Title of Invention

A FUEL INJECTION SYSTEM WITH MULTIPLE INJECTION BLEND FOR DIRECT FUEL INJECTION ENGINE AND ITS METHOD THEREOF

Abstract A fuel injection system for a direct fuel injection engine includes an injection mode module. The injection mode module selects a fuel injection mode to be one of a single injection mode and a dual injection mode. A fuel injection command module transitions between the single and dual injection modes by varying the timing of fuel injection events relative to a crankshaft position.
Full Text 1
MULTIPLE INJECTION BLEND FOR DIRECT INJECTED ENGINES
FIELD
[0001] The present disclosure relates to methods and systems for
direct fuel injection engines.
BACKGROUND
[0002] The statements in this section merely provide background
information related to the present disclosure and may not constitute prior art.
[0003] Controlling the amount of fuel and air to be delivered per
cylinder for a four stroke internal combustion engine is important to achieve
optimum performance. Proper timing of intake and exhaust valves also
provide for better performance. Conventional engines include camshafts that
regulate the timing of the valves. The rotation of the camshaft can be
controlled to ensure proper timing of each valve. In addition cam phasers
may be included to alter the position of the camshafts relative to the
crankshaft, which provides for further opportunities to properly adjust the
timing of each valve.
[0004] The placement of fuel injectors within the engine and the
control of fuel injection timing also impacts engine performance. Spark-
ignited direct injected (SIDI) engines locate one fuel injector per cylinder,
mounted directly over the cylinder head. Each injector is controlled
individually to inject fuel directly into the cylinder.
[0005] Conventional methods of controlling fuel during idle
conditions in a SIDI engine include intentionally retarding the spark timing in
order to provide a reserve torque. Spark timing is then advanced when a
request for torque is initiated. This allows the engine to respond to load
demands during idle operation. Retarding spark at idle provides for sub-
optimal efficiency.

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[0006] Other methods of fuel injection control include delivering
multiple fuel injection events per cylinder per combustion cycle. A direct
injection engine may use two injection events per cylinder per combustion
cycle in special operation regimes to provide additional energy for converter
lightoff, a smooth idle, and reduce engine knock. Unfortunately, the dual
injection mode of operation produces higher hydrocarbon emissions and
particulates. Accordingly, engine control may primarily include providing one
injection event per cylinder per combustion cycle for emissions reasons. The
dual injection method may be sparingly used for special operation regimes.
[0007] Dual injection per cylinder per combustion cycle generates
more or less engine torque than a single injection mode within the same
engine at similar operating conditions. Accordingly, drivability may be
affected by sudden engine output torque changes during periods when the
fuel delivery mode changes from a single to a multiple injection mode and vice
versa.
SUMMARY
[0008] Accordingly, a fuel injection system for a direct fuel injection
engine is provided. The system includes an injection mode module to select a
fuel injection mode to be one of a single injection mode and a dual injection
mode and a fuel injection command module that transitions between the
single and dual injection modes by varying the timing of fuel injection events
relative to a crankshaft position.
[0009] In addition, a fuel injection method of a direct fuel injection
engine is provided. The method includes operating the engine in a single
injection mode, commanding fuel delivery at a first crankshaft position,
receiving a request to transition from a single injection mode to a dual
injection mode and transitioning to the dual injection mode by commanding
fuel delivery at a second crankshaft position and at a third crankshaft position
wherein the third crankshaft position is changed incrementally during

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subsequent combustion cycles until a target third crankshaft position is
reached.
[0010] Further areas of applicability will become apparent from the
description provided herein. It should be understood that the description and
specific examples are intended for purposes of illustration only and are not
intended to limit the scope of the present disclosure.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011] The drawings described herein are for illustration purposes
only and are not intended to limit the scope of the present disclosure in any
way.
[0012] Figure 1 is a functional block diagram illustrating an internal
combustion engine system including direct fuel injection hardware;
[0013] Figure 2 is a dataflow diagram illustrating a fuel injection
system;
[0014] Figure 3 is a flow chart illustrating a method of transitioning
between single injection and dual injection modes; and
[0015] Figure 4 includes timing diagrams illustrating the scheduling
of fuel injection events during a single injection mode, a dual injection mode
and transition therebetween.

