any time during this cycle the independently controlledvalve 20 can be moved into a position that will establish a communicating link between thepressure chamber 10 and thesupply chamber 5, thereby relieving the pressure inchamber 10 resulting in the closing of the injector or delivery valve 51.

While a preferred embodiment of the invention has been disclosed, it will be apparent to those skilled in the art that changes may be made to the invention as set forth in the appended claims, and in some cases certain features of the invention may be used to advantage without corresponding use of other features. Accordingly, it is intended that the illustrative and descriptive materials herein be used to illustrate the principles of the invention and not to limit the scope thereof.

Having described the invention, what is claimed is:

l. A pump for supplying pressurized fluid which comprises:

a pump housing having a pumping chamber that has an inlet port, a relief port, an injection port communicating with said engine, and means for receiv ing a fluid, said fluid receiving means communicating with said inlet port, said relief port and said pumping chamber;

means for keeping said injection port closed below a first predetermined pressure in said pumping chamber;

means for periodically pressurizing the fluid in said chamber to cause fluid entering said pumping chamber through said inlet port to periodically flow out of said pumping chamber through said relief port; and

electromechanical valve means operative to open and close said relief port at predetermined intervals in response to at least one operating parameter of said engine, said electromechanical valve means including a solenoid valve having a core that has a first portion having an axial cross-sectional area that matches the configuration and size of said relief port and a second portion having a second axial cross-sectional area that is smaller than the relief port, said solenoid core mounted for axially reciprocating movement in said relief port so that in one position said first portion of said solenoid core closes said relief port and in a second position said second portion of said solenoid core opens said relief port, said solenoid core mounted so that neither end thereof terminates within said pumping chamber whereby the axial movement of said solenoid core that opens and closes said relief port is not biased by pressurized fluid within said pumping chamber, whereby each time said relief port closes,

the fluid pressure in said pumping chamber attains the first predetermined pressure at which said injection port opens, whereby pressurized fluid flows from said injection port.

2. The pump as recited inclaim 1 wherein said means for pressurizing fluid in said pumping chamber comprises:

'a piston mounted for reciprocating movement within said pump housing, said piston operable to periodically open and close said inlet port and thereby periodically apply pressure to said fluid in said pumping chamber as said plunger reciprocates, whereby when said relief port is open, fluid is pumped through said relief port and when said relief port is closed, fluid is pumped through said injection port.

3. The pump as recited inclaim 2 wherein said solenoid core is mounted transverse to said pump piston.

4. The pump as recited inclaim 1 wherein said solenoid core is mounted transverse to a wall of said pumping chamber so that said plunger extends into said chamber through said relief port.

5. The pump as recited inclaim 2 wherein said solenoid core is mounted transverse to a wall of said pumping chamber so that said plunger extends into said chamber through said relief port.

6. A fuel injection system for an internal combustion engine of the type having a cam shaft, the system comprising: v

a pump housing having a pumping chamber that has an inlet port, a relief port and an injection port, said injection port communicating with said engine;

means for supplying fuel to said pumping chamber through said inlet port;

means for closing said injection port, said closing means including biasing means for keeping said injection port closed until a predetermined fuel pressure is attained in said pumping chamber;

means responsive to the rotation of said engine cam shaft for periodically pressurizing the fuel in said chamber whereby the fuel in said chamber periodically flows out of said pumping chamber through said relief port; and

electromechanical valve means operative to open and close said relief port at predetermined intervals in response to at least one operating parameter of said engine whereby each time said relief port is closed the fuel pressure in said pressure chamber attains the predetermined pressure level at which said injection port opens, thereby injecting fuel into said engine, and each time said relief port is open, said injection port is closed, said electromechanical valve means is a solenoid valve having a plunger that has a first portion having an axial cross-sectional area that matches the configuration and size of said relief port and a second portion having a second axial cross-sectional area that is smaller than the relief port, said plunger mounted for axially reciprocating movement in said relief port so that in one position said first portion of said plunger closes said relief port and in a second position said second portion of said plunger opens said relief port, said solenoid core mounted so that neither end thereof terminates within said pumping chamber whereby the axial movement of said solenoid core that opens and closes said relief port is not biased by pressurized fluid within said pumping chamber.

