Title of Invention	" AN OIL LIFE MONITORING SYSTEM AND A METHOD TO MONITOR OIL LIFE OF AN ENGINE"
Abstract	TITLE : "AN OIL LIFE MONITORING SYSTEM AND A METHOD TO MONITOR OIL LIFE OF AN ENGINE" This invention relates to an oil life monitoring system for a diesel engine system (10), characterized by comprising a viscosity loss module (104) that determines a percentage of viscosity loss (VL%) of engine oil based on a post-combustion injection quantity and a post-combustion injection time, a viscosity gain module that determines a percentage of viscosity gain VG% of engine oil based on at least one of fuel evaporation and soot accumulation in said engine oil; and a remaining oil life module (108) that communicates with said viscosity loss module (104) and said viscosity gain module (106) and that determines a percentage of oil life remaining (PLOR) based on at least one of said percentage of viscosity loss (VL%) and said percentage of viscosity gain (VG%). {FIGURE - 1}

Title of Invention

" AN OIL LIFE MONITORING SYSTEM AND A METHOD TO MONITOR OIL LIFE OF AN ENGINE"

Abstract

TITLE : "AN OIL LIFE MONITORING SYSTEM AND A METHOD TO MONITOR OIL LIFE OF AN ENGINE" This invention relates to an oil life monitoring system for a diesel engine system (10), characterized by comprising a viscosity loss module (104) that determines a percentage of viscosity loss (VL%) of engine oil based on a post-combustion injection quantity and a post-combustion injection time, a viscosity gain module that determines a percentage of viscosity gain VG% of engine oil based on at least one of fuel evaporation and soot accumulation in said engine oil; and a remaining oil life module (108) that communicates with said viscosity loss module (104) and said viscosity gain module (106) and that determines a percentage of oil life remaining (PLOR) based on at least one of said percentage of viscosity loss (VL%) and said percentage of viscosity gain (VG%). {FIGURE - 1}

