Information
-
Patent Grant
-
6279541
-
Patent Number
6,279,541
-
Date Filed
Friday, December 1, 200024 years ago
-
Date Issued
Tuesday, August 28, 200123 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Reising, Ethington, Barnes, Kisselle, Learman & McCulloch,P.C.
-
CPC
-
US Classifications
Field of Search
US
- 123 514
- 123 497
- 123 456
- 123 506
- 123 357
-
International Classifications
-
Abstract
A no-return system for supplying fuel from a tank to a fuel injected internal combustion engine of an automotive vehicle in response to the fuel demand of the engine. The pump supplies more fuel than that required by the operating engine and the excess fuel is diverted from the engine by a bypass fuel pressure regulator and returned to the tank through a fluid-activatable switch movable to electrically open and closed states in response to the rate of flow of excess fuel through the switch. An electric control circuit is responsive to the state of the switch to change the magnitude of the power applied to the electric motor to change its operating speed and thereby modulate the output fuel flow rate of the pump in response to the fuel demand of the engine.
Description
FIELD OF THE INVENTION
The invention relates to a fuel supply system for an internal combustion engine of an automobile and, more particularly, to a fuel supply system responsive to engine fuel demand.
BACKGROUND OF THE INVENTION
In the fuel supply system for a fuel injected internal combustion engine present in many modem automotive vehicles, a fuel pump driven by an electric motor continuously supplies liquid fuel to the fuel injector(s) of the engine at a substantially constant flow rate which is always more than sufficient to supply the maximum possible fuel demand of the engine. Thus, under most engine operating conditions and particularly when the engine is merely idling, the fuel pump produces a significant amount of excess fuel that must be returned to the fuel tank from which the fuel pump originally drew the fuel.
Some fuel systems supply the entire fuel output of the pump to the engine and return the excess fuel from the engine to the fuel tank. Other fuel systems divert or bypass the excess fuel before it is delivered to the engine. Such a fuel system is commonly referred to as a “no return” or “returnless” type of system because it neither requires nor has a fuel return line extending from the fuel rail of the engine itself and back to the fuel tank. One prior returnless fuel system is disclosed in U.S. Pat. No. 5,975,061 issued on Nov. 2, 1999 to Briggs et al. In this system, the fuel pump continuously operates at maximum fuel output capacity, and the excess fuel is diverted from the engine and returned to the tank by a bypass fuel pressure regulator which maintains a substantially constant pressure of fuel supplied to the engine even though the fuel flow rate varies.
Another returnless fuel system is disclosed in U.S. Pat. No. 5,265,644 in which changes in the instantaneous pressure of the fuel supplied to the engine actuate a switch to change the speed of the electric motor to vary the fuel output of the pump through appropriate pulse width modulation circuitry which changes the electric power applied to the pump motor.
While these systems do attempt to deliver an amount of fuel to the engine which better matches the actual fuel demand of the engine, they are often inaccurate and untimely, especially when there is a sudden and significant rise or fall in the fuel demand of the engine, and sometimes momentarily result in insufficient fuel being supplied to the engine. Thus, there is a present need in the art for an apparatus which better and more rapidly and timely matches the actual fuel demand of the engine.
SUMMARY OF THE INVENTION
A fuel supply system with a bypass fuel pressure regulator, a fluid-activatable switch responsive to bypass fuel flow, and an associated electric control circuit to vary and modulate the speed of an electric motor driving a fuel pump and hence its output fuel flow rate in accordance with the fuel demand of an internal combustion engine. Preferably, the fluid-activatable switch is manipulable into one of either an electrically open state or an electrically closed state, as determined by the flow rate of excess fuel from the bypass fuel pressure regulator. Preferably, the control circuit is capable of adjusting the level of the voltage supplied to the electric fuel pump motor as dictated by the position of the fluid-activatable switch. In this way, the speed of the electric motor and fuel pump output is modulated in accordance with changes in both the flow of the fuel and the state of the switch.
In a preferred embodiment of the present invention, the fluid-activatable switch has a plunger movable relative to an electrical contact to change the state of the switch in response to the flow rate of excess fuel. The plunger is slidably received in an elongate chamber in a body having an inlet opening at one end, a stop opening at the opposite end, and at least one outlet opening, all communicating with the elongate chamber. Preferably, the plunger is yieldably biased by a resilient biasing element with an adjustable stop member. The stop member is received within the stop opening and has an exposed head portion and a tail portion extending into the chamber. Preferably, the biasing element is a spring with one end abutting the stop member and the other end extending into the chamber and bearing on the plunger. Preferably, the plunger has a shoulder portion, opposite the biased end and proximate each outlet opening in the body, and a single electrically conductive contact mounted on the shoulder portion proximate the inlet opening. The switch also preferably includes a pair of electrically conductive contacts electrically connected to the electric control circuit and mounted and exposed within the chamber of the body, substantially between the inlet opening and each outlet opening. In such a configuration, the chamber of the body defines a fuel flow path from the inlet opening to each outlet opening. The single contact and the shoulder portion of the plunger are situated within the fuel flow path and yieldably biased against any fuel flowing within the fuel flow path. In this way, the plunger is capable of being moved as dictated by the excess fuel flowing within the fuel flow path such that the switch is in one of either the electrically open state or the electrically closed state or position.
Preferably, the electric voltage control circuit includes means for both electrically sensing the state of the fluid-activatable switch and selectively connecting a resistive circuit element such as a resistor in electrical series with the electric fuel pump motor to an electric power source as dictated by the sensed state of the switch. Most preferably, the position sensing and selective connecting means includes a transistor such as, for example, a field-effect transistor.
Objects, features, and advantages of this invention include an electric motor fuel pump system which provides improved efficiency, improved responsiveness to varying engine fuel demand, always satisfies the engine fuel demand, and is compact, rugged, durable, of relatively simple design and economical manufacture and assembly, and in service has a long usefull life.
BRIEF DESCRIPTION OF THE DRAWINGS
These and other objects, features, and advantages of this invention will be apparent from the following detailed description of the preferred embodiments and best mode, appended claims, and accompanying drawings in which:
FIG. 1
is a partial sectional view of a fuel supply system for a fuel injected internal combustion engine of an automobile, according to the present invention;
FIG. 2
is a sectional view of a first embodiment of a fluid-activatable switch of the system of
FIG. 1
;
FIG. 3
is a sectional view of a second embodiment of a fluid-activatable switch of the system of
FIG. 1
;
FIG. 4
is an electric circuit diagram for a first embodiment of an electric voltage control circuit of the system of
FIG. 1
;
FIG. 5
is a sectional view of a third embodiment of a fluid-activatable switch of the system of
FIG. 1
;
FIG. 6
is an electric circuit diagram for a second embodiment of an electric voltage control circuit of the system of FIG.
