Information
-
Patent Grant
-
6481426
-
Patent Number
6,481,426
-
Date Filed
Tuesday, November 28, 200024 years ago
-
Date Issued
Tuesday, November 19, 200222 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Fletcher, Yoder & Van Someren
-
CPC
-
US Classifications
Field of Search
US
- 123 633
- 123 298
- 174 355 M
- 174 35 TS
- 174 104
-
International Classifications
-
Abstract
An engine system having a low EMI/RFI signature. The system comprises a two-stroke engine having a cylinder with a piston sized for reciprocal motion through the cylinder. The two-stroke engine further includes an injector deployed in communication with the combustion chamber to discharge a fuel into the combustion chamber. An electronic control unit controls the injection and ignition for the engine, and an EMI/RFI reduction system is utilized to lower the electromagnetic and radio frequency interference signature of the engine.
Description
FIELD OF THE INVENTION
The present invention relates generally to an internal combustion engine, and particularly to a two-stroke engine that utilizes a system for lowering the electromagnetic and radio frequency interference signature.
BACKGROUND OF THE INVENTION
Internal combustion engines generally have one or more cylinders through which one or more pistons move in a reciprocating manner. Each piston is connected to a crankshaft by a connecting rod able to deliver force from the piston to the crankshaft to rotate the crankshaft. Power to drive the piston is provided by igniting a fuel-air mixture disposed in the cylinder on a side of the piston opposite the connecting rod. The fuel-air mixture is ignited by some type of ignition device, such as a spark plug.
Internal combustion engines typically utilize a variety of conductors, e.g. wires, for carrying various electronic signals. For example, an electronic control unit may receive a variety of signals from various sensors and output a variety of signals to, for example, an injection system and an ignition system. The ignition system also utilizes a variety of electric signals, including electric signals provided to the one or more spark plugs used to ignite a fuel/air mixture disposed in the combustion chamber. Typically, such electric signals provide an electromagnetic and radio frequency signature that can cause unwanted interference. In certain applications, it would be advantageous to reduce the electromagnetic interference and radio frequency interference produced by the electronics of the engine.
SUMMARY OF THE INVENTION
According to one aspect of the present invention, a low signature engine system is provided to reduce electromagnetic interference (EMI) and radio frequency interference (RFI). The system includes a two-stroke engine. The engine has a combustion chamber and an injector deployed in communication with the combustion chamber to discharge a fuel thereto. Additionally, the engine includes an electronic control unit in communication with the injector to control the discharge of fuel. Also, an EMI/RFI reduction system is used to lower the electromagnetic and radio frequency interference signature of a plurality of conductors utilized by the two-stroke engine during operation.
According to another aspect of the present invention, a method is provided for reducing the electromagnetic and radio frequency signature of an engine having a plurality of electrical conductors. The method comprises placing at least some of the plurality of electrical conductors into a bundle. The bundle is surrounded with a conductive layer. Additionally, a conductive strip is deployed intermediate the bundle and the conductive layer. The conductive strip is then grounded to reduce the EMI/RFI signature.
According to another aspect of the present invention, a method is provided for making an engine having a reduced electromagnetic and radio frequency signature. The method includes providing a two-stroke engine having a combustion chamber. The method further includes injecting a fuel directly into the combustion chamber during operation. Additionally, the method comprises limiting the electromagnetic and radio frequency interference by providing an EMI/RFI barrier around a plurality of electrical conductors.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements, and:
FIG. 1
is a perspective view of a watercraft powered by an exemplary engine, according to a preferred embodiment of the present invention;
FIG. 2
is a schematic cross-sectional view of a single cylinder in an exemplary two-stroke engine that may be utilized with the watercraft illustrated in
FIG. 1
;
FIG. 3
is an enlarged view of the combustion chamber of the engine illustrated in
FIG. 2
;
FIG. 4
is a schematic representation of an exemplary fuel delivery system utilizing a fuel-only direct injection system;
FIG. 5
is a schematic representation of an alternate fuel delivery system for direct injection of fuel and air;
FIG. 6
is a schematic representation of an alternate fuel delivery system utilizing a fuel rail;
FIG. 7
is a schematic representation of an electronic control unit having a plurality of fuel maps;
FIG. 8
is a diagram showing exemplary crankshaft angles during injection and ignition under certain engine operating conditions;
FIG. 9
is a front view of a cable bundle that limits EMI/RFI emissions;
FIG. 10
is a cross-sectional view taken generally along line
10
—
10
of
FIG. 9
; and
FIG. 11
is an illustration of an engine drainage system.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The present technique for utilizing a plurality of fuel types in an internal combustion engine can be used in a variety of engines and environments. For the sake of clarity and explanation, however, the invention is described in conjunction with a cross scavenged engine that operates on a two-stroke cycle and powers a watercraft. The exemplary embodiment described herein should not be construed as limiting, however, and has potential uses in other types of engines and applications.