Full Text	FIELD OF THE INVENTION The present invention relates to diesel engines, and more particularly to monitoring an oil life of diesel engines that use post injection regeneration of diesel particulate filters. BACKGROUND OF THE INVENTION Diesel engines have many moving parts that require lubrication. Engine durability is directly related to the ability of engine oil to lubricate the moving parts. However, the lubricating ability of the engine oil becomes degraded over time. Therefore, most manufacturers provide engine oil maintenance schedules to determine when the engine oil should be changed. The maintenance schedules are typically based on mileage although engine operating conditions directly relate to the degradation of engine oil. Thus, it is desirable to determine when the engine oil should be changed based on operating conditions of the engine. In one method the degradation of engine oil is determined from monitoring engine revolutions, engine oil temperature, and soot accumulation in engine oil. However, during regeneration of a diesel particulate filter using a post injection strategy, fuel is accumulated in the engine oil. The accumulation of fuel degrades the ability of the engine oil to properly lubricate the engine. Therefore, it is desirable to determine when the engine oil should be changed due to the accumulation of fuel in the engine oil. SUMMARY OF THE INVENTION An oil life monitoring system for a diesel engine system according to the present invention includes a viscosity loss module, a viscosity gain module, and a remaining oil life module. The viscosity loss module determines a percentage of viscosity loss of engine oil based on fuel accumulation in the engine oil. The viscosity gain module determines a percentage of viscosity gain of engine oil based on fuel evaporation and/or soot accumulation in the engine oil. The remaining oil life module communicates with the viscosity loss module and the viscosity gain module and determines a percentage of oil life remaining based on the percentage of viscosity loss and/or the percentage of viscosity gain. {0005] In other features of the invention, viscosity loss due to fuel accumulation in the engine oil, which occurs when the diesel engine system is regenerating a diesel particulate filter, is modeled. The viscosity loss module determines the percentage of viscosity loss based on a rate of viscosity loss. The rate of viscosity loss is based on a viscosity loss factor. The viscosity loss factor is based on an engine speed, an engine torque, a post injection fuel quantity, and a post injection time. In still other features, viscosity gain due to fuel evaporation and/or soot accumulation, which occurs in engine oil when the diesel engine system is not regenerating a diesel particulate filter, is modeled. The viscosity gain module determines the percentage of viscosity gain based on a rate of viscosity gain. The rate of viscosity gain is based on a viscosity gain due to soot in engine oil and a viscosity gain due to engine oil temperature. In yet other features, the remaining oil life module stores the percentage of oil life remaining in memory. If the percentage of oil life remaining is decreasing, the remaining oil life module displays the percentage of oil life remaining. Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein: Figure 1 is an exemplary diesel engine system that uses post- combustion injection to regenerate a diesel particulate filter; Figure 2 is a functional block diagram of an oil life monitoring system according to the present invention; and Figure 3 is a flowchart illustrating exemplary steps taken by the oil life monitoring system of the present invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses. For purposes of clarity, the same reference numbers will be used in the drawings to identify similar elements. As used herein, the term module 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. Referring now to Figure 1, an exemplary diesel engine system 10 is illustrated. The diesel engine system 10 includes a diesel engine 12, an intake manifold 14, a fuel injection system 16, and an exhaust system 18. The exemplary engine 12 includes six cylinders 20 configured in adjacent cylinder banks 22,24 in V-type layout. Although Figure 1 depicts six cylinders (N = 6), it can be appreciated that the engine 12 may include additional or fewer cylinders 20. For example, engines having 2, 4, 5, 8, 10, 12 and 16 cylinders are contemplated. Air is drawn into the cylinders 20 from the intake manifold 14 and is compressed therein. Fuel is injected into the cylinders 20 by the fuel injection system 16 and the heat of the compressed air ignites the air/fuel mixture. The exhaust gases are exhausted from the cylinders 20 and into the exhaust system 18. In some instances, the diesel engine system 10 can include a turbocharger 26 or a supercharger (not shown) that pumps additional air into the cylinders 20 for combustion with the fuel and air drawn in from the intake manifold 14. The exhaust system 18 includes exhaust manifolds 28,30, exhaust conduits 29,31, a catalyst 38, and a diesel particulate filter (DPF) 40. First and second exhaust segments are defined by the first and second cylinder banks 22,24. The exhaust manifolds 28,30 direct the exhaust segments from the corresponding cylinder banks 22,24 into the exhaust conduits 29,31. The exhaust is then typically directed to drive the turbocharger 26. A combined exhaust stream flows from the turbocharger 26 through the catalyst 38 and the DPF 40. The DPF 40 filters particulates from the combined exhaust stream as it flows to the atmosphere. A controller 42 that has memory 43 regulates operation of the diesel engine system 10 including DPF regeneration and an oil life monitoring system according to the present invention. More particularly, the controller 42 communicates with an intake manifold absolute pressure (MAP) sensor 44, an engine speed sensor 46, and an oil temperature sensor 47. The MAP sensor 44 generates a signal indicating the air pressure within the intake manifold 14. The engine speed sensor 46 generates a signal indicating engine speed (RPM). The oil temperature sensor 47 generates a temperature signal indicating temperature of the engine oil. Alternatively, a mathematical model may be used to generate the temperature signal. The controller 42 may determine an engine torque based on operating conditions of the diesel engine 12. The controller 42 periodically estimates the amount of emitted particulates since the last DPF regeneration based