Title of Invention	A TORQUE CONVERTER CLUTCH SLIP RATE MONITORING SYSTEM
Abstract	A torque converter clutch slip rate monitoring system, comprising: a slip rate calculation module that receives a raw slip speed of a torque converter clutch and that calculates torque converter clutch slip acceleration based on the raw slip speed; a torque converter clutch slip rate monitoring module that detects deviation of the slip acceleration from a predetermined range during a pulldown of the torque converter clutch, and an apply adapt cell update module that performs an adjustment to an apply adapt cell, wherein the cell being adapted corresponds to a turbine torque at which the deviation occurred.

Title of Invention

A TORQUE CONVERTER CLUTCH SLIP RATE MONITORING SYSTEM

Abstract

A torque converter clutch slip rate monitoring system, comprising: a slip rate calculation module that receives a raw slip speed of a torque converter clutch and that calculates torque converter clutch slip acceleration based on the raw slip speed; a torque converter clutch slip rate monitoring module that detects deviation of the slip acceleration from a predetermined range during a pulldown of the torque converter clutch, and an apply adapt cell update module that performs an adjustment to an apply adapt cell, wherein the cell being adapted corresponds to a turbine torque at which the deviation occurred.

Full Text	TORQUE CONVERTER CLUTCH APPLY ADAPT AND QUALITY APPLY DETECTION CONVERTER SLIP ACCELERATION FIELD [0001] The present disclosure relates to monitoring performance of a torque converter clutch in a motor vehicle BACKGROUND [0002] The statements in this section merely provide background information related to the present disclosure and may not constitute prior art [0003] Starting with Figure 1, vehicles traditionally include a power plant, such as an internal combustion engine 102, that generates drive torque The drive torque is transferred through a powertrain and a dnveline 104 to a dnven wheel or wheels 106, which propel the vehicle along a surface The powertrain 104 often includes an automatic transmission 108 that is coupled to the engine 102 by a torque converter 110, which is a type of fluid coupling, which allows the engine 102 to spin somewhat independently of the transmission 108 [0004] Turning now to Figure 2, a typical torque converter 110 is made up of a turbine 200, a pump 202, a stator 204, and transmission fluid The housing 206 of the torque converter 110 is bolted to the flywheel 208 of the engine, and thus turns at the same speed as the engine The fins that make up the pump 202 of the torque converter 110 are attached to the housing 206, so they also turn at the same speed as the engine [0005] The pump 202 inside a torque converter is a type of centrifugal pump As it spins, fluid is flung to the outside As fluid is flung to the outside, a vacuum is created that draws more fluid in at the center The fluid then enters the blades of the turbine 200, which is connected to the transmission by turbine output shaft 210 The turbine 200 causes the transmission to spin, which moves the vehicle Since the blades of the turbine 200 are curved, the fluid, which enters the turbine 200 from the outside, has to change direction before it exits the center of the turbine 200 This directional change causes the turbine 200 to spin [0006] The fluid exits the turbine 200 at the center, moving in a different direction than when it entered The fluid exits the turbine 200 moving in an opposite direction than one in which the pump 202 (and engine) are turning If the fluid were allowed to hit the pump 202, it would slow the engine down, wasting power Therefore, a torque converter 110 has a stator 204 to prevent this waste of power [0007] The stator 204 resides in the very center of the torque converter 110 It is connected to a fixed shaft in the transmission by stator output shaft 212 The job of the stator 204 is to redirect the fluid returning from the turbine 200 before it hits the pump 202 again This redirection dramatically increases the efficiency of the torque converter 110 [0008] In some cases, there can be a lock-up clutch, which can create a firm connection between the pump 202 and turbine 200 The clutch is usually only engaged when a speed ratio of 1 1 has been achieved between turbine 200 and pump 202 [0009] Turning now to Figure 3, strategies for delivering power directly from the crankshaft into an automatic transmission have ranged from a purely mechanical connection via a high clutch drum and shaft transmitted through a damper plate assembly, to an actual clutch apply, all taking place inside the torque converter's fluid coupling The converter clutch apply method has been the strategy of choice among vehicle manufacturers This strategy has gone through several changes through the years Some previous strategies have used a simple ON/OFF solenoid 300 in conjunction with an encapsulated check ball assembly 302 at the tip of the input shaft The solenoid 300 turns the clutch on and off while the check ball assisted in a controlled apply of the clutch [0010] In more recent strategies, a pulse width modulated (PWM) torque converter clutch (TCC) solenoid 304 is added to the system in order to enhance converter clutch engagement for improved fuel economy A powertram control module (PCM) provides a duty cycle to this pulse width modulated (PWM) solenoid 304, which in turn regulates the pressure in the TCC hydraulic circuit, allowing the torque converter clutch to apply gradually As apply pressure is increased, slip is also increased proportionally Therefore, the amount of slip that occurs during the apply is proportional to the duty cycle [0011] The construction of the PWM solenoid 304 is such that when the solenoid 304 is completely turned off, feed pressure (AFL) to the solenoid 304 is blocked at the solenoid 304 When the solenoid 304 is duty-cycled, it opens to a circuit that allows pressure to act on the isolator valve 306 This increases the spnng tension acting on the TCC regulator valve 308, which then increases regulated TCC apply pressure As the duty cycle decreases, the regulated apply pressure decreases As the duty cycle increases, so does the regulated apply pressure As mentioned above, more pressure equals less slip and visa versa The relationship between fluid apply pressure and input of the pressure control solenoid is essentially linear, and can be described by the following equation y = mx + b, where y is fluid apply pressure, a is gain of the regulator valve, x is input of the pressure control solenoid, and b is offset of the solenoid spring SUMMARY [0012] A torque converter clutch