Referring generally to
FIG. 1
, an exemplary application of the present system and methodology is illustrated. In this application, a watercraft
20
, such as an inflatable boat, is powered by an engine
22
disposed in an outboard motor
24
. In this embodiment, outboard motor
24
is mounted to a transom
26
of watercraft
20
. Engine
22
is a two-stroke engine that is cross scavenged and utilizes a fuel injection system, as explained more fully below.
Referring generally to
FIGS. 2 and 3
, a single cylinder of an exemplary two-stroke engine
22
is illustrated. In this embodiment, engine
22
includes at least one cylinder
30
having an internal cylinder bore
32
through which a piston
34
reciprocates. Piston
34
typically includes one or more rings
36
that promote a better seal between the piston
34
and cylinder bore
32
as piston
34
reciprocates within cylinder
30
.
Piston
34
is coupled to a connecting rod
38
by a pin
40
, sometimes referred to as a wrist pin. Opposite pin
40
, connecting rod
38
is connected to a crankshaft
42
at a location
43
offset from a crankshaft central axis
44
. Crankshaft
42
rotates about axis
44
in a crankshaft chamber
46
defined by a housing
48
.
At an end of cylinder
30
opposite crankshaft housing
48
, a cylinder head
50
is mounted to cylinder
30
to define a combustion chamber
52
. Cylinder head
50
may be used to mount a fuel injection system
54
able to supply fuel to combustion chamber
52
. In one preferred embodiment, fuel injection system
54
is a direct injection system having an injector or injector pump
55
mounted to cylinder head
50
, generally above combustion chamber
52
, to spray a fuel directly into the combustion chamber.
Cylinder head
50
also may be used to mount a spark plug
56
to ignite an air-fuel mixture in combustion chamber
52
. Injector pump
55
and spark plug
56
are received in openings
58
and
60
, respectively. Openings
58
and
60
may be formed through the wall that forms either cylinder head
50
or cylinder
30
. In the illustrated embodiment, openings
58
and
60
both are formed through the wall of cylinder head
50
for communication with combustion chamber
52
within a recessed internal region
62
of cylinder head
50
. Cylinder head
50
also may include a notch
65
that enhances mixing of the fuel and air.
By way of example, injector pump
55
may be generally centrally located at the top of cylinder head
50
, as illustrated best in FIG.
3
. In this exemplary embodiment, injector
55
is oriented at an angle with respect to the longitudinal axis
63
of cylinder
30
. As illustrated, spark plug
56
also may be disposed at an angle such that its electrodes
64
are positioned in a fuel spray pattern
66
during injection of fuel into recessed region
62
of combustion chamber
52
. Fuel spray pattern
66
is the “cone” or other pattern of fuel spray injected by injector pump
55
.
A deflector pin
68
may be positioned such that it extends partially into fuel spray pattern
66
intermediate an injection nozzle
70
of injector pump
55
and electrodes
64
of spark plug
56
. Deflector pin
68
reduces or eliminates the amount of fuel sprayed directly onto electrode
64
. This, in turn, reduces the chance of fouling spark plug
56
. Additionally, a combustion sensor
72
, such as an oxygen sensor or knock sensor, may be positioned in communication with combustion chamber
52
within recessed region
62
.