1
and suitable for use with the third embodiment of the switch of
FIG. 5
; and
FIG. 7
is a perspective view of a plug suitable for use with the first embodiment of the switch of FIG.
2
and the third embodiment of the switch of FIG.
5
.
FIG. 8
is a sectional view of a fourth embodiment of a fluid-activatable switch of the system of
FIG. 1
, wherein the switch is in an electrically open position;
FIG. 9
is another sectional view of the fluid-activatable switch of
FIG. 8
, wherein the switch is in an electrically closed position;
FIG. 10
is an exploded perspective view of a fifth embodiment of a fluid-activatable switch of the system of
FIG. 1
;
FIG. 11
is an end view of the fluid-activatable switch of
FIG. 10
;
FIG. 12
is a sectional view of the fluid-activatable switch of
FIG. 10
, wherein the view is taken along the
12
—
12
line of
FIG. 11
;
FIG. 13
is another sectional view of the fluid-activatable switch of
FIG. 10
, wherein the view is taken along the
13
—
13
line of
FIG. 11
; and
FIG. 14
is a graph illustrating an operational hysteresis characteristic of the system of
FIG. 1
with the fluid-activatable switch of FIG.
10
.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring in more detail to the drawings,
FIG. 1
illustrates a returnless fuel supply system
40
embodying this invention for supplying fuel from a tank
12
to a fuel rail
28
and fuel injectors
32
of an internal combustion engine
30
preferably of an automotive vehicle. Fuel is supplied from the tank
12
to the rail
28
by a fuel pump module
16
mounted on the top wall
14
of the tank
12
. To control the pressure of the fuel, excess fuel supplied by the pump module
16
is diverted from the engine
30
by a bypass pressure regulator
36
and returned to the fuel tank
12
through a fluid-activatable switch
42
. An electric control circuit
44
in conjunction with the switch
42
provides an apparatus
50
for modulating the speed of an electric fuel pump motor
18
and hence the speed and output of a fuel pump
19
of the module
16
to vary the fuel flow rate of the operating fuel pump
19
.
From the tank
12
, the pump
19
draws fuel through a fuel inlet
20
and a filter
22
disposed adjacent the bottom of the tank
12
and supplies fuel under pressure to the fuel rail
28
through a pump outlet
24
and a connecting fuel supply line
26
. The inlet of the bypass fuel pressure regulator
36
is connected to the line
26
by a branch fuel bypass line or conduit
34
, and the outlet of the bypass regulator
36
is connected to the inlet of the switch
42
by a line
34
′. The outlet of the switch
42
communicates with the fuel tank
12
to return fuel to the tank
12
through a line
34
″.
The electric voltage control circuit
44
is electrically connected to the switch
42
via electrical wires
46
and
47
and electrically connected to the electric fuel pump motor
18
via electrical wires
38
and
39
. The electric voltage control circuit
44
is also electrically connected to both a positive power node
15
and a negative power node
25
of an electric power source of the electrical system of the automobile. In such a configuration, the electric voltage control circuit
44
is thereby capable of supplying a current to the electric fuel pump motor
18
for successfully operating the motor
18
.
The fluid-activatable switch
42
of
FIG. 1
is manipulable into one of either an electrically open position or an electrically closed position, as determined by the flow of the fuel from the bypass fuel pressure regulator
36
. The electric voltage control circuit
44
is capable of adjusting the level of the voltage supplied to the electric fuel pump motor
18
as dictated by the position of the fluid-activatable switch
42
. In this way, the speed of the electric fuel pump motor
18
is modulated in accordance with changes in both the flow rate of excess fuel through the fuel bypass line
34
and the position of the switch
42
.
As shown in
FIG. 2
, a first embodiment
42
′ of the fluid-activatable switch
42
has an elongate body
52
with an inlet opening
54
at one end, a stop opening
56
at the opposite end, at least one outlet opening
58
, and a longitudinal chamber
60
in communication with the inlet opening
54
, the stop opening
56
, and each outlet opening
58
. The longitudinal chamber
60
is preferably substantially cylindrical and has a longitudinal axis
59
with which both the inlet opening
54
and the stop opening
56
are preferably substantially aligned. Although only one outlet opening
58
is illustrated in
FIG. 2
, it is to be understood that more than one outlet opening may be provided through the wall
90
of the elongate body
52
. Where there is more than one outlet opening
58
, each outlet opening
58
is most preferably provided within a common middle section of the elongate body
52
to facilitate the even flow of fuel through the switch
42
′ for precise calibration of the switch
42
′.
The switch
42
′ also includes an adjustable stop member
62
and an elastic, resilient biasing element
64
. The stop member
62
is received within the stop opening
56
and has an exposed head portion
66
and a tail portion
68
extending into the chamber
60
. The stop member
62
is a threaded plug received in a complimentary mating threaded portion of the opening
56
to facilitate precise adjusting of the stop member
62
within the longitudinal chamber
60
of the elongate body
52
for operational calibration of the switch
42
′. As an alternative to a plug, the stop member
62
may be a cup-shaped closure.
A plunger
74
is slidably received in the chamber
60
and yieldably biased toward an extended position by the biasing element
64
, which in this embodiment is a helical spring. The biasing element
64
has one end
70
bearing on and received over the tail portion
68
of the stop member
62
and the other end
72
bearing on and received over a biased end
76
of the plunger
74
. A single electrically conductive contact
80
, preferably in the form of an annular metal disc
80
′, is mounted on a stem
92
axially extending from a shoulder portion
78
of the plunger
74
proximate the inlet opening
54
. The biased end
76
of the plunger
74
has a plurality of integral and circumferentially spaced apart fins
84
and
86
in smooth sliding contact with the inner surface
88
of the wall
90
of the elongate body
52
. Similarly, the shoulder portion
78
of the plunger
74
is substantially cylindrical and has a cross-sectional area that approaches the cross-sectional area of the longitudinal chamber
60
. In this way, smooth sliding contact between the shoulder portion
78
of the plunger
74
and the inner surface
88
of the wall
90
of the elongate body
52
is facilitated as well.
The switch
42
′ has a pair of electrically conductive contacts
82
and
83
electrically connected via electric wires
46
and
47
to the electric voltage control circuit
44
. The contacts
82
and
83
are mounted and exposed within the chamber
60
of the body
52
, substantially between the inlet opening
54
and the outlet opening
58
. As shown in
FIG. 7
, the contacts
82
and
83
are preferably a pair of metal prongs
82
′ and
83
′ mounted in an insulative plug casing
96
such that the metal prongs
82
′ and
83
′ are at least partially exposed within the longitudinal chamber
60
. As shown in
FIG. 2
, the plug casing
96
is received and sealed in an opening
98
in the body
52
.