on engine operating parameters. When the DPF 40 is deemed full of particulates, the controller 42 generates a regeneration signal and initiates DPF regeneration. During DPF regeneration, the controller 42 controls the fuel injection system 16 to inject fuel into the first and second cylinder banks 22, 24 at a calibrated time after combustion (i.e., post-combustion injection). Post-combustion injected fuel is expelled from the cylinders with the exhaust gas and is oxidized in the catalyst - 38. Heat released during oxidation increases the exhaust gas temperature, which burns trapped soot particulates in the DPF 40. The post-combustion injected fuel may accumulate in engine oil degrading the ability of the engine oil to lubricate the diesel engine system 10. Accordingly, the present invention monitors engine oil life based on the accumulation of fuel. The engine oil life may be displayed as a percent of remaining life on an oil life indicator 48. Referring now to Figure 2, an oil life monitoring system 100 includes a viscosity loss module 104, a viscosity gain module 106, and a remaining life module 108. When the controller 42 initiates DPF regeneration a regeneration flag 107 is set in memory 43. When the diesel engine system 10 is regenerating the DPF 40, the viscosity loss module 104 determines a viscosity loss factor based on engine speed, engine torque, post injection fuel quantity, and post injection timing. The viscosity loss factor may be determined with the following equation: where VLF is the viscosity loss factor, Es is the engine speed, Er is the engine torque Q1 is a injection fuel quantity, Q2 is a second post injection fuel quantity, T1 is a first post injection timing, T2 is a second post injection timing, and C1 - C7 are constants that are experimentally determined. Once the viscosity loss factor has been determined, the viscosity loss module 104 determines a viscosity loss rate. The viscosity loss rate represents viscosity loss per hour and may be determined from an experimentally determined lookup table. The viscosity loss module 104 determines a percent viscosity loss based on the viscosity loss rate. The percent viscosity loss is independent of time and may be determined with the following equation: where VL% is the percent viscosity loss, VLR is the viscosity loss rate, and t is a time that the diesel engine 12 has been operating according to the current operating conditions. For example, if the diesel engine 12 has been operating at 2000 RPM for 20 seconds, t would equal 20 seconds. The remaining oil life module 108 uses the percent viscosity loss to determine a percent oil life remaining (POLR). More specifically, the remaining oil life module 108 retrieves a previously determined POLR from memory 43 and subtracts the percent viscosity loss to determine the POLR. The following equation may be used to determine the POLR: where POLR is the percent oil life remaining, POLROLD is the previously determined POLR, and VL% is the percent viscosity loss. The POLR is stored in memory 43 as POLROLD 109 and is used to calculate the POLR during the next cycle. [0025] When regeneration of the DPF 40 is not occurring, the viscosity gain module 106 determines a viscosity gain due to soot accumulation in the engine oil and a viscosity gain due to oil temperature related fuel evaporation. Both the viscosity gain due to soot and viscosity gain due to temperature may be determined with a respective lookup table that is experimentally determined. Once the viscosity gains due to soot and oil temperature have been determined, the viscosity gain module 106 determines a viscosity gain rate. The viscosity gain rate may be determined with the following equation: where VGR is the viscosity gain rate, VGs is the viscosity gain due to soot accumulation in the engine oil, and VGT is the viscosity gain due to engine oil temperature. The viscosity gain module 106 determines a percent viscosity gain that is independent of time based on the viscosity gain rate. The percent viscosity gain may be determined with the following equation: where VG% is the percent viscosity gain, VGR is the viscosity gain rate, and t is a time that the diesel engine 12 has been operating according to the current operating conditions. The remaining oil life module 108 uses the percent viscosity gain to determine the POLR. More specifically, the remaining life oil module 108 retrieves the previously determined POLR from memory 43 and adds the percent viscosity gain to determine the POLR. The following equation may be used to determine the POLR when the viscosity is increasing due to fuel evaporation: where POLR is the percent oil life remaining, POLROLD is the previously determined POLR, and VG% is the percent viscosity gain. The POLR is stored in memory 43 as POLROLD 109 and is used to calculate the POLR during the next cycle. However, the POLR is only displayed on the oil life indicator 48 when POLR is less than POLROLD 109 to prevent a driver from observing an increase in the POLR. Referring now to Figure 3, the oil life monitoring system 100 implements steps generally identified at 200. The process starts in step 202 when the diesel engine system 10 is started. In step 204, control determines whether the diesel engine system 10 is regenerating the DPF 40. If the diesel engine system 10 is regenerating the DPF 40, the viscosity loss module 104 determines the viscosity loss factor in step 206. As previously discussed, the viscosity loss factor is based on engine speed, engine torque, post injection fuel quantity, and post injection timing. In step 208, the viscosity loss module 104 determines the viscosity loss rate based on the viscosity loss factor. As previously discussed, the viscosity loss rate represents viscosity loss per hour. In step 210, the viscosity loss module 104 determines the percent viscosity loss, which is independent of time, based on the viscosity loss rate. The remaining oil life module 108 determines the POLR based on the percent viscosity loss in step 212. More specifically, the remaining oil life module 108 subtracts the percent viscosity loss from the POLR calculated during the last iteration. If the diesel engine system 10 is not regenerating the DPF 40, the viscosity gain module 106 determines the viscosity gain due to soot accumulation in the engine oil in step 214. In step 216, the viscosity gain module 106 determines the viscosity gain due to engine oil temperature. The viscosity gain module 106 determines the rate of viscosity gain based on the viscosity gain due to soot accumulation