In a cross scavenged engine, cylinder
30
includes one or more intake or scavenge ports
74
and one or more exhaust ports
76
. Generally, the scavenge port
74
and exhaust port
76
are disposed on generally opposite sides of cylinder
30
at a common axial or longitudinal distance along cylinder
30
. The arrangement of ports makes it possible to drill the scavenge and exhaust ports directly in a single operation performed from the exhaust port side. This greatly reduces the manufacturing costs of the cross scavenged engine as compared to an equivalent loop scavenged engine. The cross scavenged cylinder also includes a deflector
78
designed to deflect air incoming through scavenge port or ports
74
for promoting mixing of air and fuel in combustion chamber
52
. In the illustrated embodiment, deflector
78
is disposed on a crown
80
of piston
34
. An exemplary deflector
78
includes a front deflector face or wall
82
, a top region
84
and a declined region
86
generally disposed towards the exhaust port side of piston
34
. Cylinder head notch
65
preferably is positioned such that it is proximate the transition between front deflector wall
82
and top region
84
when piston
34
is at top dead center.
In operation, piston
34
travels towards cylinder head
50
to compress a charge of air within combustion chamber
52
. Simultaneously, injector pump
55
injects fuel to create a fuel air mixture that is ignited by an appropriately timed spark across electrode
64
. As piston
34
travels towards cylinder head
50
, air is drawn through an inlet port
88
into crankshaft chamber
46
and cylinder
30
on a side of piston
34
opposite combustion chamber
52
. A valve
90
, such as a reed valve, allows the air to pass into engine
22
but prevents escape back through inlet port
88
.
Upon ignition of the fuel-air charge in combustion chamber
52
, piston
34
is driven away from cylinder head
50
past exhaust port
76
through which the exhaust gasses are discharged. As piston
34
moves past exhaust port
76
, scavenge port
74
is fully opened. Air from crankshaft chamber
46
is forced along a transfer passage
92
and through scavenge port
74
into cylinder
30
on the combustion chamber side of piston
34
. The incoming air is deflected upwardly by deflector
78
to facilitate removal of exhaust gasses through exhaust port
76
while providing a fresh charge of air for mixing with the injected fuel. Effectively, the downward travel of piston
34
compresses the air in crankshaft chamber
46
and forces this fresh charge of air into cylinder
30
for mixing with the next charge of fuel and ignition by spark plug
56
.
Preferably, the angle of injector pump
55
is selected to direct fuel spray pattern
66
generally towards the internal wall of cylinder
30
proximate scavenge port
74
. This aids in the mixing of fuel and air as the incoming air, deflected upwardly by deflector
78
, meets the charge of fuel injected through injection nozzle
70
. In an exemplary embodiment, if the injector nozzle
70
is disposed near longitudinal axis
63
and the bore/stroke ratio is approximately 1, the angle between injector pump
55
and longitudinal axis
63
is preferably in the range from 5 to 25 degrees. Regardless of the angle, it is preferred that injector pump
55
be positioned and/or angled such that a majority of the fuel spray is directed into the hemisphere or side of cylinder
30
having scavenge port
74
.
The actual amount of fuel injected and the timing of the injection can vary greatly depending on a variety of factors, including engine size, engine design, operating conditions, engine speed, etc. However, the utilization of fuel injection system
54
and the precise control over injector
55
allows the amount of fuel injected and the timing of the ignition to be carefully controlled. Also, the heat otherwise retained in piston
34
and deflector
78
is removed as fuel is sprayed onto the piston and vaporized. These factors permit increases in efficiency, fuel economy and power that would otherwise not be achievable with cross scavenged engines. The factors also permit a variety of fuels to be utilized in engine
22
.