The chamber
60
of the body
52
defines a fuel flow path from the inlet opening
54
to the outlet opening
58
. The single contact
80
and the shoulder portion
78
of the plunger
74
are situated within the fuel flow path and yieldably biased against any fuel flowing within the fuel flow path. In this way, the plunger
74
is capable of being moved as dictated by the fuel flowing within the fuel flow path such that the switch
42
′ is in one of either an electrically open position or an electrically closed position. In the open position, the single contact
80
is spaced from the pair of contacts
82
and
83
. In the closed position, the single contact
80
bears on and is in electrical contact with the pair of contacts
82
and
83
.
FIG. 4
illustrates a first embodiment
44
′ of the electric voltage control circuit
44
of FIG.
1
and is suitable for use with the first and second embodiments
42
′ and
42
″ of the switch
42
of FIG.
1
. The circuit
44
′ has an electrically resistive circuit element, in this case, a resistor
102
, and means for electrically sensing the position of the fluid-activatable switch
42
′ and selectively connecting the resistor
102
in electrical series with the electric fuel pump motor
18
to the positive power node
15
and the negative power node
25
as dictated by the sensed position of the switch
42
′. In this circuit
44
′, the position sensing and selective connecting means is an n-channel field-effect transistor (FET)
100
. It is to be understood, however, that other types of transistors or switching devices may be used instead of an n-channel field-effect transistor.
The electric fuel pump motor
18
is electrically connected between the positive power node
15
via electric wire
38
and the drain of the FET
100
via electric wire
39
. The resistor
102
is electrically connected between the drain and the source of the FET
100
, and the source of the FET
100
is electrically connected to the negative power node
25
. The fluid-activatable switch
42
′ is electrically connected between the positive power node
15
via electric wire
46
and a circuit node
110
via electric wire
47
. A resistor
112
is electrically connected between the circuit node
110
and a circuit node
106
. A capacitor
108
and a resistor
114
are electrically connected in parallel between the circuit node
106
and the negative power terminal
25
. A resistor
104
is electrically connected between the gate of the FET
100
and the circuit node
106
.
During operation of the fuel supply system
40
of
FIG. 1
, the fuel pump
19
draws fuel from within the fuel tank
12
through the filter
22
and the fuel inlet
20
and thereafter delivers the fuel through the fuel outlet
24
under pressure to the fuel supply line
26
. The line
26
supplies a portion of the fuel under pressure to the fuel rail
28
and associated fuel injectors
32
of the internal combustion engine
30
. In doing so, the fuel pump
19
normally maintains an output fuel pressure and fuel flow rate at the outlet
24
which is greater than that required to meet the fuel demand of the operating engine
30
. At least most of the time, the fuel pump
19
provides an amount of fuel that exceeds the actual fuel demand of the engine
30
during operation, and the bypass fuel pressure regulator
36
then, under pressure, diverts the excess fuel flow from the line
26
and returns the excess fuel via the fuel bypass line
34
and switch
42
′ back to the fuel tank
12
. If the fuel pump
19
provides an amount of fuel that closely matches the fuel demand of the engine
30
, then the bypass fuel pressure regulator
36
diverts little to no excess fuel into the fuel bypass line
34
and the switch
42
′.
Thus, when the fuel demand of the engine
30
is high, such as during times when the automobile rapidly accelerates or the engine operates under a great load, the bypass fuel pressure regulator
36
then diverts little to no fuel into the fuel bypass line
34
to insure that the high fuel demand of the engine is met. This dictates that little to no fuel will enter the inlet opening
54
of the switch
42
′ and thus the force, if any, exerted by the excess fuel against the metal annular disc
80
′ and the shoulder portion
78
of the plunger
74
will not be sufficient to counteract and overcome the bias of the biasing element
64
against the plunger
74
. As a result, the switch
42
′ will remain in an electrically closed position wherein the metal annular disc
80
′ rests against both metal prongs
82
′ and
83
′ and thereby electrically shorts or connects the metal prongs
82
′ and
83
′ together.
Referring to
FIG. 4
, when the switch
42
′ is in an electrically closed position during times when the engine
30
has a relatively high fuel demand, a high electrical signal supplied by the positive power node
15
passes through the closed switch
42
′ and the resistor
112
to the circuit node
106
. After reaching the circuit node
106
, the capacitor
108
is charged up, and the high electrical signal is divided between the resistor
104
and the resistor
114
such that a high enough electrical signal reaches the gate of the FET
100
to thereby induce the FET
100
into conduction mode. In the conduction mode, the FET
100
thereby permits the conduction of current from its drain to its source such that the resistor
102
is essentially electrically shorted out or bypassed. In shorting out the resistor
102
, the full voltage potential between the positive power node
15
and the negative power node
25
is applied to the electric fuel pump motor
18
. As a result, the electric fuel pump motor
18
will then operate at full speed to ensure that enough fuel is pumped from the fuel tank
12
and supplied to the fuel rail
28
to meet the high fuel demand of the engine
30
.
On the other hand, when the fuel demand of the engine
30
becomes low, such as when the engine is merely idling, a significant amount of excess fuel provided by the fuel pump
19
to the fuel supply line
26
is diverted by the bypass fuel pressure regulator
36
into the fuel bypass line
34
and the inlet opening
54
of the switch
42
′ and exerts a substantial amount of force against both the metal annular disc
80
′ and the shoulder portion
78
of the plunger
74
such that the bias of the biasing element
64
against the plunger
74
is counteracted and overcome. As a result, the plunger
74
is retracted against the bias of the biasing element
64
such that switch
42
′ moves from an electrically closed position to an electrically open position wherein the metal annular disc
80
′ no longer rests against both of the metal prongs
82
′ and
83
′.
Referring again to
FIG. 4
, when the switch
42
′ moves into an electrically open position, the high electrical signal provided by the positive power node
15
is prevented from reaching the gate of the FET
100
since the open switch
42
′ creates an open circuit condition between the positive power node
15
and the gate of the FET
100
. As a result, any high electrical charge stored in the capacitor
108
is discharged through the resistor
114
, and the FET
100
is induced into non-conduction mode and therefore prevents the passage of electric current from its drain to its source. Further, electric current moving from the positive power node
15
, through the electric fuel pump motor
18
, and to the negative power node
25
is thereby forced to pass through the resistor
102
as well. The resultant voltage drop across the resistor
102
thereby reduces the net voltage drop across the electric fuel pump motor
18
. Thus, the full voltage potential between the positive power node
15
and the negative power node
25
is not fully applied across the electric fuel pump motor
18
. As a result, the electric fuel pump motor
18
will operate at a reduced speed and pump a reduced amount of fuel from the fuel tank
12
that is sufficient for the low fuel demand of the engine
30
.