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DETAILED DESCRIPTION
[0016] The following description is merely exemplary in nature and
is in no way intended to limit the disclosure, its application, or uses. For
purposes of clarity, the same reference numbers will be used in the drawings
to identify the same elements. As used herein, the term module and/or device
refers to an application specific integrated circuit (ASIC), an electronic circuit,
a processor (shared, dedicated, or group) and memory that execute one or
more software or firmware programs, a combinational logic circuit and/or other
suitable components that provide the described functionality.
[0017] Referring now to Figure 1, an engine system 10 includes an
engine 12 that combusts an air and fuel mixture to produce drive torque. Air
is drawn into an intake manifold 14 through a throttle 16. The throttle 16
regulates mass air flow into the intake manifold 14. Air within the intake
manifold 14 is distributed into cylinders 18. Although a single cylinder 18 is
illustrated, it can be appreciated that the engine can have a plurality of
cylinders including, but not limited to, 2, 3, 4, 5, 6, 8, 10, 12 and 16 cylinders.
[0018] A fuel injector 20 is electronically controlled to inject fuel into
the cylinder 18. Fuel is combined with air as it is drawn into the cylinder 18
through the intake port. An intake valve 22 selectively opens and closes to
enable the air to enter the cylinder 18. The intake valve position is regulated
by an intake camshaft 24. A piston (not shown) compresses the air/fuel
mixture within the cylinder 18. A spark plug 26 initiates combustion of the
air/fuel mixture, driving the piston in the cylinder 18. The piston drives a
crankshaft (not shown) to produce drive torque. Combustion exhaust within
the cylinder 18 is forced out through an exhaust manifold 28 when an exhaust
valve 30 is in an open position. The exhaust valve position is regulated by an
exhaust camshaft 32. The exhaust can then be treated in an exhaust system
(not shown). Although single intake and exhaust valves 22,30 are illustrated,
it can be appreciated that the engine 12 can include multiple intake and
exhaust valves 22,30 per cylinder 18.

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[0019] A crankshaft sensor 34 senses a position of the crankshaft
and generates a crankshaft signal. A control module 36 receives the
crankshaft signal, interprets the signal as degrees of rotation and schedules
fuel injection events based on the interpretation of the signal. The control
module 36 sends a fuel injection signal to the fuel injector to control the
amount and the timing of the fuel delivery. The fuel injection signal can be a
pulse width modulated signal where the pulse width regulates the amount of
fuel delivered to the cylinder.
[0020] Referring now to Figure 2, the present disclosure provides a
control method and system that governs the transitions between single and
dual fuel injection modes. A dataflow diagram illustrates a fuel injection
system that may be embedded within the control module 36. Various
embodiments of fuel injection systems according to the present disclosure
may include any number of sub-modules embedded within the control module
36. The sub-modules shown may be combined and/or further partitioned to
similarly govern the transitions between the single injection mode and the dual
injection mode during engine operation.
[0021] In various embodiments, the control module 36 of Figure 2
includes an injection mode module 50 and a fuel injection command module
52. The injection mode module 50 receives engine and vehicle operating
data 54 as an input. As can be appreciated, the inputs to the injection mode
module 50 may be sensed from the system 10, received from other control
modules (not shown) in the system, or determined from other sub-modules
within the control module 36. Figure 3 provides a flow chart with an
exemplary method of transitioning between single injection and dual injection
modes where vehicle operating data 54 includes coolant temperature, engine
speed and vehicle speed. This exemplary method will be described in greater
detail hereinafter.