Referring generally to
FIGS. 4 through 6
, exemplary fuel injection systems
54
are illustrated. In
FIG. 4
, fuel injection system
54
comprises a direct fuel injection system in which only liquid fuel is directly injected into cylinder
30
of engine
22
. Fuel is supplied to injector
55
via a fuel reservoir
110
, e.g., a low pressure fuel supply such as a fuel tank, and fuel supply lines
112
. In this embodiment, fuel injector
55
may be of a variety of injector types, including electrically, hydraulically or mechanically actuated injectors. In this type of system, a pressure pulse created in the liquid fuel forces a fuel spray to be formed at the mouth or outlet of nozzle
70
for direct, in-cylinder injection. The operation of injector
55
is controlled by an electronic control unit (ECU)
114
. The ECU
114
typically includes a programmed microprocessor or other digital processing circuitry, a memory device such as an EEPROM for storing a routine employed in providing command signals from the microprocessor, and a drive circuit for processing commands or signals from the microprocessor, as known to those of ordinary skill in the art.
An alternate embodiment of fuel injection system
54
, labeled
54
′ is illustrated in FIG.
5
. In this embodiment, both fuel and air are directly injected into cylinder
30
of engine
22
by injector
55
. Fuel is supplied via a fuel reservoir
116
, e.g., a low pressure fuel supply such as a fuel tank, and fuel supply lines
118
. Additionally, high pressure air is supplied to injector
55
via an air supply
120
and air supply line
122
. Again, the activation of injector
55
is controlled by an ECU
124
. In this type of system, both the air and the fuel for combustion are provided by injector
55
.
Another embodiment of fuel injection system
54
, labeled
54
″, is illustrated in FIG.
6
. In this embodiment, a fuel rail
126
is utilized to supply fuel to one or more cylinders
30
of engine
22
. Fuel rail
126
supply high pressure fuel to injectors
55
, which are actuated between an open and a closed position to selectively permit the injection of high pressure fuel into one or more cylinders
30
, as known to those of ordinary skill in the art.
In the embodiment illustrated, a low pressure fuel supply
128
provides fuel to a high pressure fuel supply
130
via appropriate fuel lines
132
. High pressure fuel supply
130
, in turn, supplies fuel under injection pressure to fuel rail
126
via supply lines
134
.
Referring generally to
FIG. 7
, a preferred electronic control unit, e.g. ECU
114
, is designed to receive a variety of inputs via a plurality of input lines
300
. Input lines
300
carry input signals to the electronic control unit
114
, such as signals from sensors, e.g. sensor
72
. Other signals input to control unit
114
include engine speed (RPM), throttle position (load) and inputs from a fuel selector switch
302
. Fuel selector switch
302
may be a simple mechanical switch having two or more positions representative of two or more fuel types that may be combusted in internal combustion engine
22
. Optionally, fuel selector switch
302
may comprise a sensor
304
, typically disposed in a fuel reservoir, e.g. reservoir
110
. Fuel sensor
304
is able to detect the fuel type placed into the fuel tank. The sensor outputs a signal representative of the fuel type to electronic control unit
114
.
Based on the input from the fuel selector switch
302
, electronic control unit
114
selects a fuel map from a plurality of fuel maps
306
. Each fuel map
306
corresponds to a different fuel type that may be utilized by engine
22
. Exemplary fuel types include gasoline, kerosene, jet fuel, diesel and other petroleum liquid based fuels.
In the preferred embodiment, fuel maps
306
are stored in electronic control unit
114
as lookup tables
308
. Each lookup table
308
is designed for the specific, selected fuel to be combusted in internal combustion engine
22
. In other words, fuel maps
306
allow electronic control unit
114
to output control signals through a plurality of control lines
310
to facilitate combustion of the particular fuel type within combustion chamber
52
. This unique ability to customize the control according to fuel type permits operation of engine
22
on a variety of fuels. The content of lookup tables
308
varies depending on various parameters, including fuel type, engine size, engine design and environment in which the engine is utilized, as is understood by those of ordinary skill in the art. The system also can be an active mapping system in which lookup tables are modified based on sensor (e.g., a combustion or knock sensor) feedback.