Second Switch
In a second embodiment, the fluid-activatable switch
42
″ illustrated in
FIG. 3
may be used in the system
40
of
FIG. 1
instead of the switch
42
′ of FIG.
2
. The switch
42
″ is substantially similar to the switch
42
′ with only a few variations. In particular, the metal annular disc
80
′ is replaced with a metal cylindrical ring
80
″ which is fixedly seated in a pocket
81
integral with the shoulder
78
of the plunger
74
. Both the metal cylindrical ring
80
″ and the pocket
81
are situated so that they generally face the inlet opening
54
and the metal cylindrical ring
80
″ extends axially toward the inlet opening
54
beyond the confines of the pocket
81
.
A pair of flexible metal prongs
82
″ and
83
″ is sealingly mounted in the insulative wall
90
of the longitudinal chamber
60
so that they are at least partially exposed within the longitudinal chamber
60
and are electrically connected to the electric voltage control circuit
44
′ via electric wires
46
and
47
.
The switch
42
″ includes laminar flow guide structures or fins
85
,
87
,
91
and
95
which are integral with the wall
90
of the longitudinal chamber
60
. The guide structures
85
,
87
,
91
and
95
extend longitudinally and are particularly situated within the chamber
60
proximate the inlet opening
54
and in the fuel flow path between the inlet opening
54
and the outlet opening
58
. The guide structures
87
and
91
have stop surfaces
89
and
93
for physically limiting the range of flexing of the flexible metal prongs
82
″ and
83
″ when the cylindrical metal ring
80
″ carried by the plunger
74
is biased against both of the flexible metal prongs
82
″ and
83
″ when the switch
42
″ is in an electrically closed position.
Operation of the second switch
42
′ is substantially the same as the operation of the first switch
42
′ described earlier hereinabove and thus will not be repeated herein.
Third Switch and Second Circuit
A third embodiment of a fluid-activatable switch
42
′″ illustrated in
FIG. 5 and a
second embodiment of an electric voltage control circuit
44
′″ illustrated in
FIG. 6
may be used in the system of
FIG. 1
instead of the switch
42
′ and the electric voltage control circuit
44
′.
As shown in
FIG. 5
, the switch
42
′″ is substantially similar to the switch
42
′ with only a few variations. In particular, the stem
92
′″ of this switch
42
′″ is substantially longer than the stem structure
92
′ of switch
42
′ and has a metal annular disc
80
′″ adjustably fixed on its extended end which is generally disposed between the inlet opening
54
and the insulative plug casing
96
with metal prongs
82
′″ and
83
′″. The plug casing
96
is rotated 180° and disposed downstream of the metal annular disc
80
′″. With this configuration, the switch
42
′″ is in an electrically open position when the force of little to no fuel flow is exerted against the metal annular disc
80
′″ and the shoulder portion
78
of the plunger
74
and is in an electrically closed position when the fuel flow produces a sufficient force to move the plunger
74
sufficiently so that the disc
80
′″ simultaneously bears on both of the metal prongs
82
′″ and
83
′″.
As shown in
FIG. 6
, the electric voltage control circuit
44
′″ has an electrically resistive circuit element, in this case the resistor
102
, and means for electrically sensing the position of the fluid-activatable switch
42
′″ and selectively connecting the resistor
102
in electrical series with the electric fuel pump motor
18
to the positive power node
15
and the negative power node
25
as dictated by the sensed position of the switch
42
′″. In this circuit, the position sensing and selective connecting means comprises the n-channel field-effect transistor (FET)
100
. It is to be understood, however, that other types of transistors or switching devices may be used instead of an n-channel field-effect transistor.
The electric fuel pump motor
18
is electrically connected between the positive power node
15
via electric wire
38
and the drain of the FET
100
via electric wire
39
. The resistor
102
is electrically connected between the drain and the source of the FET
100
, and the source of the FET
100
is electrically connected to the negative power node
25
. The fluid-activatable switch
42
′″ is electrically connected between the negative power node
25
via electric wire
47
and a circuit node
128
via electric wire
46
. A resistor
130
is electrically connected between the circuit node
128
and the positive power node
15
. The anode of a diode
126
is electrically connected to the circuit node
128
, and the cathode of the diode
126
is electrically connected to a circuit node
118
. In parallel therewith, a resistor
122
and a diode
124
are serially connected between the circuit node
118
and the circuit node
128
such that the anode of the diode
124
is electrically connected to the resistor
122
and the cathode of the diode
124
is electrically connected to the circuit node
128
. A capacitor
120
is electrically connected between the circuit node
118
and the negative power node
25
while a resistor
116
is electrically connected between the circuit node
118
and the gate of the FET
100
.
In operation, when the fuel demand of the engine
30
is low, fuel diverted by the bypass fuel pressure regulator
36
into the fuel bypass line
34
enters the inlet opening
54
of the switch
42
′″ and exerts sufficient force against both the metal annular disc
80
′″ and the shoulder portion
78
of the plunger
74
to overcome the bias of the biasing element
64
against the plunger
74
and move the metal annular disc
80
′″ against both of the metal prongs
82
′″ and
83
′″ mounted in the plug casing
96
. When this occurs, the metal prongs
82
′″ and
83
′″ are electrically shorted or connected together such that switch
42
′″ is in an electrically closed position.
As shown in
FIG. 6
, when the switch
42
′″ is in an electrically closed position when the fuel demand of the engine
30
is low, electric current from the positive power node
15
flows through the resistor
130
, through the closed switch
42
′″, and down to the negative power node
25
. That is, the closed switch
42
′″ electrically shorts out a significant portion of the electric voltage control circuit
44
′″ such that a high electrical signal is not able to reach the gate of the FET
100
. Thus, the FET
100
is left in non-conduction mode and will not allow the passage of electric current from the drain to the source of the FET
100
. As a result, electric current moving from the positive power node
15
, though the electric fuel pump motor
18
, and to the negative power node
25
is thereby forced to pass through the resistor
102
as well and the resultant voltage drop across the resistor
102
thereby reduces the net voltage applied to the electric fuel pump motor
18
. That is, the full voltage potential between the positive power node
15
and the negative power node
25
is not fully applied to the electric fuel pump motor
18
. As a result, the electric fuel pump motor
18
will operate at a reduced speed and the pump will deliver a reduced amount and flow rate of fuel from the fuel tank
12
that is sufficient for the low fuel demand of the engine
30
.