in the engine oil and the viscosity gain due to engine oil temperature in step 218. As previously discussed, the viscosity gain represents viscosity gain per hour. In step 220, the viscosity gain module 106 determines the percent viscosity gain, which is independent of time, based on the viscosity gain rate. The remaining oil life module 108 determines the POLR based on the percent viscosity gain in step 212. More specifically, the remaining oil life module 108 adds the percent viscosity gain to the POLROLD 109, which is calculated during the last iteration. The remaining oil life module 108 stores the POLR as POLROLD 109 in memory 43 for the next iteration in step 222. In step 224, the remaining oil life module 108 compares the POLR to POLROLD 109. If the POLR is less than the POLROLD 109, the POLR is displayed on the oil life indicator 48 in step 226. If the POLR is not less than the POLROLD 109, the POLROLD 109 is displayed on the oil life indicator 48 in step 228. The process ends in step 230. Those skilled in the art can now appreciate from the foregoing description that the broad teachings of the present invention can be implemented in a variety of forms. Therefore, while this invention has been described, in connection with particular examples thereof, the true scope of the invention 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. WE CLAIM 1. An oil life monitoring system for a diesel engine system (10), characterized by comprising: a viscosity loss module (104) that determines a percentage of viscosity loss (VL%) of engine oil based on a post-combustion injection quantity and a post-combustion injection time, a viscosity gain module that determines a percentage of viscosity gain VG% of engine oil based on at least one of fuel evaporation and soot accumulation in said engine oil; and a remaining oil life module (108) that communicates with said viscosity loss module (104) and said viscosity gain module (106) and that determines a percentage of oil life remaining (PLOR) based on at least one of said percentage of viscosity loss (VL%) and said percentage of viscosity gain (VG%). 2. The oil life monitoring system as claimed in claim 1, wherein said viscosity loss (VL%) occurs due to fuel accumulation caused by said post- 4 combustion when the diesel engine system is regenerating a diesel particulate filter. 3. The oil life monitoring system as claimed in claim 2, wherein said percentage of viscosity loss (VL%) is based on a rate of viscosity loss (VLR). 4. The oil life monitoring system as claimed in claim 3, wherein said rate of viscosity loss (VL%) is based on a viscosity loss factor (VLf). 5. The oil life monitoring system as claimed in claim 4, wherein said viscosity loss factor (VLF) is based on an engine speed, and an engine torque. 6. The oil life monitoring system as claimed in claim 1, wherein said viscosity gain (VGs, VGT) occurs when the diesel engine system (10) is not regenerating a diesel particulate filter. 7. The oil life monitoring system as claimed in claim 6, wherein said percentage of viscosity gain (VG%) is based on a rate of viscosity gain (VGR). 8. The oil life monitoring system as claimed in claim 7, wherein said rate of viscosity gain (VGR) is based on a viscosity gain (VGs) due to soot in engine oil and a viscosity gain (VGT) due to engine oil temperature. 9. The oil life monitoring system as claimed in claim 1, wherein said percentage of oil life remaining (POLR) is stored in memory (43). 10.The oil life monitoring system as claimed in claim 1, wherein said remaining life oil module (108) displays said percentage of oil life remaining (POLR) when said percentage of oil life remaining (POLR) is decreasing. 11. A method to monitor oil life of a diesel engine system, comprising: determining (206) a percentage of viscosity loss (VL%) of engine oil based on a post-combustion injection quantity and a post-combustion injection time; determining (214) a percentage of viscosity gain (VG%) of engine oil based on at least one of fuel evaporation and soot accumulation in said engine oil; and determining (226,228) a percentage of oil life remaining based on at least one of said percentage of viscosity loss (VL%) and said percentage of viscosity gain (VG%). 12.The method as claimed in claim 11, wherein said viscosity loss occurs due to fuel accumulation caused by said post-combustion injection quantity and said post-combustion injection time when the diesel engine system is regenerating a diesel particulate filter. 13.The method as claimed in claim 12, comprising determining (210) said percentage of viscosity loss (VL%) based on a rate of viscosity loss. 14.The method as claimed in claim 13, comprising determining (208) said rate of viscosity loss based on a viscosity loss factor (VLR). 15.The method as claimed in claim 14, comprising determining said viscosity loss factor based on an engine speed, an engine torque, a post injection fuel quantity, and a post injection time. 16.The method as claimed in claim 11, wherein said viscosity gain occurs when the diesel engine system is not regenerating a diesel particulate filter. 17.The method as claimed in claim 16, comprising determining (214,216) said percentage of viscosity gain based on a rate of viscosity gain. 18.The method as claimed in claim 17, comprising determining (218) said rate of viscosity gain based on a viscosity gain based on a rte of viscosity gain. 19.The method as claimed in claim 11, comprising storing (222) said percentage of oil life remaining in a memory (43). 20.The method as claimed in claim 11, comprising displaying (228) said percentage of oil life remaining when said percentage of oil life remaining is decreasing. ABSTRACT TITLE : "AN OIL LIFE MONITORING SYSTEM AND A METHOD TO MONITOR OIL LIFE OF AN ENGINE" This invention relates to an oil life monitoring system for a diesel engine system (10), characterized by comprising a viscosity loss module (104) that determines a percentage of viscosity loss (VL%) of engine oil based on a post-combustion injection quantity and a post-combustion injection time, a viscosity gain module that determines a percentage of viscosity gain VG% of engine oil based on at least one of fuel evaporation and soot accumulation in said engine oil; and a remaining oil life module (108) that communicates with said viscosity loss module (104) and said viscosity gain module (106) and that determines a percentage of oil life remaining (PLOR) based on at least one of said percentage of viscosity loss (VL%) and said percentage of viscosity gain (VG%). {FIGURE - 1}