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[0022] Based on the operating data 54, the injection mode module
50 selects an injection mode 56 to be one of a single injection mode and a
dual injection mode. The fuel injection command module 52 receives the
injection mode 56 and a crankshaft position 58 as inputs. The fuel injection
command module 52 schedules fuel injection events and provides a fuel
command 60 based on the injection mode 56 and the crankshaft position 58.
[0023] During the dual injection mode, two injection events are
scheduled per cylinder per combustion cycle. This generates a change in
torque without increasing fuel consumption. Fuel injection command module
52 smoothly transitions engine operation between single and dual injection
modes of operation. Torque variations or "bumps" during operating mode
transitions are minimized.
[0024] Referring to Figure 3, the flow chart illustrates an exemplary
method of transitioning between single injection and dual injection modes. In
this example, it may be beneficial to switch from a single injection mode to a
dual injection mode to perform catalytic converter light off. Catalytic converter
light off may be implemented soon after engine start-up to quickly heat up the
catalyst within the catalytic converter to reduce engine emissions. Catalytic
converter light off is an example sub-mode of dual injection operation that
may be determined by injection mode module 50. Once this sub-mode of
operation is entered, control block 66 determines the temperature of the
engine coolant. Decision block 68 determines if the coolant temperature is
less than a predetermined constant K1. K1 may be chosen to represent a
temperature indicative of an engine operating at start up or having run for a
minimal amount of time. If the coolant temperature is greater than or equal to
K1, control returns to control block 66. If the coolant temperature is less than
K1, control block 70 determines the engine operating speed.
[0025] Control block 72 determines if the engine speed is less than
a predetermined constant K2. If the engine is operating at a relatively low
speed near idle, catalytic converter light off may be desirable. If the engine is

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operating at a higher speed, sufficient energy and additional fuel may already
be supplied to the catalytic converter such that additional fuel need not be
provided. Accordingly, if the engine speed is greater than or equal to K2,
control returns to control blqck 66. If the engine speed is less than K2, control
block 74 determines the vehicle speed.
[0026] If the vehicle is in motion above a predetermined speed,
catalytic converter light off may not be desirable because immediate engine
response to a torque request may be desired. As such, decision block 76
determines if the vehicle speed is less than the predetermined constant K3. If
the vehicle speed is greater than or equal to K3, control is returned to control
block 66. If the vehicle speed is less than K3, control block 78 transitions
engine fuel injection from the single injection mode to the dual injection mode.
The specific steps taken during the transition will be described in greater
detail hereinafter.
[0027] Once a transition from the single injection mode to the dual
injection mode has been completed, control block 80 determines the amount
of time that the engine has been operating in the dual injection mode.
Decision block 82 determines if the dual injection mode operating time is
greater than a predetermined constant K4. If the engine has not been
operating within the dual injection mode greater than K4, control returns to
control block 80. If the dual injection mode operating time exceeds K4, control
block 84 calculates an amount of energy added to the catalytic converter by
operation in the dual injection mode.
[0028] Decision block 86 determines if the energy added exceeds a
predetermined threshold of K5. If the energy threshold has not been reached,
control returns to control block 84. If the energy threshold, K5, has been
exceeded, catalytic converter light off has been completed and control block
88 transitions from the dual injection mode to the single injection mode.

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[0029] Referring now to Figure 4, timing diagrams for scheduling
fuel injection events according to the present disclosure are shown. In the
example depicted, control begins in the dual injection mode shown generally
at 100. During the dual injection mode, two injection events are scheduled
per cylinder per combustion cycle. If injection mode module 50 determines
that appropriate conditions exist, control switches to a single injection mode
shown generally at 200.
[0030] Injection mode module 50 may determine through evaluation
of operating data 54 that a dual injection mode should be entered. Examples
relating to special operation regimes where mode switching would be
beneficial include dual injection sub-modes such as the catalytic converter
light off sub-mode previously described as well as idle fuel efficiency increase
sub-mode, an idle stability sub-mode and an engine knock reduction sub-
mode. While these sub-modes will not be described in great detail, it should
be noted that entry and exit from these sub-modes of operation of double
injection may cause torque variations as previously described. As such, the
present disclosure provides an apparatus and a method of minimizing torque
variations during transition between dual injection and single injection modes.
[0031] Fuel injection events can be scheduled according to the
crankshaft position indicated by degrees of crank rotation. A crankshaft signal
can be interpreted as a position in crank degrees. Each diagram illustrates
the position of the crankshaft in crank degrees during intake and compression
cycles. The piston begins an intake stroke at three hundred sixty (360) crank
rotation degrees before top dead center at 110. The piston begins a
compression stroke at one hundred eighty (180) crank rotation degrees before
top dead center (also referred to bottom dead center (BDC)) at 120. The
piston ends the compression stroke at top dead center or zero (0) crank
rotation degrees shown at 130. Firing of spark for both the single injection
mode 200 and the dual injection mode 100 typically occurs near top dead
center of the compression stroke at 140. In the example depicted in Figure 4,