slip rate monitoring system includes a slip rate calculation module that receives a raw slip speed of a torque converter clutch and that calculates torque converter clutch slip acceleration based on the raw slip speed A torque converter clutch slip rate monitoring module detects deviation of the slip acceleration from a predetermined range during a pulldown of the torque converter clutch [0013] 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 DRAWINGS [0014] The drawings descnbed herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way [0015] Figure 1 is a diagram illustrating a vehicle [0016] Figure 2 is a diagram of a torque converter [0017] Figure 3 is a block diagram illustrating a torque converter apply pressure control assembly [0018] Figure 4 is a block diagram illustrating a TCC apply adapt update system [0019] Figure 5 is a block diagram illustrating TCC slip acceleration calculation [0020] Figure 6 is a block diagram illustrating TCC slip acceleration calculation by a third order Kalman filter [0021] Figure 7 is a graphical representation illustrating TCC apply adapt update calculation to arrive at an ideal slip [0022] Figure 8 is a graphical representation illustrating adapt cells arrayed by turbine torque [0023] Figure 9 is a flow diagram illustrating a TCC apply adapt update method DETAILED DESCRIPTION [0024] The following description of the preferred embodiment 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, or other suitable components that provide the described functionality [0025] The slip rate monitoring system and method according to the present invention can be implemented in various ways For example, the slip rate monitoring system and method can include or employ a third order Kalman filter Alternatively or additionally, the slip rate monitoring system and method can include or employ a rating module to rate torque converter clutch performance in order to provide feedback to system designers Alternatively or additionally, the slip rate monitoring system and method can be employed as a component of a torque converter clutch apply adapt update system and method Moreover, it should be readily understood that these embodiments can be combined to accomplish a torque converter clutch apply adapt update system that employs a third order Kalman filter and includes a rating module Therefore, it should also be readily understood that, although the slip rate monitoring system and method is described below with respect to such a combination, the slip rate monitoring system and method is not embodied solely in such a combination [0026] Referring now to Figures 4-6, an exemplary vehicle system 10 includes an engine 12 that generates drive torque More specifically, air is drawn into an intake manifold 14 through a throttle 16 The air is mixed with fuel, and the fuel and air mixture is combusted within a cylinder 18 to reciprocally drive a piston (not shown), which rotatably drives a crankshaft (not shown) Exhaust, resulting from the combustion process, is exhausted through an exhaust manifold 20, is treated in an after-treatment system (not shown) and is released to atmosphere [0027] The crankshaft dnves an automatic transmission 22 through a torque converter 24 The transmission 22 includes an input shaft (not shown) and an output shaft 26, which transmits drive torque through a dnveline (not shown) to rotatably dnve a wheel or wheels 28 [0028] "A control module 30 regulates overall operation of the vehicle system 10 More specifically, the control module 30 receives vehicle operating parameter signals from a plurality of sensors and controls the system 10 based thereon Exemplary sensors include a mass air flow (MAF) sensor 32, a throttle position sensor 34, a manifold absolute pressure (MAP) sensor 36 and an engine RPM sensor 38 [0029] The sensors also include a turbine speed sensor 40 that generates a signal based on the rotation of the turbine of the torque converter 24 More specifically, the turbine speed sensor 40 is responsive to a toothed wheel 42 that is fixed for rotation with the turbine output shaft The turbine speed sensor 40 generates a pulse signal or output shaft signal (OSS) 44, wherein the pulses correspond to the rising and falling edges of the teeth of the toothed wheel 42 The OSS 44 is transmitted to the control module 30 [0030] In the control module 30, a hardware input/output driver 46 processes the OSS 44 pulse period and pulse count to obtain a raw turbine shaft speed 48, which is then compared to raw engine speed 50 to obtain a raw slip speed 52 This raw slip speed serves as input to a 3rd order Kalman filter 54, which calculates the TCC slip acceleration 56 In addition to the slip acceleration 56, the Kalman filter 54 also calculates speed 58 and jerk 60 During this process, filter 54 calculates error 62 by comparing the measured OSS to an estimated OSS The process of the Kalman filter can be described by the following equations Error = raw measured signal - estimated signal, E(k) = Y(k)-X1(k-1), X1(K)= X1(K-1)+ TX2(k-1) + E(k) K1, X2(K)= X2(K-1)+ TX3(k-1) + E(k) K2, X3(K)=X3(K-1)+E(k)*K3, Y(k) measured raw signal from the sensor, X1 Estimated signal, X2 Estimated acceleration, X3 Estimated acceleration derivative (Jerk), T Filter sampling period As mentioned above, measured raw signal is equal to TCC Slip raw = Engine rpm raw - Turbine speed raw [0031] Turning now to Figures 7-8, the TCC apply adapt update system is able to determine a difference 66 between a desired slip rate 68 and an actual slip rate 70 occurnng as a result of a slow apply The system employs this difference 66 to adapt the apply pressure rate at the solenoid 72 (Fig 4) in order to adjust an actual slip 74 to be within upper and lower bounds 76A-B in order to achieve an ideal slip curve 78 In other words, the system first utilizes a third order Kalman filter to calculate torque acceleration of converter slip Then, if the rate of change of the slip value during an apply is less than desired, then adapt apply pressure rate is updated based on apply turbine torque in order to reduce apply pressure rate On the other hand, if the rate of change of the slip value during the apply is greater than desired, then the adapt apply pressure rate is updated based on apply turbine torque in order to increase apply pressure rate To this end, the system employs an adapt cell map 80 having adapt cells arrayed by turbine torque The system monitors the slip rate during a pulldown while using the update cells 82A-E of the map 80 obtained during an immediately previous pulldown Then, the cells 82A-E are updated for use in a next pulldown [0032] The amount of adapt correction