Full Text

FIELD OF THE INVENTION The present invention relates to diesel engines, and more
particularly to monitoring an oil life of diesel engines that use post injection
regeneration of diesel particulate filters.
BACKGROUND OF THE INVENTION
Diesel engines have many moving parts that require lubrication.
Engine durability is directly related to the ability of engine oil to lubricate the
moving parts. However, the lubricating ability of the engine oil becomes
degraded over time. Therefore, most manufacturers provide engine oil
maintenance schedules to determine when the engine oil should be changed.
The maintenance schedules are typically based on mileage although engine
operating conditions directly relate to the degradation of engine oil. Thus, it is
desirable to determine when the engine oil should be changed based on
operating conditions of the engine.
In one method the degradation of engine oil is determined from
monitoring engine revolutions, engine oil temperature, and soot accumulation in
engine oil. However, during regeneration of a diesel particulate filter using a post
injection strategy, fuel is accumulated in the engine oil. The accumulation of fuel
degrades the ability of the engine oil to properly lubricate the engine. Therefore,

it is desirable to determine when the engine oil should be changed due to the
accumulation of fuel in the engine oil.
SUMMARY OF THE INVENTION
An oil life monitoring system for a diesel engine system
according to the present invention includes a viscosity loss module, a viscosity
gain module, and a remaining oil life module. The viscosity loss module
determines a percentage of viscosity loss of engine oil based on fuel
accumulation in the engine oil. The viscosity gain module determines a
percentage of viscosity gain of engine oil based on fuel evaporation and/or soot
accumulation in the engine oil. The remaining oil life module communicates with
the viscosity loss module and the viscosity gain module and determines a
percentage of oil life remaining based on the percentage of viscosity loss and/or
the percentage of viscosity gain.
{0005] In other features of the invention, viscosity loss due to fuel
accumulation in the engine oil, which occurs when the diesel engine system is
regenerating a diesel particulate filter, is modeled. The viscosity loss module
determines the percentage of viscosity loss based on a rate of viscosity loss.
The rate of viscosity loss is based on a viscosity loss factor. The viscosity loss
factor is based on an engine speed, an engine torque, a post injection fuel
quantity, and a post injection time.
In still other features, viscosity gain due to fuel evaporation
and/or soot accumulation, which occurs in engine oil when the diesel engine

system is not regenerating a diesel particulate filter, is modeled. The viscosity
gain module determines the percentage of viscosity gain based on a rate of
viscosity gain. The rate of viscosity gain is based on a viscosity gain due to soot
in engine oil and a viscosity gain due to engine oil temperature.
In yet other features, the remaining oil life module stores the
percentage of oil life remaining in memory. If the percentage of oil life remaining
is decreasing, the remaining oil life module displays the percentage of oil life
remaining.
Further areas of applicability of the present invention will
become apparent from the detailed description provided hereinafter. It should be
understood that the detailed description and specific examples, while indicating
the preferred embodiment of the invention, are intended for purposes of
illustration only and are not intended to limit the scope of the invention.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS

The present invention will become more fully understood from
the detailed description and the accompanying drawings, wherein:
Figure 1 is an exemplary diesel engine system that uses post-
combustion injection to regenerate a diesel particulate filter;
Figure 2 is a functional block diagram of an oil life monitoring
system according to the present invention; and
Figure 3 is a flowchart illustrating exemplary steps taken by the
oil life monitoring system of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following description of the preferred embodiment(s) is
merely exemplary in nature and is in no way intended to limit the invention, its
application, or uses. For purposes of clarity, the same reference numbers will be
used in the drawings to identify similar elements. As used herein, the term
module 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.
Referring now to Figure 1, an exemplary diesel engine system
10 is illustrated. The diesel engine system 10 includes a diesel engine 12, an
intake manifold 14, a fuel injection system 16, and an exhaust system 18. The
exemplary engine 12 includes six cylinders 20 configured in adjacent cylinder
banks 22,24 in V-type layout. Although Figure 1 depicts six cylinders (N = 6), it
can be appreciated that the engine 12 may include additional or fewer cylinders
20. For example, engines having 2, 4, 5, 8, 10, 12 and 16 cylinders are
contemplated.
Air is drawn into the cylinders 20 from the intake manifold 14
and is compressed therein. Fuel is injected into the cylinders 20 by the fuel
injection system 16 and the heat of the compressed air ignites the air/fuel
mixture. The exhaust gases are exhausted from the cylinders 20 and into the
exhaust system 18. In some instances, the diesel engine system 10 can include

a turbocharger 26 or a supercharger (not shown) that pumps additional air into
the cylinders 20 for combustion with the fuel and air drawn in from the intake
manifold 14.
The exhaust system 18 includes exhaust manifolds 28,30,
exhaust conduits 29,31, a catalyst 38, and a diesel particulate filter (DPF) 40.
First and second exhaust segments are defined by the first and second cylinder
banks 22,24. The exhaust manifolds 28,30 direct the exhaust segments from the
corresponding cylinder banks 22,24 into the exhaust conduits 29,31. The
exhaust is then typically directed to drive the turbocharger 26. A combined
exhaust stream flows from the turbocharger 26 through the catalyst 38 and the
DPF 40. The DPF 40 filters particulates from the combined exhaust stream as it
flows to the atmosphere.
A controller 42 that has memory 43 regulates operation of the
diesel engine system 10 including DPF regeneration and an oil life monitoring
system according to the present invention. More particularly, the controller 42
communicates with an intake manifold absolute pressure (MAP) sensor 44, an
engine speed sensor 46, and an oil temperature sensor 47. The MAP sensor 44
generates a signal indicating the air pressure within the intake manifold 14. The
engine speed sensor 46 generates a signal indicating engine speed (RPM). The
oil temperature sensor 47 generates a temperature signal indicating temperature
of the engine oil. Alternatively, a mathematical model may be used to generate
the temperature signal. The controller 42 may determine an engine torque based
on operating conditions of the diesel engine 12.