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firing occurs between ten (10) and zero (0) crank degrees before top dead
center. However, as will be described, spark timing may also be varied to
provide a smooth transition between single and dual injection modes.
[0032] As mentioned, the dual injection mode 100 provides two fuel
injection events per cylinder per intake and compression cycle. The first
injection event is scheduled early in the intake cycle and can be scheduled
anywhere between two hundred fifty (250) and three hundred eighty (380)
crank degrees before top dead center. An exemplary range for scheduling
the first fuel delivery is between two hundred and seventy (270) and three
hundred and thirty (330) crank degrees before top dead center as shown at
160.
[0033] The second fuel injection event is scheduled in one of the
intake and compression cycles and can be scheduled anywhere between zero
(0) and three hundred sixty (360) crank degrees before top dead center. An
exemplary range for scheduling the second fuel delivery is between one
hundred twenty (120) and two hundred seventy (270) crank degrees before
top dead center as shown at 170. The second injection event injects the
remainder of fuel necessary for the combustion cycle.
[0034] If an injection mode change is requested, the injection mode
is transitioned over time to the single injection mode 200 where a single
injection event is scheduled early in the intake cycle. The injection event is
scheduled early and can be scheduled anywhere between two hundred fifty
(250) and three hundred eighty (380) crank degrees before top dead center.
An exemplary range for scheduling the fuel delivery is between two hundred
and seventy (270) and three hundred and thirty (330) crank degrees before
top dead center as shown at 180. The single injection mode 200 delivers
more or less torque than dual injection for the same conditions but allows for
spark timing to be near minimum best torque (MBT) or knock border limit
(KBL) to improve efficiency.

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[0035] Figure 4 includes additional timing diagrams depicting
injection pulse timing during the transition between dual injection mode 100
and single injection mode 200. In particular, timing diagram 210 shows the
start of transition from dual injection mode 100 to single injection mode 200.
Within the first step of the transition at timing diagram 210, the first fuel
delivery 160 is performed at the same or similar time as previously described
in reference to dual injection mode 100 while a second fuel injection event is
scheduled ten degrees advanced from the prior second injection as shown at
220. Timing diagram 230 represents the next intake and compression strokes
for a given cylinder where the first injection event schedule remains constant
while the second injection event has been advanced another ten crank
degrees as shown at 240. Timing diagrams 250 and 270 depict second
injection events 260 and 280, respectively. Second injection event 260
occurs at ten crank degrees advanced relative to second injection event 240.
Second injection event 280 occurs ten degrees advanced relative to second
injection event 260. After timing diagram 270 has been implemented, control
switches to single injection mode 200. To transition from single injection
mode 200 to dual injection mode 100, the previously described method is
reversed.
[0036] As mentioned earlier, spark delivery timing may also be
varied during injection mode switching. Spark timing modification is based on
the sub-mode of dual injection. In the idle fuel efficiency increase sub-mode,
spark timing is typically near MBT in the dual injection mode. During
transition from the dual injection to the single injection mode, spark timing is
retarded by about five to ten degrees so that torque fluctuations are
minimized. Spark advance is lag filtered toward MBT during transitions from
the single injection to the dual injection mode.