is a function of slip rate error (slip rate - threshold) Adapt_Ramp = Adapt_Ramp + correction term, TCC Apply Pressure = TCC Operting point + Ramp + Adapt_Ramp + On_Ramp Torque converter clutch apply is a function of torque converter slip rate of change and is looked up once per apply Apply thresholds are predetermined calibrations [0033] Turning now to Figure 9, a TCC apply adapt update method begins by calculating TCC slip acceleration at step 84 using the third order Kalman filter If the TCC is in the apply mode as at decision step 86, then slip rate pulldown is monitored dunng the apply at step 88 For example, if the offset adjusted slip acceleration falls above or below predefined thresholds during the apply as at decision steps 88A1 and 88A2, then the highest or lowest peak value of acceleration slip can be recorded, along with the turbine torque during the pulldown at step 88B In other words, if slip acceleration dunng the apply is outside the nominal range, then the TCC apply pressure' adapt correction is required The pressure adapt cells are a (17 cells) table function of turbine torque, Cell (x) = Cell (x) + adapt correction The adapt apply ramp can be adjusted according to the pulldown rate error and turbine torque at step 88C Based on the highest or lowest peak value of TCC slip acceleration, a signed pressure modifier correction can be added to the adapt cell (increase or decrease) at the corresponding turbine torque The TCC pressure correction modifier value is looked up from a predetermined calibration table This update of the apply adapt cells can be performed during the apply ramp or after completion of the pulldown Even of several cells are incorrect, iterative update of the most incorrect cell over several pulldowns can arrive deliberately and accurately at a slip rate within a predetermined range of acceptability for the entire pulldown However, it should also be readily understood that additional or alternative embodiments can update more than one cell after a pulldown, including some or all of the cells that, when used to accomplish the pulldown, result in a significant deviation from the ideal slip acceleration for their respective turbine torque values [0034] Once the apply is determined to be complete at decision step 90, then the TCC apply quality can be rated based on the slip rate and the apply time at step 92 in order to provide feedback to system designers In particular, based on TCC slip acceleration, the pulldown can be rated based on a predetermined TCC slip acceleration vs TCC quality rating table This rating can be a real time feedback to the engineer that can be used during the development phase of the product [0035] The TCC apply adapt update system and method yields several accomplishments For example, it accomplishes real time adaptation of torque converter clutch apply that can be derived with good accuracy and repeatability Also, it serves as an aid to calibration engineers in GMUT quantifying TCC applies Additionally, it accomplishes go/no-no testing for transmission misbuilds at assembly plants Further, it increases long term torque converter durability [0036] Returning now to Figure 4, it should be readily understood that control module 30 can have various functional modules for carrying out the functions of the system and steps of the method For example, control module 30 can have a slip rate calculation module, such as a third order Kalman filter, calculating torque converter clutch slip acceleration as a function of raw slip speed of a torque converter clutch Also, control module 30 can have a torque converter clutch slip rate monitoring module in communication with the slip rate calculation module and operating to (1) detect a deviation of the slip acceleration from an acceptable range dunng a pulldown of the torque converter clutch, and (2) record a value of the deviation together with a turbine torque at which the deviation occurred [0037] In some embodiments, control module 30 can have an apply adapt cell update module in communication with the monitoring module and operating to perform an adjustment to an apply adapt cell in computer readable memory that is employed to accomplish the pulldown The cell being adapted can correspond to the turbine torque at which the deviation occurred The adjustment can be performed in order to decrease the deviation during a subsequent pulldown [0038] In some embodiments, the monitoring module can compare the slip acceleration during the pulldown of the torque converter clutch to predetermined thresholds defining the range of acceptable slip acceleration and, if the slip acceleration is found to be unacceptable, record a value of greatest deviation of the slip acceleration outside of the range of acceptable slip acceleration along with the corresponding turbine torque at which the value of greatest deviation occurred In these and additional or alternative embodiments, the update module can add a signed pressure modifier correction to the apply adapt cell corresponding to the turbine torque at which the greatest deviation occurred by retrieving a value of the signed pressure modifier correction from a predetermined calibration table by the value of the greatest deviation [0039] Additional components of control module 30 can include a computer readable memory storing a data structure containing apply adapt cells arranged according to turbine torque Similarly, control module 30 can include a powertrain control module in communication with the memory and employing the adapt cells to adjust control of a solenoid governing fluid pressure in the torque converter clutch during a pulldown of the torque converter clutch The solenoid 72 can be in communication with this powertrain control module and responsive to control by the powertrain control module to govern fluid pressure in the torque converter clutch [0040] Also, control module 30 can have a raw slip speed calculation module in communication with the third order Kalman filter and calculating the raw slip speed by comparing a turbine speed to an engine speed Turbine speed sensor 40 can be in communication with this raw slip speed calculation module, and can operate to detect speed of the turbine of the torque converter clutch and generate a signal indicating the raw turbine speed Similarly, engine speed sensor 38 can be in communication with the raw slip speed calculation module, and can operate to detect engine speed and generate a signal indicating engine speed [0041] In additional or alternative embodiments, another functional module that can be included in control module 30 can be a rating module generating a rating of torque converter