When the fuel demand of the engine
30
is high, the bypass fuel pressure regulator
36
then diverts little to no fuel into the fuel bypass line
34
to ensure that the high fuel demand of the engine
30
is met. The low flow rate or lack of excess fuel within the fuel bypass line
34
, however, dictates that little to no excess fuel will enter the inlet opening
54
of the switch
42
′″ of FIG.
5
. Thus, the force of the excess fuel, if any, exerted against the metal annular disc
80
′″ and the shoulder portion
78
of the plunger
74
will not be sufficient to overcome the bias of the biasing element
64
against the plunger
74
. As a result, the switch
42
′″ will be in an electrically open position wherein the metal annular disc
80
′″ no longer rests against both metal prongs
82
′″ and
83
′″.
As shown in
FIG. 6
, when the switch
42
′″ is in an electrically open position during a time when the engine
30
has a high fuel demand, a high electrical signal supplied by the positive power node
15
passes through the resistor
130
, the diode
126
, and the resistor
116
so that a high enough electrical signal reaches the gate of the FET
100
to thereby induce the PET
100
into conduction mode. As the high electrical signal reaches the gate of the FET
100
, the capacitor
120
begins to charge up so that the high electrical signal at the gate of the FET
100
is properly maintained. In the conduction mode, the FET
100
thereby permits the conduction of current from its drain to its source so that the resistor
102
is essentially electrically shorted out and thus the full voltage potential between the positive power node
15
and the negative power node
25
is applied to the electric fuel pump motor
18
. As a result, the electric fuel pump motor
18
will then operate at full speed to ensure that enough fuel is pumped from the fuel tank
12
and supplied to the fuel rail
28
to meet the high fuel demand of the engine
30
. When the switch
42
′″ is subsequently closed, for example, due to a sudden decrease in fuel demand from the engine
30
, the capacitor
120
will then begin to discharge its high voltage potential through the resistor
122
, the diode
124
, and the closed switch
42
′″ until there is no longer a high electrical signal at the gate of the FET
100
and the FET
100
eventually enters into non-conduction mode again.
Fourth Switch
A fourth embodiment of a fluid-activatable switch
42
″″ illustrated in
FIGS. 8 and 9
may be used in the system
40
of
FIG. 1
with the first electric voltage control circuit
44
′ of FIG.
4
. The fluid-activatable switch
42
″″ has an elongate body
200
with an inlet opening
202
at one end, an end outlet opening
204
at the opposite end, side outlet openings
206
and
208
, and a longitudinal chamber
210
. The longitudinal chamber
210
communicates with the inlet opening
202
, the end outlet opening
204
, and the side outlet openings
206
and
208
. The switch
42
″″ has an electrically conductive first contact
212
and an electrically conductive resilient biasing element
214
which, in this embodiment, is a spring. The first contact
212
is electrically connected to the electric voltage control circuit
44
′ (see
FIG. 4
) and is also mounted and exposed within the chamber
210
of the body
200
proximate the end outlet opening
204
. The electrically conductive biasing element
214
has one end
216
electrically attached to the first contact
212
and the other end
218
extending into the chamber
210
and bearing on a plunger
220
in the form of an electrically conductive ball preferably of metal. The plunger
220
is slidingly received within the chamber
210
and preferably has a biased side
222
, electrically attached to the end
218
of the biasing element
214
, and an impact side
224
, opposite the biased side
222
and movably situated substantially between the inlet opening
202
and the side outlet openings
206
and
208
in the body
200
. The switch
42
″″ also has an electrically conductive second contact
226
electrically connected to the electric voltage control circuit
44
′ and mounted and exposed within the chamber
210
of the body
200
, substantially between the inlet opening
202
and the side outlet openings
206
and
208
. In this configuration, the chamber
210
of the body
200
defines a fuel flow path from the inlet opening
202
to the outlet openings
206
and
208
. The plunger
220
is situated within the fuel flow path and yieldably biased against any fuel flowing within the fuel flow path. In this way, the plunger
220
is capable of being moved as dictated by the rate of fuel flowing through the fuel flow path so that the switch
42
″″ is in one of either an electrically open position or an electrically closed position. The open position or state is particularly defined as the plunger
220
being separated from the second contact
226
, and the closed position or state is particularly defined as the plunger
220
being in electrical contact with the second contact
226
.
As illustrated in
FIGS. 8 and 9
, the chamber
210
of the switch
42
″″ has a venturi shape and is substantially cylindrical from the inlet opening
202
to the electrically conductive second contact
226
and then tapered with a generally frusto-conical or funnel shape to the side outlet openings
206
and
208
. From the side outlet openings
206
and
208
to the end outlet opening
204
, the chamber
210
is substantially cylindrical and has an inner diameter which is smaller than the inner diameter of the chamber
210
from the inlet opening
202
to the second contact
226
. The inlet opening
202
and the end outlet opening
204
are substantially aligned with the longitudinal axis
228
of the chamber
210
, and each of the side outlet openings
206
and
208
are within a common middle section of the elongate body
200
between the first contact
212
and the second contact
226
. In this configuration, fuel flow within the switch
42
″″ is more symmetrical and therefore predictable so that critical dimensions that dictate the operational characteristics of the switch
42
″″ are more easily calculated and calibrated. The diameter of the plunger
220
substantially approaches the diameter of the longitudinal chamber
210
proximate the side outlet openings
206
and
208
. Given such a configuration, dithering or bouncing of the plunger
220
within the chamber
210
as fuel flows therethrough is significantly reduced. As a result, smooth and even flow of fuel through the chamber
210
and through the outlet openings
204
,
206
, and
208
is thereby facilitated.
In operation, when the fuel demand of the engine
30
is low, a significant amount of excess fuel is diverted by the bypass fuel pressure regulator
36
and introduced into the chamber
210
of the switch
42
″″ via the inlet opening
202
. The excess fuel exerts a substantial force against the plunger
220
such that the bias of the biasing element
214
is overcome and the plunger
220
moves and becomes separated or spaced from the second contact
226
and the switch
42
″″ is moved to an electrically open position. Given such an open circuit condition, the FET
100
in
FIG. 4
slips into non-conduction mode, and a lower supply voltage is therefore applied by the electric voltage control circuit
44
″″ to the electric fuel pump motor
18
. As a result, both the operational speed of the electric fuel pump motor
18
and the amount and flow rate of fuel supplied thereby is reduced to better match the low fuel demand of the engine
30
.