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[0037] Idle stability and catalytic converter light off sub-modes
typically include retarding spark timing to after top dead center during the dual
injection mode. When transitioning from the dual injection mode to the single
injection mode, spark timing is advanced toward the single injection target
spark timing at a rate of about two degrees per cylinder combustion event.
This process is reversed during transition from the single injection to the dual
injection mode.
[0038] The engine knock reduction sub-mode is entered to ensure
absence of engine knock. The dual injection mode is entered to achieve this
goal. During transition from the single injection to the dual injection mode,
spark timing is lag filtered toward a dual injection spark timing target. The
target spark timing is less retarded than possible to assure engine knock
reduction.
[0039] It should be appreciated that transition between the single
injection mode and the dual injection mode may be accomplished solely via
adjustment of the second injection event timing as depicted in Figure 4 or may
also include in combination modifying the spark timing during the transition.
In addition, those skilled in the art can now appreciate from the foregoing
description that the broad teachings of the present disclosure can be
implemented in a variety of forms. Therefore, while this disclosure has been
described in connection with particular examples thereof, the true scope of the
disclosure should not be so limited since other modifications will become
apparent to the skilled practitioner upon a study of the drawings, the
specification and the following claims.

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CLAIMS
What is claimed is:
1. A fuel injection system for a direct fuel injection engine,
comprising:
an injection mode module that selects a fuel injection mode to
be one of a single injection mode and a dual injection mode during engine
operation; and
a fuel injection command module that receives crankshaft
position and that transitions between the single and dual injection modes by
varying timing of fuel injection events during said transition based on said
crankshaft position.
2. The system of claim 1 wherein the fuel injection command
module commands a first fuel injection event when the crankshaft position is
within a first predetermined angle range and a second fuel injection event
when the crankshaft is within a second predetermined angle range during the
dual injection mode and wherein the fuel injection mode module commands
the second fuel injection event to occur at incrementally advanced crankshaft
positions during said transition between the single and dual injection modes.
3. The system of claim 2 wherein the timing of the first fuel
injection event remains constant during the transition between the single and
dual injection modes.
4. The system of claim 3 wherein the timing of the second fuel
injection event is advanced approximately ten degrees every subsequent
combustion event.

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5. The system of claim 1 further including varying spark timing
during transitions between the single and dual injection modes.
6. The system of claim 5 wherein the spark timing is varied when
transitioning from one of an idle fuel efficiency increase mode, an idle stability
mode, a catalytic converter light off mode and an engine knock reduction
mode.
7. The system of claim 6 wherein the catalytic converter light off
mode includes retarding spark timing to after top dead center in the dual
injection mode and advancing spark timing at a rate of substantially two
degrees per cylinder per combustion event until a target single injection mode
spark timing is met.
8. The system of claim 6 wherein the engine knock reduction mode
includes transitioning into the dual injection mode.
9. The system of claim 8 wherein varying the spark timing during a
transition from the single injection mode to the dual injection mode includes
retarding the spark timing.
10. A fuel injection method for a direct fuel injection engine, comprising:
operating the engine in a single injection mode;
commanding fuel delivery at a first crankshaft position;
receiving a request to transition from a single injection mode to a dual
injection mode; and
transitioning to the dual injection mode by commanding fuel delivery at
a second crankshaft position and at a third crankshaft position wherein the third
crankshaft position is changed incrementally during subsequent combustion cycles
until a target third crankshaft position is reached.

14
11. The method of claim 10 wherein the commanding fuel delivery
at a first crankshaft position further includes commanding fuel delivery when
the crankshaft position is within a first predetermined range during an intake
cycle of an engine cylinder.
12. The method of claim 11 wherein the commanding fuel delivery
at a second crankshaft position and at a third crankshaft position further
includes commanding fuel delivery at the second crankshaft position when the
crankshaft position is within a second predetermined range and commanding
fuel delivery at the third crankshaft position when the crankshaft position is
within a third predetermined range during intake and compression cycles of
the engine cylinder.
13. The method of claim 12 wherein the second predetermined
range is substantially the first predetermined range.
14. The method of claim 10 wherein the third crankshaft position is
retarded at a rate of ten degrees per cylinder combustion event until the target
third crankshaft position is reached.
15. The method of claim 14 wherein the third crankshaft position is
varied between 120 and 270 degrees of crankshaft rotation before top dead
center.
16. The method of claim 10 further including receiving a request to
transition from the dual injection mode to a single injection mode and
transitioning to the single injection mode by commanding fuel delivery at the
third crankshaft position to be advanced at a predetermined rate during
subsequent combustion cycles.