clutch apply quality in order to provide feedback to system designers In some embodiments, the pulldown can be rated as a function of slip rate and apply time with reference to a slip acceleration versus torque converter clutch quality rating table This rating can be stored in computer readable memory for reference by system designers, and/or communicated to system designers by a user interface It should be readily understood that the rating module can alternatively be separate from the control module 30, such as in the case of a computer workstation receiving the slip acceleration data into computer readable memory and producing the rating for the system designers [0042] 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 descnbed 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. A torque converter clutch slip rate monitoring system, comprising: a slip rate calculation module that receives a raw slip speed of a torque converter clutch and that calculates torque converter clutch slip acceleration based on the raw slip speed; a torque converter clutch slip rate monitoring module that detects deviation of the slip acceleration from a predetermined range during a pulldown of the torque converter clutch; and an apply adapt cell update module that performs an adjustment to an apply adapt cell, wherein the cell being adapted corresponds to a turbine torque at which the deviation occurred. 2. The system as claimed in claim 1, wherein a data structure that stores apply adapt cells arranged according to turbine torque. 3. The system as claimed in claim 2, wherein a powertrain control module that employs the adapt cells to adjust control of a solenoid governing fluid pressure of the torque converter clutch. 4. The system as claimed in claim 2, wherein a solenoid governing fluid pressure in the torque converter clutch. 5. The system as claimed in claim 1, wherein said monitoring module compares the slip acceleration during the pulldown of the torque converter clutch to predetermined thresholds defining the predetermined range of slip acceleration and, if the slip acceleration deviates from the range, records a value of greatest deviation along with the corresponding turbine torque at which the value of greatest deviation occurred. 6. The system as claimed in claim 5, wherein said update module adds a signed pressure modifier correction to the apply adapt cell corresponding to the turbine torque at which the greatest deviation occurred, wherein a value of the signed pressure modifier correction is retrieved from a predetermined calibration table by the value of the greatest deviation. 7. The system as claimed in claim 1, wherein a rating module that generates a rating of torque converter clutch apply quality. 8. The system as claimed in claim 7, wherein said rating module rates the pulldown based on slip rate and apply time with reference to a slip acceleration versus torque converter clutch quality rating table. 9. The system as claimed in claim 1, wherein a raw slip speed calculation module that calculates the raw slip speed by comparing a turbine speed to an engine speed. 10. The system as claimed in claim 9, wherein a turbine shaft speed sensor that detects speed of a turbine shaft of the torque converter clutch. 11. The system as claimed in claim 9, wherein an engine speed sensor that detects engine speed. 12. The system as claimed in claim 1, wherein said slip rate calculation module is a third order Kalman filter. 13. A torque converter clutch slip rate monitoring method, comprising: receiving a signal indicative of a raw slip speed of a torque converter clutch; calculating torque converter clutch slip acceleration as a function of the raw slip speed of the torque converter clutch; detecting a deviation of the slip acceleration from a predetermined range during a pulldown of the torque converter clutch; and performing an adjustment to an apply adapt cell, wherein the cell being adapted corresponds to a turbine torque at which the deviation occurred. 14. The method as claimed in claim 13, wherein employing a data structure that stores apply adapt cells arranged according to turbine torque. 15. The method as claimed in claim 14, wherein employing the adapt cells to adjust control of a solenoid governing fluid pressure in the torque converter clutch. 16. The method as claimed in claim 15, wherein controlling the solenoid to govern fluid pressure in the torque converter clutch. 17. The method as claimed in claim 13, wherein: comparing the slip acceleration to predetermined thresholds defining the predetermined range of slip acceleration; and if the slip acceleration deviates from the range, recording a value of greatest deviation of the slip acceleration along with the corresponding turbine torque at which the value of greatest deviation occurred. 18. The method as claimed in claim 17, wherein: retrieving a value of a signed pressure modifier correction from a predetermined calibration table by the value of the greatest deviation; and adding the signed pressure modifier correction to the apply adapt cell corresponding to the turbine torque at which the greatest deviation occurred. 19. The method as claimed in claim 13, wherein generating a rating of torque converter clutch apply quality. 20. The method as claimed in claim 19, wherein rating the pulldown based on slip rate and apply time with reference to a slip acceleration versus torque converter clutch quality rating table. 21. The method as claimed in claim 13, wherein calculating the raw slip speed by comparing a turbine speed to an engine speed. 22. The method as claimed in claim 21, wherein employing a turbine shaft speed sensor to detect speed of a turbine shaft of the torque converter clutch. 23. The method as claimed in claim 21, wherein employing an engine speed sensor to detect engine speed. 24. The method as claimed in claim 13, wherein employing a third order Kalman filter to calculate the torque converter clutch slip acceleration. ABSTRACT Title: A torque converter clutch slip rate monitoring system. A torque converter clutch slip rate monitoring system, comprising: a slip rate calculation module that receives a raw slip speed of a torque converter clutch and that calculates torque converter clutch slip acceleration based on the raw slip speed; a torque converter clutch slip rate monitoring module that detects deviation of the slip acceleration from a predetermined range during a pulldown of the torque converter clutch, and an apply adapt cell update module that performs an adjustment to an apply adapt cell, wherein the cell being adapted corresponds to a turbine torque at which the deviation occurred.