When, on the other hand, the fuel demand of the engine
30
is high, relatively little to no fuel is diverted by the bypass fuel pressure regulator
36
, and little to no force is exerted against the plunger
220
in the switch
42
″″. The plunger
220
is therefore pressed against the second contact
226
by the biasing force of the biasing element
214
as illustrated in FIG.
9
. With the plunger
220
pressed against the second contact
226
in this manner, a closed circuit condition is created in the switch
42
″″. Given such a closed circuit condition, the FET
100
in
FIG. 4
then slips into conduction mode wherein the resistor
102
is electrically shorted out. As a result, a greater supply voltage equal to the full voltage potential between the positive power node
15
and the negative power node
25
is therefore applied to the electric fuel pump motor
18
. In this way, both the operational speed of the electric fuel pump motor
18
and the amount of fuel produced by the fuel pump
19
are increased to better match and satisfy the high fuel demand of the engine
30
.
Fifth Switch
A fifth embodiment of a fluid-activatable switch
42
′″″ illustrated in
FIGS. 10-13
may be used in the system
40
with the electric voltage control circuit
44
′ of FIG.
4
. The fluid-activatable switch
42
′″″ has an elongate body
250
having an inlet opening
252
at one end, an end outlet opening
254
at the opposite end, four side outlet openings
255
,
256
,
257
, and
258
, and a longitudinal chamber
260
. The longitudinal chamber
260
is in communication with the inlet opening
252
, the end outlet opening
254
, and the four side outlet openings
255
,
256
,
257
and
258
. The switch
42
′″″ also has an electrically conductive first contact
262
and an electrically conductive biasing element
264
which, in this embodiment, is a metal spring. The first contact
262
is electrically connected to the electric voltage control circuit
44
′ (see FIG.
4
). and is also mounted and exposed within the chamber
260
of the body
250
proximate the end outlet opening
254
. The biasing element
264
has a first end
266
electrically attached to the first contact
262
and a second end
268
extending into the chamber
260
and bearing on an electrically conductive plunger
270
, preferably a metal ball, slidingly received within the chamber
260
. Preferably, the plunger
270
has a biased side
272
, electrically attached to the second end
268
of the biasing element
264
, and an impact side
274
, opposite the biased side
272
and movably situated substantially between the inlet opening
252
and the four side outlet openings
255
,
256
,
257
, and
258
in the body
250
. The switch
42
′″″ has an electrically conductive second contact
276
electrically connected to the electric voltage control circuit
44
′. The second contact
276
is mounted and exposed within the chamber
260
of the body
250
, substantially between the inlet opening
252
and the four side outlet openings
255
,
256
,
257
, and
258
. In such a configuration, the chamber
260
of the body
250
defines a fuel flow path from the inlet opening
252
to the outlet openings
255
,
256
,
257
, and
258
. The plunger
270
is situated within the fuel flow path and yieldably biased against any fuel flowing within the fuel flow path. In this way, the plunger
270
is capable of being moved as dictated by the fuel flowing within the fuel flow path such that the switch
42
′″″ is in one of either an electrically open position or an electrically closed position. In the open position or state, the plunger
270
is separated from the second contact
276
, and in the closed position or state, the plunger
270
is in electrical contact with the second contact
276
.
Preferably, the diameter of the plunger ball
270
substantially approaches the diameter of the longitudinal chamber
270
proximate the four side outlet openings
255
,
256
,
257
, and
258
. Given such a configuration, dithering or bouncing of the plunger
270
within the chamber
260
as significant amounts of fuel flow therethrough is significantly reduced. As a result, smooth and even flow of fuel through the chamber
260
and through the four outlet openings
255
,
256
,
257
, and
258
is thereby facilitated.
As best shown in
FIG. 10
, both the first contact
262
and the second contact
276
comprise a separate pair of metal prongs wherein the prongs of each pair are substantially parallel to each other and electrically shorted together. The pairs of prongs are all mounted and exposed within the chamber
260
such that fuel may flow around and between the prongs. The prongs of the second contact
276
provide a means for capturing the plunger ball
270
in the chamber as best illustrated in
FIGS. 11 and 12
. Furthermore, as illustrated in
FIGS. 11 and 13
, the plunger ball
270
is closely and slidably received between four axially extending and equally circumferentially spaced-apart ribs
277
to restrain the plunger ball
270
from dithering when fuel flow through the switch
42
′″″ is low and the switch
42
′″″ is in an electrically closed position.
The function and operation of the fifth switch
42
′″″ is substantially similar to the above-described operation of the fourth switch
42
′″″ of
FIGS. 8 and 9
and hence will not be repeated herein.
System Operation
A further example of the operation of the fuel system
40
with the fifth switch
42
′″″ and the first electric control circuit
44
′ is illustrated in the graph of
FIG. 14
which shows the operational hysteresis characteristics of the system
40
. Assuming that the engine
30
, the returnless fuel system
40
, and the apparatus
50
have been at rest for some period of time, the point
300
on the graph in
FIG. 14
represents the initial start-up of the engine
30
. At the initial start-up of the engine
30
, the electric motor
18
is turned on and initially operates at the maximum possible voltage (for example, 13 volts) that is deliverable by the electric voltage control circuit
44
′. While the electric fuel pump motor
18
runs in such a full-speed mode, the fuel pump
19
supplies fuel under pressure to the fuel supply line
26
at a rate of 220 liters per hour (l/h or lph). If the fuel demand of the engine
30
is negligible at this time, then the flow rate of fuel within the fuel bypass line
34
and through the bypass fuel pressure regulator
36
and the fifth switch
42
′″″ is about 220 lph as well. This fuel flow rate exerts enough force against the impact side
274
of the plunger
270
so that it moves against the bias of the biasing element
264
to the point where it is no longer in electrical contact with the second contact
276
. As a result, the switch
42
′″″ is in an electrically open position, and the FET
100
in the electric voltage control circuit
44
′ slips into non-conduction mode and a reduced voltage (for example, 10 volts) is thereby applied to the electric fuel pump motor
18
from the electric voltage control circuit
44
′. Consequently, the operating speed of the electric fuel pump motor
18
and the flow rate of fuel delivered by the fuel pump
19
to the fuel supply line
26
is reduced to, for example, 130 lph. Since the fuel demand of the engine
30
is still negligible at this point, the fuel flow rate within the fuel bypass line
34
and the switch
42
′″″ as regulated by the bypass fuel pressure regulator
36
then drops to 130 lph as well. Point
302
on the graph in
FIG. 14
illustrates this particular low-speed mode of operation.