The controller 42 periodically estimates the amount of emitted
particulates since the last DPF regeneration based on engine operating
parameters. When the DPF 40 is deemed full of particulates, the controller 42
generates a regeneration signal and initiates DPF regeneration. During DPF
regeneration, the controller 42 controls the fuel injection system 16 to inject fuel
into the first and second cylinder banks 22, 24 at a calibrated time after
combustion (i.e., post-combustion injection). Post-combustion injected fuel is
expelled from the cylinders with the exhaust gas and is oxidized in the catalyst
- 38. Heat released during oxidation increases the exhaust gas temperature,
which burns trapped soot particulates in the DPF 40.
The post-combustion injected fuel may accumulate in engine oil
degrading the ability of the engine oil to lubricate the diesel engine system 10.
Accordingly, the present invention monitors engine oil life based on the
accumulation of fuel. The engine oil life may be displayed as a percent of
remaining life on an oil life indicator 48.
Referring now to Figure 2, an oil life monitoring system 100
includes a viscosity loss module 104, a viscosity gain module 106, and a
remaining life module 108. When the controller 42 initiates DPF regeneration a
regeneration flag 107 is set in memory 43.
When the diesel engine system 10 is regenerating the DPF 40,
the viscosity loss module 104 determines a viscosity loss factor based on engine
speed, engine torque, post injection fuel quantity, and post injection timing. The
viscosity loss factor may be determined with the following equation:

where VLF is the viscosity loss factor, Es is the engine speed, Er is the engine
torque Q1 is a injection fuel quantity, Q2 is a second post injection fuel
quantity, T1 is a first post injection timing, T2 is a second post injection timing, and
C1 - C7 are constants that are experimentally determined.
Once the viscosity loss factor has been determined, the
viscosity loss module 104 determines a viscosity loss rate. The viscosity loss
rate represents viscosity loss per hour and may be determined from an
experimentally determined lookup table.
The viscosity loss module 104 determines a percent viscosity
loss based on the viscosity loss rate. The percent viscosity loss is independent
of time and may be determined with the following equation:

where VL% is the percent viscosity loss, VLR is the viscosity loss rate, and t is a
time that the diesel engine 12 has been operating according to the current
operating conditions. For example, if the diesel engine 12 has been operating at
2000 RPM for 20 seconds, t would equal 20 seconds.
The remaining oil life module 108 uses the percent viscosity
loss to determine a percent oil life remaining (POLR). More specifically, the
remaining oil life module 108 retrieves a previously determined POLR from
memory 43 and subtracts the percent viscosity loss to determine the POLR. The
following equation may be used to determine the POLR:

where POLR is the percent oil life remaining, POLROLD is the previously
determined POLR, and VL% is the percent viscosity loss. The POLR is stored in
memory 43 as POLROLD 109 and is used to calculate the POLR during the next
cycle.
[0025] When regeneration of the DPF 40 is not occurring, the viscosity
gain module 106 determines a viscosity gain due to soot accumulation in the
engine oil and a viscosity gain due to oil temperature related fuel evaporation.
Both the viscosity gain due to soot and viscosity gain due to temperature may be
determined with a respective lookup table that is experimentally determined.
Once the viscosity gains due to soot and oil temperature have
been determined, the viscosity gain module 106 determines a viscosity gain rate.
The viscosity gain rate may be determined with the following equation:

where VGR is the viscosity gain rate, VGs is the viscosity gain due to soot
accumulation in the engine oil, and VGT is the viscosity gain due to engine oil
temperature.
The viscosity gain module 106 determines a percent viscosity
gain that is independent of time based on the viscosity gain rate. The percent
viscosity gain may be determined with the following equation:

where VG% is the percent viscosity gain, VGR is the viscosity gain rate, and t is a
time that the diesel engine 12 has been operating according to the current
operating conditions.
The remaining oil life module 108 uses the percent viscosity
gain to determine the POLR. More specifically, the remaining life oil module 108
retrieves the previously determined POLR from memory 43 and adds the percent
viscosity gain to determine the POLR. The following equation may be used to
determine the POLR when the viscosity is increasing due to fuel evaporation:

where POLR is the percent oil life remaining, POLROLD is the previously
determined POLR, and VG% is the percent viscosity gain.
The POLR is stored in memory 43 as POLROLD 109 and is used
to calculate the POLR during the next cycle. However, the POLR is only
displayed on the oil life indicator 48 when POLR is less than POLROLD 109 to
prevent a driver from observing an increase in the POLR.
Referring now to Figure 3, the oil life monitoring system 100
implements steps generally identified at 200. The process starts in step 202
when the diesel engine system 10 is started. In step 204, control determines
whether the diesel engine system 10 is regenerating the DPF 40.
If the diesel engine system 10 is regenerating the DPF 40, the
viscosity loss module 104 determines the viscosity loss factor in step 206. As
previously discussed, the viscosity loss factor is based on engine speed, engine
torque, post injection fuel quantity, and post injection timing. In step 208, the

viscosity loss module 104 determines the viscosity loss rate based on the
viscosity loss factor. As previously discussed, the viscosity loss rate represents
viscosity loss per hour. In step 210, the viscosity loss module 104 determines
the percent viscosity loss, which is independent of time, based on the viscosity
loss rate.
The remaining oil life module 108 determines the POLR based
on the percent viscosity loss in step 212. More specifically, the remaining oil life
module 108 subtracts the percent viscosity loss from the POLR calculated during
the last iteration.
If the diesel engine system 10 is not regenerating the DPF 40,
the viscosity gain module 106 determines the viscosity gain due to soot
accumulation in the engine oil in step 214. In step 216, the viscosity gain module
106 determines the viscosity gain due to engine oil temperature. The viscosity
gain module 106 determines the rate of viscosity gain based on the viscosity gain
due to soot accumulation in the engine oil and the viscosity gain due to engine oil
temperature in step 218. As previously discussed, the viscosity gain represents
viscosity gain per hour. In step 220, the viscosity gain module 106 determines
the percent viscosity gain, which is independent of time, based on the viscosity
gain rate.
The remaining oil life module 108 determines the POLR based
on the percent viscosity gain in step 212. More specifically, the remaining oil life
module 108 adds the percent viscosity gain to the POLROLD 109, which is
calculated during the last iteration.