Exemplary output lines carry signals controlling the point at which fuel is injected into combustion chamber
52
(fuel injection angle) and the quantity of fuel injected into the combustion chamber. These signals are output to injection system
54
which appropriately controls the actuation of each injector
55
. Other exemplary output lines provide signals to an engine ignition system
312
that controls, for instance, spark timing and spark duration at electrodes
64
of spark plug
56
. Each of these controlled outputs, e.g. fuel injection angle, fuel quantity, spark timing, spark duration, may be uniquely controlled according to a specific fuel map
306
having a lookup table
308
that corresponds to the fuel type, e.g. A, B or C, of the fuel disposed in a fuel reservoir, e.g. reservoir
110
.
Preferably, fuel maps
306
are designed to facilitate cold start capabilities with a variety of fuels. With kerosene, for instance, engine
22
can be difficult to start when cold. However, with direct fuel injection and a properly designed fuel map, engine
22
can be readily started and run on kerosene.
For example, under specific conditions, such as cold starts on kerosene, fuel maps
306
may be designed to inject fuel into combustion chamber
52
at or near the highest cylinder pressure near top dead center (TDC). The higher pressure creates a warmer environment that facilitates ignition. Additionally, the higher pressure facilitates atomization of the fuel as it is injected into the high pressure, warm environment. The warmer temperature and better atomization promotes better ignition and starting of engine
22
. In one exemplary embodiment, fuel may be injected into combustion chamber
52
at between 0 and 10 degrees before top dead center, as illustrated by block
314
in FIG.
8
.
Similarly, the ignition or spark at electrodes
64
may be controlled during starting to facilitate cold starts with a variety of fuels, e.g. kerosene. In an exemplary embodiment, a spark is established at electrodes
64
just before, during and after the piston
34
moves past TDC, as indicated by block
316
of FIG.
8
. In the example provided, fuel is directly sprayed towards the spark plug gap and multiple sparks or a single long spark is initiated before the fuel reaches the spark plug electrodes. In this example, the continuous spark or multiple small sparks are formed before, during and after the injection event. In addition to directing fuel towards the spark plug electrodes, the fuel may be directed into the incoming scavenge air and areas of high charge motion, as described above, to better atomize the fuel. Also, combustion chamber
52
may be formed as a compact chamber containing the spark plug
56
and injector nozzle
70
to mechanically contain the fuel-air mixture in the immediate vicinity of spark plug
56
.
In this example, the output signal to ignition system
312
may be programmed to cause multiple sparks or a single long spark at electrode
64
. For example, between approximately 5 degrees before top dead center and approximately 10 degrees after top dead center, a single long spark or a plurality of sparks, e.g., 10-15 sparks, may be created across electrode
64
.
Another unique feature of engine
22
is the protection provided against electromagnetic and radio frequency interference. The variety of wires and other conductors that carry input and output signals as well as electric current directed to electrode
64
of spark plug
56
can provide substantial electromagnetic interference (EMI) and radio frequency interference (RFI). In certain applications of engine
22
, it is desirable to eliminate or lower the signature of the EMI and RFI.
In a preferred embodiment, many of the conductive lines, such as input lines
300
and output lines
310
are bundled together in one or more wire bundles
318
, as illustrated in dashed lines in
FIG. 7. A
variety of conductors utilized for carrying sensor signals, output control signals, and ignition currents can be bundled in one or more wire bundles
318
. Preferably, each wire bundle includes an EMI/RFI signature reduction system
320
, as illustrated in
FIGS. 9 and 10
. In one preferred embodiment, a plurality of conductive wires
322
, each typically having an insulative coating
324
, are bundled together and wrapped in a surrounding, insulative layer
326
. An exemplary insulative layer
326
comprises a shrink tube disposed about wires
322
.
Additionally, a conductive layer, preferably a conductive mesh layer
328
, is disposed within insulative layer
326
surrounding wires
322
, as best illustrated in
FIG. 10. A
bare, conductive wire
330
is squeezed between mesh layer
328
and the plurality of bundled wires
322
. Each of the bare conductive wires
330
preferably is connected to a common ground. This signature reduction system effectively reduces the electromagnetic interference and radio frequency interference that would otherwise be present during operation of engine
22
.