As the fuel demand of the engine
30
increases, the flow of fuel in the bypass fuel line
34
and the switch
42
′″″ is reduced by the bypass fuel pressure regulator
36
. When a predetermined low fuel flow threshold level is eventually reached, for example 20 lph, the biasing force exerted on the plunger
270
by the biasing element
264
becomes larger than the force produced by the fuel flowing through the switch
42
′″″ via the inlet opening
252
. As a result, the plunger
270
moves toward and becomes pressed against the second contact
276
into an electrically closed position again. Consequently, the FET
100
in the electric voltage control circuit
44
′ slips back into conduction mode and the resistor
102
is thereby electrically shorted out. Thus, the full voltage potential (in this example, 13 volts) between the positive power node
15
and the negative power node
25
is again applied to the electric fuel pump motor
18
. Point
304
on the graph in
FIG. 14
illustrates this particular mode of operation.
With the maximum possible voltage again being applied to the electric fuel pump motor
18
, both the operational speed and fuel output of the fuel pump
19
increases such that, for example, fuel at 115 lph is delivered to the engine
30
and fuel at 105 lph is diverted into the fuel bypass line
34
by the bypass fuel pressure regulator
36
as dictated by the fuel demand of the engine
30
. Point
306
on the graph in
FIG. 14
illustrates this particular mode of operation.
As the fuel demand of the engine
30
thereafter continues to increase, the fuel flow diverted into the fuel bypass line
34
correspondingly decreases, thereby maintaining the switch
42
′″″ in an electrically closed position and the operational speed of the electric motor
18
and fuel pump
19
at a maximum. Point
308
on the graph of
FIG. 14
illustrates this particular mode of operation. Subsequently, as the fuel demand of the engine
30
decreases, the fuel flow diverted into the fuel bypass line
34
correspondingly increases until a predetermined high fuel flow threshold level is attained (for example, 120 lph). Once attained, the force of the fuel flow exerted against the plunger
270
is once again sufficient to overcome the biasing force of the biasing element
264
and thereby separate the plunger
270
from the second contact
276
and change the state of the switch
42
′″″ to an electrically open position. As a result, the FET
100
in the electric voltage control circuit
44
′ slips into non-conduction mode, and the voltage supplied to the electric fuel pump motor
18
is again reduced, for example, to 10 volts. Point
310
on the graph of
FIG. 14
illustrates this particular mode of operation. With the reduced voltage being supplied to the electric fuel pump motor
18
, the operational speed and fuel output of the fuel pump
19
is again reduced to a minimum level. At this minimum level, if the fuel demand of the engine
30
remains the same, then the amount of fuel diverted into the fuel bypass line
34
by the bypass fuel pressure regulator
36
is accordingly reduced. Point
312
on the graph of
FIG. 14
illustrates this particular mode of operation.
In summary, in operating the fuel system according to the various embodiments described hereinabove, the apparatus
50
is able to apply a current at two different voltage levels to the electric fuel pump motor
18
and thereby modulate the operational speed of the fuel pump
19
in a timed relationship or phase with the changing fuel demands of the engine
30
. In this way, the present invention provides a better overall means for delivering an amount of fuel to the engine
30
which better correlates with and more timely or rapidly responds to the actual fuel demand of the engine
30
. Because of the time lag between a rapid engine acceleration with its rapid increase in fuel demand and the response of the fuel system in delivering increased maximum fuel flow, the fuel system is designed and operated to normally and virtually always supply some fuel in excess of the engine fuel demand under all operating conditions. Further, it is to be understood that the particular switching speed of the electric voltage control circuit
44
can be controlled to a certain extent by calibrating the electrical values of the circuit elements included therein.
While the present invention has been described in what are presently considered to be the most practical and preferred embodiments and/or implementations, it is to be understood that the invention is not to be limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims, which scope is to be accorded the broadest interpretation so as to encompass modifications and equivalent structures as is permitted under the law. For example, the invention may be utilized in a return type fuel system with the fluid-activatable switch actuated by and responsive to the flow rate of the excess fuel returned from the engine and the control circuit may be a pulse width modulated (PWM) circuit applying a current to the electric motor at two different power levels to modulate the speed of the pump. A suitable PWM control circuit is disclosed in U.S. Pat. No. 5,265,644, the disclosure of which is incorporated herein by reference.
Claims
- 1. An apparatus for supplying fuel in a fuel system to an internal combustion engine comprising:an electric motor for driving a fuel pump; a fuel pump having an outlet configured to deliver fuel to the engine; a bypass fuel pressure regulator communicating with the pump outlet to regulate the pressure of fuel supplied to the engine and configured to divert excess fuel flow from the engine in response to the fuel demand of the engine; a fluid-activatable switch communicating with the pressure regulator and receiving the excess fuel from the pressure regulator and returning the excess fuel to a fuel tank; and an electric control circuit electrically connected to the switch, capable of being electrically connected to an electric voltage power source and to the electric motor for supplying an electric current to the electric motor; wherein said switch is manipulable into an electrically open position and an electrically closed position as determined by the rate of flow of excess fuel from the pressure regulator; and wherein said control circuit is capable of adjusting the magnitude of the power of the current supplied to the electric motor as dictated by the position of the switch such that the speed of said electric fuel pump motor is modulated in accordance with changes in the rate of flow of excess fuel and the position of the switch.
- 2. The apparatus according to claim 1, wherein said fluid-activatable switch comprises:an elongate body having an inlet opening at one end, a stop opening at the opposite end, at least one outlet opening, and a longitudinal chamber in communication with said inlet opening, said stop opening, and said at least one outlet opening; a plunger, slidingly received within said chamber, having a shoulder portion proximate said at least one outlet opening in said body, and a single electrically conductive contact mounted on said shoulder portion proximate said inlet opening; an adjustable stop received in said stop opening having a tail portion extending into said chamber and an exposed head portion; a yieldable and resilient biasing element, received between said plunger and said stop, having a first end bearing and abutting said tail portion of said stop and a second end extending into said chamber and abutting said plunger; and a pair of electrically conductive contacts electrically connected to said electric control circuit and exposed within said chamber of said body substantially between said inlet opening and said at least one outlet opening; wherein said chamber of said body defines a fuel flow path from said inlet opening to said at least one outlet opening, said single contact and said shoulder portion of said plunger are situated in said fuel flow path and yieldably biased against fuel flowing within said fuel flow path, said plunger is capable of being moved as dictated by the rate of the excess fuel flowing along said fuel flow path such that said switch is in one of said electrically open position and said electrically closed position, and said open position is defined as said single contact being separated from said pair of contacts and said closed position is defined as said single contact being in electrical contact with said pair of contacts.