Full Text

TORQUE CONVERTER CLUTCH APPLY ADAPT AND QUALITY APPLY
DETECTION CONVERTER SLIP ACCELERATION
FIELD
[0001] The present disclosure relates to monitoring performance of
a torque converter clutch in a motor vehicle
BACKGROUND
[0002] The statements in this section merely provide background
information related to the present disclosure and may not constitute prior art
[0003] Starting with Figure 1, vehicles traditionally include a power
plant, such as an internal combustion engine 102, that generates drive torque
The drive torque is transferred through a powertrain and a dnveline 104 to a
dnven wheel or wheels 106, which propel the vehicle along a surface The
powertrain 104 often includes an automatic transmission 108 that is coupled
to the engine 102 by a torque converter 110, which is a type of fluid coupling,
which allows the engine 102 to spin somewhat independently of the
transmission 108
[0004] Turning now to Figure 2, a typical torque converter 110 is
made up of a turbine 200, a pump 202, a stator 204, and transmission fluid
The housing 206 of the torque converter 110 is bolted to the flywheel 208 of
the engine, and thus turns at the same speed as the engine The fins that
make up the pump 202 of the torque converter 110 are attached to the
housing 206, so they also turn at the same speed as the engine
[0005] The pump 202 inside a torque converter is a type of
centrifugal pump As it spins, fluid is flung to the outside As fluid is flung to
the outside, a vacuum is created that draws more fluid in at the center The
fluid then enters the blades of the turbine 200, which is connected to the
transmission by turbine output shaft 210 The turbine 200 causes the
transmission to spin, which moves the vehicle Since the blades of the turbine
200 are curved, the fluid, which enters the turbine 200 from the outside, has to