The remaining oil life module 108 stores the POLR as POLROLD
109 in memory 43 for the next iteration in step 222. In step 224, the remaining oil
life module 108 compares the POLR to POLROLD 109. If the POLR is less than
the POLROLD 109, the POLR is displayed on the oil life indicator 48 in step 226.
If the POLR is not less than the POLROLD 109, the POLROLD 109 is displayed on
the oil life indicator 48 in step 228. The process ends in step 230.
Those skilled in the art can now appreciate from the foregoing
description that the broad teachings of the present invention can be implemented
in a variety of forms. Therefore, while this invention has been described, in
connection with particular examples thereof, the true scope of the invention
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.

WE CLAIM
1. An oil life monitoring system for a diesel engine system (10),
characterized by comprising:
a viscosity loss module (104) that determines a percentage of viscosity
loss (VL%) of engine oil based on a post-combustion injection quantity and
a post-combustion injection time,
a viscosity gain module that determines a percentage of viscosity gain VG%
of engine oil based on at least one of fuel evaporation and soot
accumulation in said engine oil; and
a remaining oil life module (108) that communicates with said viscosity
loss module (104) and said viscosity gain module (106) and that
determines a percentage of oil life remaining (PLOR) based on at least
one of said percentage of viscosity loss (VL%) and said percentage of
viscosity gain (VG%).
2. The oil life monitoring system as claimed in claim 1, wherein said viscosity
loss (VL%) occurs due to fuel accumulation caused by said post-
4
combustion when the diesel engine system is regenerating a diesel
particulate filter.
3. The oil life monitoring system as claimed in claim 2, wherein said
percentage of viscosity loss (VL%) is based on a rate of viscosity loss (VLR).

4. The oil life monitoring system as claimed in claim 3, wherein said rate of
viscosity loss (VL%) is based on a viscosity loss factor (VLf).
5. The oil life monitoring system as claimed in claim 4, wherein said viscosity
loss factor (VLF) is based on an engine speed, and an engine torque.
6. The oil life monitoring system as claimed in claim 1, wherein said viscosity
gain (VGs, VGT) occurs when the diesel engine system (10) is not
regenerating a diesel particulate filter.
7. The oil life monitoring system as claimed in claim 6, wherein said
percentage of viscosity gain (VG%) is based on a rate of viscosity gain
(VGR).
8. The oil life monitoring system as claimed in claim 7, wherein said rate of
viscosity gain (VGR) is based on a viscosity gain (VGs) due to soot in engine
oil and a viscosity gain (VGT) due to engine oil temperature.
9. The oil life monitoring system as claimed in claim 1, wherein said
percentage of oil life remaining (POLR) is stored in memory (43).
10.The oil life monitoring system as claimed in claim 1, wherein said
remaining life oil module (108) displays said percentage of oil life
remaining (POLR) when said percentage of oil life remaining (POLR) is
decreasing.
11. A method to monitor oil life of a diesel engine system, comprising:

determining (206) a percentage of viscosity loss (VL%) of engine oil based
on a post-combustion injection quantity and a post-combustion injection
time;
determining (214) a percentage of viscosity gain (VG%) of engine oil based
on at least one of fuel evaporation and soot accumulation in said engine
oil; and
determining (226,228) a percentage of oil life remaining based on at least
one of said percentage of viscosity loss (VL%) and said percentage of
viscosity gain (VG%).
12.The method as claimed in claim 11, wherein said viscosity loss occurs due
to fuel accumulation caused by said post-combustion injection quantity
and said post-combustion injection time when the diesel engine system is
regenerating a diesel particulate filter.
13.The method as claimed in claim 12, comprising determining (210) said
percentage of viscosity loss (VL%) based on a rate of viscosity loss.
14.The method as claimed in claim 13, comprising determining (208) said
rate of viscosity loss based on a viscosity loss factor (VLR).
15.The method as claimed in claim 14, comprising determining said viscosity
loss factor based on an engine speed, an engine torque, a post injection
fuel quantity, and a post injection time.

16.The method as claimed in claim 11, wherein said viscosity gain occurs
when the diesel engine system is not regenerating a diesel particulate
filter.
17.The method as claimed in claim 16, comprising determining (214,216)
said percentage of viscosity gain based on a rate of viscosity gain.
18.The method as claimed in claim 17, comprising determining (218) said
rate of viscosity gain based on a viscosity gain based on a rte of viscosity
gain.
19.The method as claimed in claim 11, comprising storing (222) said
percentage of oil life remaining in a memory (43).
20.The method as claimed in claim 11, comprising displaying (228) said
percentage of oil life remaining when said percentage of oil life remaining
is decreasing.