- 3. The apparatus according to claim 2, wherein said longitudinal chamber is substantially cylindrical.
- 4. The apparatus according to claim 3, wherein said inlet opening and said stop opening are substantially aligned with the longitudinal axis of said longitudinal chamber.
- 5. The apparatus according to claim 3, wherein said shoulder portion of said plunger is substantially cylindrical and has a cross-sectional area that approaches the cross-sectional area of said longitudinal chamber.
- 6. The apparatus according to claim 2, wherein each of said at least one outlet opening is defined within a common middle portion of said elongate body.
- 7. The apparatus according to claim 2, wherein said adjustable stop and said stop opening are both threaded such that said stop is adjustably threadingly received in said stop opening.
- 8. The apparatus according to claim 2, wherein said stop is one of a plug and a cup-shaped closure.
- 9. The apparatus according to claim 2, wherein said resilient biasing element is a spring.
- 10. The apparatus according to claim 2, wherein said plunger has a plurality of integral fins in sliding contact with the inner surface of said elongate body.
- 11. The apparatus according to claim 2, wherein said single electrically conductive contact is an annular disc of metal.
- 12. The apparatus according to claim 11, wherein said plunger has a stem integral with said shoulder portion and extending toward said inlet opening, and said annular disc is adjustably fixed on said stem proximate the extended end of said stem.
- 13. The apparatus according to claim 12, wherein said longitudinal chamber is substantially cylindrical, and said inlet opening and said stem are substantially aligned with the longitudinal axis of said longitudinal chamber.
- 14. The apparatus according to claim 2, wherein said single electrically conductive contact is an annular ring of metal.
- 15. The apparatus according to claim 14, wherein said plunger has a pocket integral with said shoulder portion and facing said inlet opening, and said annular ring is fixedly seated in said pocket such that said annular ring extends toward said inlet opening partially beyond the confines of said pocket.
- 16. The apparatus according to claim 2, wherein said pair of electrically conductive contacts is a pair of prongs of metal.
- 17. The apparatus according to claim 16, wherein said elongate body has a plug opening substantially between said inlet opening and said at least one outlet opening, said fluid-activatable switch includes an electrically insulative plug casing sealingly situated within said plug opening, and said pair of prongs is mounted in said plug casing such that said prongs are at least partially exposed within said longitudinal chamber and are electrically connected to said electric voltage control circuit.
- 18. The apparatus according to claim 2, wherein said pair of electrically conducive contacts is a pair of flexible prongs of metal and sealingly mounted in the wall of said longitudinal chamber such that said flexible prongs protrude into said chamber substantially between said inlet opening and said at least one outlet opening.
- 19. The apparatus according to claim 18, wherein said elongate body includes a plurality of laminar flow guide structures integral with the wall of said longitudinal chamber and situated within said chamber proximate said inlet opening, and at least one of said laminar flow guide structures has a stop surface for physically limiting the extent of flexing of at least one of said flexible prongs when said fluid-activatable switch is in said electrically closed position.
- 20. The apparatus according to claim 1, wherein said electric control circuit comprises:an electrically resistive circuit element; and means for electrically sensing the position of said fluid-activatable switch and selectively connecting said resistive circuit element in electrical series with said electric motor and to said electric voltage power source as dictated by said sensed position of said switch.
- 21. The apparatus according to claim 20, wherein said electrically resistive circuit element is a resistor.
- 22. The apparatus according to claim 20, wherein said position sensing and selective connecting means comprises a field-effect transistor.
- 23. The apparatus of claim 1, wherein said fluid-activatable switch comprises:an elongate body having an inlet opening at one end, an end outlet opening at the opposite end, at least one side outlet opening, and a longitudinal chamber in communication with said inlet opening, said end outlet opening, and said at least one side outlet opening; an electrically conductive first contact, electrically connected to said electric control circuit, mounted and exposed within said chamber of said body proximate said end outlet opening; an electrically conductive resilient biasing element having a first end electrically attached to said first contact and a second end extending into said chamber; an electrically conductive plunger, slidingly received within said chamber, having a biased side electrically attached to said second end of said biasing element, and an impact side opposite said biased side and movably situated substantially between said inlet opening and said at least one side outlet opening in said body; and an electrically conductive second contact, electrically connected to said electric control circuit, mounted and exposed within said chamber of said body substantially between said inlet opening and said at least one side outlet opening; wherein said chamber of said body defines a fuel flow path from said inlet opening to said outlet openings, said plunger is situated within said fuel flow path and yieldably biased against fuel flowing within said fuel flow path, said plunger is capable of being moved as dictated by said fuel flowing within said fuel flow path such that said switch is in one of said electrically open position and said electrically closed position, and said open position is defined as said plunger being separated from said second contact and said closed position is defined as said plunger being in electrical contact with said second contact.
- 24. The apparatus according to claim 23, wherein said longitudinal chamber is at least substantially funnel-shaped between substantially said second contact and said at least one side outlet opening and cylindrical between substantially said at least one side outlet opening and said first contact.
- 25. The apparatus according to claim 23, wherein each of said at least one side outlet opening is defined within a common middle section of said elongate body between said first contact and said second contact.
- 26. The apparatus according to claim 23, wherein said resilient biasing element is a helical spring of metal.
- 27. The apparatus according to claim 23, wherein said electrically conductive plunger is substantially spherical.
- 28. The apparatus according to claim 27, wherein said longitudinal chamber is substantially cylindrical proximate said at least one side outlet opening, and the diameter of said spherical plunger substantially approaches the diameter of said longitudinal chamber proximate said at least one side outlet opening.
- 29. The apparatus according to claim 27, wherein said electrically conductive spherical plunger is a ball of metal.
- 30. The apparatus according to claim 23, wherein said electrically conductive second contact comprises a pair of metal prongs electrically shorted together.
- 31. The apparatus accordingly to claim 30, wherein said electrically conductive first contact comprises another pair of metal prongs electrically shorted together.
- 32. The apparatus according to claim 31, wherein said metal prongs of said second contact are substantially parallel to each other, and said metal prongs of said first contact are substantially parallel to each other.
- 33. The apparatus according to claim 1 wherein the fuel system is a returnless fuel system.
- 34. The apparatus according to claim 1 wherein the electric control circuit is configured to adjust the magnitude of the voltage of the current applied to the electric motor as dictated by the position of the switch.
- 35. The apparatus according to claim 1 wherein the control circuit is configured as a pulse width modulation circuit to adjust the power of the current applied to the electric motor as dictated by the position of the switch.
US Referenced Citations (12)