Claims (6)

1. A pump for supplying pressurized fluiD which comprises: a pump housing having a pumping chamber that has an inlet port, a relief port, an injection port communicating with said engine, and means for receiving a fluid, said fluid receiving means communicating with said inlet port, said relief port and said pumping chamber; means for keeping said injection port closed below a first predetermined pressure in said pumping chamber; means for periodically pressurizing the fluid in said chamber to cause fluid entering said pumping chamber through said inlet port to periodically flow out of said pumping chamber through said relief port; and electromechanical valve means operative to open and close said relief port at predetermined intervals in response to at least one operating parameter of said engine, said electromechanical valve means including a solenoid valve having a core that has a first portion having an axial cross-sectional area that matches the configuration and size of said relief port and a second portion having a second axial cross-sectional area that is smaller than the relief port, said solenoid core mounted for axially reciprocating movement in said relief port so that in one position said first portion of said solenoid core closes said relief port and in a second position said second portion of said solenoid core opens said relief port, said solenoid core mounted so that neither end thereof terminates within said pumping chamber whereby the axial movement of said solenoid core that opens and closes said relief port is not biased by pressurized fluid within said pumping chamber, whereby each time said relief port closes, the fluid pressure in said pumping chamber attains the first predetermined pressure at which said injection port opens, whereby pressurized fluid flows from said injection port.

2. The pump as recited in claim 1 wherein said means for pressurizing fluid in said pumping chamber comprises: a piston mounted for reciprocating movement within said pump housing, said piston operable to periodically open and close said inlet port and thereby periodically apply pressure to said fluid in said pumping chamber as said plunger reciprocates, whereby when said relief port is open, fluid is pumped through said relief port and when said relief port is closed, fluid is pumped through said injection port.

3. The pump as recited in claim 2 wherein said solenoid core is mounted transverse to said pump piston.

4. The pump as recited in claim 1 wherein said solenoid core is mounted transverse to a wall of said pumping chamber so that said plunger extends into said chamber through said relief port.

5. The pump as recited in claim 2 wherein said solenoid core is mounted transverse to a wall of said pumping chamber so that said plunger extends into said chamber through said relief port.

6. A fuel injection system for an internal combustion engine of the type having a cam shaft, the system comprising: a pump housing having a pumping chamber that has an inlet port, a relief port and an injection port, said injection port communicating with said engine; means for supplying fuel to said pumping chamber through said inlet port; means for closing said injection port, said closing means including biasing means for keeping said injection port closed until a predetermined fuel pressure is attained in said pumping chamber; means responsive to the rotation of said engine cam shaft for periodically pressurizing the fuel in said chamber whereby the fuel in said chamber periodically flows out of said pumping chamber through said relief port; and electromechanical valve means operative to open and close said relief port at predetermined intervals in response to at least one operating parameter of said engine whereby each time said relief port is closed the fuel pressure in said pressure chamber attains the predetermined pressure level at which said injection port opens, thereby injecting fuel into said engine, and each time said relief port is open, said injection porT is closed, said electromechanical valve means is a solenoid valve having a plunger that has a first portion having an axial cross-sectional area that matches the configuration and size of said relief port and a second portion having a second axial cross-sectional area that is smaller than the relief port, said plunger mounted for axially reciprocating movement in said relief port so that in one position said first portion of said plunger closes said relief port and in a second position said second portion of said plunger opens said relief port, said solenoid core mounted so that neither end thereof terminates within said pumping chamber whereby the axial movement of said solenoid core that opens and closes said relief port is not biased by pressurized fluid within said pumping chamber.

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