In one particular, exemplary application, engine
22
is utilized in a submersible outboard motor
24
. Allowing outboard motor
24
to be submersible, particularly when combined with the multi-fuel capabilities, permits use of outboard motor
24
in a wide variety of environments, applications and geographical regions. Also, the cold-start capability and the use of precisely controlled injector pumps, as described above, permit the straightforward construction of an outboard motor
24
able to start and run dependably on one or more fuel types. This is particularly true for the two-stroke, cross scavenged engine described herein.
However, if engine
22
is submersed in water, certain portions of the engine are protected from the inflow of water while other portions are designed to permit the ready evacuation of water. For example, fuel may be delivered to injector pump
55
from fuel tank
110
, and for oil injected engines, oil is delivered to engine
22
from an oil tank
332
, as illustrated in FIG.
11
. Fuel is typically pumped to engine
22
by an appropriate fuel pump
333
and oil is delivered from oil tank
332
to engine
22
by an oil pump
334
.
Pumping of these fluids requires that the oil tank and fuel system be vented via an oil vent
336
and a fuel vent
338
. Oil vent
336
may be deployed in communication with oil tank
332
, and fuel vent
338
may be deployed in communication with, for example, a vapor separator
339
coupled to fuel tank
110
.
A pair of valves
340
,
342
are coupled to vents
336
and
338
, respectively. Each valve
340
and
342
includes an actuator
344
and
346
, respectively, that permits the vents to be opened or closed. Thus, prior to submersion of outboard motor
24
and engine
22
, valves
340
and
342
simply are moved to a closed position. Following submersion, valves
340
and
342
are moved to an open position before engine
22
is started and operated. Exemplary valves include mechanically actuated valves that can be physically adjusted by moving actuator
344
and actuator
346
between the open and closed positions.
During submersion, cylinder
30
and crankshaft chamber
46
often intake water that must be substantially removed prior to starting the engine. Accordingly, a drainage opening
348
is formed through housing
48
generally at the lowermost portion of crankshaft chamber
46
when outboard motor
24
is mounted in a normal operating position. Drainage port
348
is coupled to a valve
350
having an actuator
352
able to move the valve
350
between an open and a closed position. Thus, when engine
22
is retrieved from its submerged location, the engine can be drained simply by opening valve
350
and allowing any water accumulated in cylinder
30
and crankshaft chamber
46
to drain through valve
350
. Additionally, any water accumulated in combustion chamber
52
can be allowed to drain through passage
92
and crankshaft chamber
46
. Once drained, valve
350
is moved to its closed position via actuator
352
, thereby permitting the normal operation of engine
22
—provided valves
340
and
342
have been opened. An exemplary valve
350
is a simple mechanical valve of the type in which actuator
352
may be physically moved between an open and a closed position.
To carry out a submersion and retrieval of outboard motor
24
, valves
340
and
342
are closed to prevent water from entering areas, such as oil tank
332
and any portion of the fuel delivery system. Once retrieved, valves
340
and
342
are moved to an open position for starting and operation of engine
22
. Valve
350
, on the other hand, is initially opened to drain any accumulated water from the interior of engine
22
. After drainage, valve
350
is closed and engine
22
is started.
It will be understood that the foregoing description is of preferred exemplary embodiments of this invention, and that the invention is not limited to the specific forms shown. For example, the fuel injection systems described are exemplary embodiments, but a variety of injection systems can be utilized with an engine, such as the cross scavenged engine described. Additionally, a variety of engine configurations, ignition systems, displacements, cylinder numbers, piston designs, scavenge port designs and exhaust port designs can be utilized. These and other modifications may be made in the design and arrangement of the elements without departing from the scope of the invention as expressed in the appended claims.