change direction before it exits the center of the turbine 200 This directional
change causes the turbine 200 to spin
[0006] The fluid exits the turbine 200 at the center, moving in a
different direction than when it entered The fluid exits the turbine 200 moving
in an opposite direction than one in which the pump 202 (and engine) are
turning If the fluid were allowed to hit the pump 202, it would slow the engine
down, wasting power Therefore, a torque converter 110 has a stator 204 to
prevent this waste of power
[0007] The stator 204 resides in the very center of the torque
converter 110 It is connected to a fixed shaft in the transmission by stator
output shaft 212 The job of the stator 204 is to redirect the fluid returning
from the turbine 200 before it hits the pump 202 again This redirection
dramatically increases the efficiency of the torque converter 110
[0008] In some cases, there can be a lock-up clutch, which can
create a firm connection between the pump 202 and turbine 200 The clutch
is usually only engaged when a speed ratio of 1 1 has been achieved
between turbine 200 and pump 202
[0009] Turning now to Figure 3, strategies for delivering power
directly from the crankshaft into an automatic transmission have ranged from
a purely mechanical connection via a high clutch drum and shaft transmitted
through a damper plate assembly, to an actual clutch apply, all taking place
inside the torque converter's fluid coupling The converter clutch apply
method has been the strategy of choice among vehicle manufacturers This
strategy has gone through several changes through the years Some
previous strategies have used a simple ON/OFF solenoid 300 in conjunction
with an encapsulated check ball assembly 302 at the tip of the input shaft
The solenoid 300 turns the clutch on and off while the check ball assisted in a
controlled apply of the clutch

[0010] In more recent strategies, a pulse width modulated (PWM)
torque converter clutch (TCC) solenoid 304 is added to the system in order to
enhance converter clutch engagement for improved fuel economy A
powertram control module (PCM) provides a duty cycle to this pulse width
modulated (PWM) solenoid 304, which in turn regulates the pressure in the
TCC hydraulic circuit, allowing the torque converter clutch to apply gradually
As apply pressure is increased, slip is also increased proportionally
Therefore, the amount of slip that occurs during the apply is proportional to
the duty cycle
[0011] The construction of the PWM solenoid 304 is such that when
the solenoid 304 is completely turned off, feed pressure (AFL) to the solenoid
304 is blocked at the solenoid 304 When the solenoid 304 is duty-cycled, it
opens to a circuit that allows pressure to act on the isolator valve 306 This
increases the spnng tension acting on the TCC regulator valve 308, which
then increases regulated TCC apply pressure As the duty cycle decreases,
the regulated apply pressure decreases As the duty cycle increases, so does
the regulated apply pressure As mentioned above, more pressure equals
less slip and visa versa The relationship between fluid apply pressure and
input of the pressure control solenoid is essentially linear, and can be
described by the following equation
y = mx + b,
where y is fluid apply pressure, a is gain of the regulator valve, x is input of
the pressure control solenoid, and b is offset of the solenoid spring
SUMMARY
[0012] A torque converter clutch slip rate monitoring system
includes a slip rate calculation module that receives a raw slip speed of a
torque converter clutch and that calculates torque converter clutch slip
acceleration based on the raw slip speed A torque converter clutch slip rate
monitoring module detects deviation of the slip acceleration from a
predetermined range during a pulldown of the torque converter clutch