ABSTRACT

TITLE : "AN OIL LIFE MONITORING SYSTEM AND A METHOD TO
MONITOR OIL LIFE OF AN ENGINE"
This invention relates to an oil life monitoring system for a diesel engine system
(10), characterized by comprising a viscosity loss module (104) that determines a
percentage of viscosity loss (VL%) of engine oil based on a post-combustion
injection quantity and a post-combustion injection time, a viscosity gain module
that determines a percentage of viscosity gain VG% of engine oil based on at
least one of fuel evaporation and soot accumulation in said engine oil; and a
remaining oil life module (108) that communicates with said viscosity loss
module (104) and said viscosity gain module (106) and that determines a
percentage of oil life remaining (PLOR) based on at least one of said percentage
of viscosity loss (VL%) and said percentage of viscosity gain (VG%).
{FIGURE - 1}

Documents:

01739-kol-2007-abstract.pdf

01739-kol-2007-claims.pdf

01739-kol-2007-correspondence others.pdf

01739-kol-2007-description complete.pdf

01739-kol-2007-drawings.pdf

01739-kol-2007-form 1.pdf

01739-kol-2007-form 2.pdf

01739-kol-2007-form 3.pdf

01739-kol-2007-form 5.pdf

1739-KOL-2007-(27-01-2012)-CORRESPONDENCE.pdf

1739-KOL-2007-(27-01-2012)-PA.pdf

1739-KOL-2007-ABSTRACT.pdf

1739-KOL-2007-AMANDED CLAIMS.pdf

1739-KOL-2007-ASSIGNMENT.pdf

1739-KOL-2007-CORRESPONDENCE 1.1.pdf

1739-KOL-2007-CORRESPONDENCE 1.3.pdf

1739-KOL-2007-CORRESPONDENCE OTHERS 1.1.pdf

1739-KOL-2007-CORRESPONDENCE OTHERS 1.2.pdf

1739-KOL-2007-CORRESPONDENCE-1.2.pdf

1739-KOL-2007-DESCRIPTION (COMPLETE).pdf

1739-KOL-2007-DRAWINGS.pdf

1739-KOL-2007-EXAMINATION REPORT.pdf

1739-KOL-2007-FORM 1.pdf

1739-KOL-2007-FORM 18.pdf

1739-KOL-2007-FORM 2.pdf

1739-KOL-2007-FORM 3 1.1.pdf

1739-KOL-2007-FORM 3 1.2.pdf

1739-KOL-2007-FORM 5 1.1.pdf

1739-KOL-2007-FORM 5.pdf

1739-KOL-2007-GPA.pdf

1739-KOL-2007-GRANTED-ABSTRACT.pdf

1739-KOL-2007-GRANTED-CLAIMS.pdf

1739-KOL-2007-GRANTED-DESCRIPTION (COMPLETE).pdf

1739-KOL-2007-GRANTED-DRAWINGS.pdf

1739-KOL-2007-GRANTED-FORM 1.pdf

1739-KOL-2007-GRANTED-FORM 2.pdf

1739-KOL-2007-GRANTED-SPECIFICATION.pdf

1739-KOL-2007-OTHERS 1.2.pdf

1739-KOL-2007-OTHERS-1.1.pdf

1739-KOL-2007-OTHERS.pdf

1739-KOL-2007-PETITION UNDER RULE 137.pdf

1739-KOL-2007-PRIORITY DOCUMENT.pdf

1739-KOL-2007-REPLY TO EXAMINATION REPORT 1.1.pdf

1739-KOL-2007-REPLY TO EXAMINATION REPORT.pdf

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Patent Number

252671

Indian Patent Application Number

1739/KOL/2007

PG Journal Number

22/2012

Publication Date

01-Jun-2012

Grant Date

28-May-2012

Date of Filing

27-Dec-2007

Name of Patentee

GM GLOBAL TECHNOLOGY OPERATIONS, INC.

Applicant Address

300 GM RENAISSANCE CENTER DETROIT, MICHIGAN

Inventors:

#	Inventor's Name	Inventor's Address
1	MATTHEW J. SNIDER	2604 BONNY BROOK HOWELL, MICHIGAN 48843
2	RICHARD A. BARKMAN	3018 N. VERMONT AVENUE ROYAL OAK, MICHIGAN 48073
3	ROBERT T. STOCKWELL	2116 JUANITO PONCA CITY, OKLAHOMA 47604
4	STEVEN J. ANDRASKO	30175 OLD PLANK ROAD WIXOM, MICHIGAN 48393
5	DAVID P. QUIGLEY	10032 NEWFOUND GAP BRIGHTON, MICHIGAN 48114

PCT International Classification Number

F01M11/10; F01M11/10

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	11/650,866	2007-01-08	U.S.A.