Claims
- 1. A low signature system, comprising:a two-stroke engine having: a combustion chamber; an injector deployed in communication with the combustion chamber to discharge a fuel into the combustion chamber; an electronic control unit in communicaton with the injector to control the discharge of the fuel; and an EMI/RFI reduction system to lower the electrognetic and radio frequency interference signature of a plurality of conductors utilized by the two-stroke engine during operation, wherein the EMI/RFI reduction system comprises: an outer insulative layer disposed about a bundle of the plurality of conductors; a conductive layer disposed intermediate the outer insulative layer and the bundle; and a bare, conductive wire disposed intermediate the conductive layer and the bundle.
- 2. The low signature engine system as recited in claim 1, wherein the conductive layer comprises a mesh layer.
- 3. The low signature engine system as recited in claim 1, wherein the bare conductive wire is connected to ground.
- 4. The low signature engine system as recited in claim 1, wherein the EMI/RFI reduction system comprises:a second outer insulative layer disposed about a second bundle of the plurality of conductors; a second conductive layer disposed intermediate the second outer insulative layer and the second bundle; and a second bare, conductive wire disposed intermediate the second conductive layer and the second bundle.
- 5. The low signature engine system as recited in claim 4, wherein the conductive layer and the second conductive layer each comprise a mesh layer.
- 6. The low signature engine system as recited in claim 4, wherein the bare conductive wire and the second bare conductive wire are connected to ground.
- 7. The low signature engine system as recited in claim 1, wherein the two-stroke engine comprises a cross-scavenged engine.
- 8. A method for reducing the electromagnetic and radio frequency signature of an engine having a plurality of electrical conductors, comprising:placing at least some of the plurality of electrical conductors into a bundle; surrounding the bundle with a conductive layer; deploying a conductive strip intermediate the bundle and the conductive layer; grounding the conductive strip; and utilizing the plurality of electrical conductors in the engine.
- 9. The method as recited in claim 8, wherein the engine comprises a direct injected two-stroke engine.
- 10. The method as recited in claim 9, further comprising providing an insulative layer around the conductive layer.
- 11. The method as recited in claim 10, wherein surrounding comprises surrounding the bundle with a conductive mesh layer.
- 12. The method as recited in claim 11, wherein deploying comprises deploying a conductive wire longitudinally along the bundle.
- 13. The method as recited in claim 12, wherein placing comprises arranging the plurality of electrical conductors into a plurality of bundles.
- 14. The method as recited in claim 13, wherein surrounding comprises surrounding each bundle with a conductive mesh layer.
- 15. The method as recited in claim 14, wherein deploying comprises deploying a conductive wire intermediate each of the bundles and the conductive mesh layer surrounding the bundle.
- 16. The method as recited in claim 15, wherein grounding comprises grounding each conductive wire.
- 17. A system for reducing the electromagnetic and radio frequency signature of an engine having a plurality of electrical conductors, comprising:means for placing at least some of the plurality of electrical conductors into a bundle for use by a two-stroke engine; means for surrounding the bundle with a conductive layer; means for deploying a conductive strip intermediate the bundle and the conductive layer; and means for grounding the conductive strip.
- 18. The system as recited in claim 17, further comprising means for directly injecting a fuel into the two-stroke engine.
- 19. A method for making an engine having a reduced electromagnetic and radio frequency signature, comprising:providing a two-stroke engine having a combustion chamber; injecting a fuel directly into the combustion chamber during operation; and limiting the electromagnetic and radio frequency interference by providing a grounded EMI/RFI barrier around a plurality of electrical conductors.
- 20. The method as recited in claim 19, wherein limiting comprises surrounding the plurality of conductors with a conductive layer.
- 21. The method as recited in claim 20, wherein surrounding comprises surrounding the plurality of conductors with a conductive mesh layer.
- 22. The method as recited in claim 21, wherein limiting comprises deploying a conductive wire longitudinally between the conductive mesh layer and the plurality of conductors.
- 23. The method as recited in claim 22, wherein limiting further comprises providing an insulative layer about the conductive mesh layer.
US Referenced Citations (10)