[0013] 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
DRAWINGS
[0014] The drawings descnbed herein are for illustration purposes
only and are not intended to limit the scope of the present disclosure in any
way
[0015] Figure 1 is a diagram illustrating a vehicle
[0016] Figure 2 is a diagram of a torque converter
[0017] Figure 3 is a block diagram illustrating a torque converter
apply pressure control assembly
[0018] Figure 4 is a block diagram illustrating a TCC apply adapt
update system
[0019] Figure 5 is a block diagram illustrating TCC slip acceleration
calculation
[0020] Figure 6 is a block diagram illustrating TCC slip acceleration
calculation by a third order Kalman filter
[0021] Figure 7 is a graphical representation illustrating TCC apply
adapt update calculation to arrive at an ideal slip
[0022] Figure 8 is a graphical representation illustrating adapt cells
arrayed by turbine torque
[0023] Figure 9 is a flow diagram illustrating a TCC apply adapt
update method

DETAILED DESCRIPTION
[0024] The following description of the preferred embodiment 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, or
other suitable components that provide the described functionality
[0025] The slip rate monitoring system and method according to the
present invention can be implemented in various ways For example, the slip
rate monitoring system and method can include or employ a third order
Kalman filter Alternatively or additionally, the slip rate monitoring system and
method can include or employ a rating module to rate torque converter clutch
performance in order to provide feedback to system designers Alternatively
or additionally, the slip rate monitoring system and method can be employed
as a component of a torque converter clutch apply adapt update system and
method Moreover, it should be readily understood that these embodiments
can be combined to accomplish a torque converter clutch apply adapt update
system that employs a third order Kalman filter and includes a rating module
Therefore, it should also be readily understood that, although the slip rate
monitoring system and method is described below with respect to such a
combination, the slip rate monitoring system and method is not embodied
solely in such a combination
[0026] Referring now to Figures 4-6, an exemplary vehicle system
10 includes an engine 12 that generates drive torque More specifically, air is
drawn into an intake manifold 14 through a throttle 16 The air is mixed with
fuel, and the fuel and air mixture is combusted within a cylinder 18 to
reciprocally drive a piston (not shown), which rotatably drives a crankshaft
(not shown) Exhaust, resulting from the combustion process, is exhausted

through an exhaust manifold 20, is treated in an after-treatment system (not
shown) and is released to atmosphere
[0027] The crankshaft dnves an automatic transmission 22 through
a torque converter 24 The transmission 22 includes an input shaft (not
shown) and an output shaft 26, which transmits drive torque through a
dnveline (not shown) to rotatably dnve a wheel or wheels 28
[0028] "A control module 30 regulates overall operation of the
vehicle system 10 More specifically, the control module 30 receives vehicle
operating parameter signals from a plurality of sensors and controls the
system 10 based thereon Exemplary sensors include a mass air flow (MAF)
sensor 32, a throttle position sensor 34, a manifold absolute pressure (MAP)
sensor 36 and an engine RPM sensor 38
[0029] The sensors also include a turbine speed sensor 40 that
generates a signal based on the rotation of the turbine of the torque converter
24 More specifically, the turbine speed sensor 40 is responsive to a toothed
wheel 42 that is fixed for rotation with the turbine output shaft The turbine
speed sensor 40 generates a pulse signal or output shaft signal (OSS) 44,
wherein the pulses correspond to the rising and falling edges of the teeth of
the toothed wheel 42 The OSS 44 is transmitted to the control module 30
[0030] In the control module 30, a hardware input/output driver 46
processes the OSS 44 pulse period and pulse count to obtain a raw turbine
shaft speed 48, which is then compared to raw engine speed 50 to obtain a
raw slip speed 52 This raw slip speed serves as input to a 3rd order Kalman
filter 54, which calculates the TCC slip acceleration 56 In addition to the slip
acceleration 56, the Kalman filter 54 also calculates speed 58 and jerk 60

During this process, filter 54 calculates error 62 by comparing the measured
OSS to an estimated OSS The process of the Kalman filter can be described
by the following equations
Error = raw measured signal - estimated signal,
E(k) = Y(k)-X1(k-1),
X1(K)= X1(K-1)+ T*X2(k-1) + E(k)* K1,
X2(K)= X2(K-1)+ T*X3(k-1) + E(k)* K2,
X3(K)=X3(K-1)+E(k)*K3,
Y(k) measured raw signal from the sensor,
X1 Estimated signal,
X2 Estimated acceleration,
X3 Estimated acceleration derivative (Jerk),
T Filter sampling period
As mentioned above, measured raw signal is equal to
TCC Slip raw = Engine rpm raw - Turbine speed raw
[0031] Turning now to Figures 7-8, the TCC apply adapt update
system is able to determine a difference 66 between a desired slip rate 68
and an actual slip rate 70 occurnng as a result of a slow apply The system
employs this difference 66 to adapt the apply pressure rate at the solenoid 72
(Fig 4) in order to adjust an actual slip 74 to be within upper and lower
bounds 76A-B in order to achieve an ideal slip curve 78 In other words, the
system first utilizes a third order Kalman filter to calculate torque acceleration
of converter slip Then, if the rate of change of the slip value during an apply
is less than desired, then adapt apply pressure rate is updated based on
apply turbine torque in order to reduce apply pressure rate On the other
hand, if the rate of change of the slip value during the apply is greater than
desired, then the adapt apply pressure rate is updated based on apply turbine
torque in order to increase apply pressure rate To this end, the system
employs an adapt cell map 80 having adapt cells arrayed by turbine torque
The system monitors the slip rate during a pulldown while using the update