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17. The method of claim 10 wherein transitioning to the dual
injection mode includes commanding spark delivery at a first spark timing
position and varying spark timing per subsequent combustion cycles until
spark is delivered at a second spark timing position.
18. The method of claim 17 further including anticipating a sub-
mode of dual injection operation to be entered and setting the first spark
timing position based on the anticipated sub-mode.
19. The method of claim 18 wherein the sub-modes include idle fuel
efficiency increase, idle stability, catalytic converter light off and engine knock
reduction.
20. The method of claim 19 wherein the first spark timing position is
set to a value ranging from five to ten degrees retarded from a maximum
brake torque value and wherein the second spark timing position is near the
maximum brake torque value when transitioning to the idle fuel efficiency
increase sub-mode.
21. The method of claim 19 wherein transitioning to one of the idle
stability and the catalytic converter light off sub-modes includes setting the
second spark timing position to occur after top dead center.
22. The method of claim 19 wherein transition to the engine knock
reduction sub-mode includes setting the second spark timing position at a
value retarded relative to the first spark timing position.

A fuel injection system for a direct fuel injection engine includes an
injection mode module. The injection mode module selects a fuel injection
mode to be one of a single injection mode and a dual injection mode. A fuel
injection command module transitions between the single and dual injection
modes by varying the timing of fuel injection events relative to a crankshaft
position.

Documents:

00222-kol-2008-abstract.pdf

00222-kol-2008-claims.pdf

00222-kol-2008-correspondence others.pdf

00222-kol-2008-description complete.pdf

00222-kol-2008-drawings.pdf

00222-kol-2008-form 1.pdf

00222-kol-2008-form 2.pdf

00222-kol-2008-form 3.pdf

00222-kol-2008-form 5.pdf

222-KOL-2008-(16-05-2013)-ANNEXURE TO FORM 3.pdf

222-KOL-2008-(16-05-2013)-CLAIMS.pdf

222-KOL-2008-(16-05-2013)-CORRESPONDENCE.pdf

222-KOL-2008-(16-05-2013)-DESCRIPTION (COMPLETE).pdf

222-KOL-2008-(16-05-2013)-DRAWINGS.pdf

222-KOL-2008-(16-05-2013)-FORM-1.pdf

222-KOL-2008-(16-05-2013)-FORM-2.pdf

222-KOL-2008-(16-05-2013)-OTHERS.pdf

222-KOL-2008-(16-05-2013)-PA.pdf

222-KOL-2008-(19-02-2014)-PETITION UNDER RULE 137.pdf

222-KOL-2008-ASSIGNMENT.pdf

222-KOL-2008-CORRESPONDENCE OTHERS 1.1.pdf

222-kol-2008-form 18.pdf

222-KOL-2008-PRIORITY DOCUMENT.pdf

abstract-00222-kol-2008.jpg


Patent Number 263324
Indian Patent Application Number 222/KOL/2008
PG Journal Number 43/2014
Publication Date 24-Oct-2014
Grant Date 20-Oct-2014
Date of Filing 07-Feb-2008
Name of Patentee GM GLOBAL TECHNOLOGY OPERATIONS, INC.
Applicant Address 300 GM RENAISSANCE CENTER DETROIT, MICHIGAN
Inventors:
# Inventor's Name Inventor's Address
1 JONATHAN T. SHIBATA 613 ALLEN ROAD MILAN, MICHIGAN 48160
2 STUART R. SMITH 9251 BERGIN ROAD HOWELL, MICHIGAN 48843
3 MICHAEL J. LUCIDO 42372 COSTWOLD COURT NORTHVILLE, MICHIGAN 48168
4 VIJAY RAMAPPAN 24935 PORTSMOUTH AVENUE NOVI MICHIGAN 48374
5 JESSE M. GWIDT 7791 FULLER STREET BRIGHTON, MICHIGAN 48116
PCT International Classification Number F02D41/04; F02D41/08; F02D41/30
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 11/676,561 2007-02-20 U.S.A.