cells 82A-E of the map 80 obtained during an immediately previous pulldown
Then, the cells 82A-E are updated for use in a next pulldown
[0032] The amount of adapt correction is a function of slip rate error
(slip rate - threshold)
Adapt_Ramp = Adapt_Ramp + correction term,
TCC Apply Pressure = TCC Operting point + Ramp + Adapt_Ramp
+ On_Ramp
Torque converter clutch apply is a function of torque converter slip rate of
change and is looked up once per apply Apply thresholds are predetermined
calibrations
[0033] Turning now to Figure 9, a TCC apply adapt update method
begins by calculating TCC slip acceleration at step 84 using the third order
Kalman filter If the TCC is in the apply mode as at decision step 86, then slip
rate pulldown is monitored dunng the apply at step 88 For example, if the
offset adjusted slip acceleration falls above or below predefined thresholds
during the apply as at decision steps 88A1 and 88A2, then the highest or
lowest peak value of acceleration slip can be recorded, along with the turbine
torque during the pulldown at step 88B In other words, if slip acceleration
dunng the apply is outside the nominal range, then the TCC apply pressure'
adapt correction is required The pressure adapt cells are a (17 cells) table
function of turbine torque,
Cell (x) = Cell (x) + adapt correction
The adapt apply ramp can be adjusted according to the pulldown rate error
and turbine torque at step 88C Based on the highest or lowest peak value of
TCC slip acceleration, a signed pressure modifier correction can be added to
the adapt cell (increase or decrease) at the corresponding turbine torque
The TCC pressure correction modifier value is looked up from a
predetermined calibration table This update of the apply adapt cells can be
performed during the apply ramp or after completion of the pulldown Even of
several cells are incorrect, iterative update of the most incorrect cell over
several pulldowns can arrive deliberately and accurately at a slip rate within a

predetermined range of acceptability for the entire pulldown However, it
should also be readily understood that additional or alternative embodiments
can update more than one cell after a pulldown, including some or all of the
cells that, when used to accomplish the pulldown, result in a significant
deviation from the ideal slip acceleration for their respective turbine torque
values
[0034] Once the apply is determined to be complete at decision step
90, then the TCC apply quality can be rated based on the slip rate and the
apply time at step 92 in order to provide feedback to system designers In
particular, based on TCC slip acceleration, the pulldown can be rated based
on a predetermined TCC slip acceleration vs TCC quality rating table This
rating can be a real time feedback to the engineer that can be used during the
development phase of the product
[0035] The TCC apply adapt update system and method yields
several accomplishments For example, it accomplishes real time adaptation
of torque converter clutch apply that can be derived with good accuracy and
repeatability Also, it serves as an aid to calibration engineers in GMUT
quantifying TCC applies Additionally, it accomplishes go/no-no testing for
transmission misbuilds at assembly plants Further, it increases long term
torque converter durability
[0036] Returning now to Figure 4, it should be readily understood
that control module 30 can have various functional modules for carrying out
the functions of the system and steps of the method For example, control
module 30 can have a slip rate calculation module, such as a third order
Kalman filter, calculating torque converter clutch slip acceleration as a
function of raw slip speed of a torque converter clutch Also, control module
30 can have a torque converter clutch slip rate monitoring module in
communication with the slip rate calculation module and operating to (1)
detect a deviation of the slip acceleration from an acceptable range dunng a
pulldown of the torque converter clutch, and (2) record a value of the deviation
together with a turbine torque at which the deviation occurred

[0037] In some embodiments, control module 30 can have an apply
adapt cell update module in communication with the monitoring module and
operating to perform an adjustment to an apply adapt cell in computer
readable memory that is employed to accomplish the pulldown The cell
being adapted can correspond to the turbine torque at which the deviation
occurred The adjustment can be performed in order to decrease the
deviation during a subsequent pulldown
[0038] In some embodiments, the monitoring module can compare
the slip acceleration during the pulldown of the torque converter clutch to
predetermined thresholds defining the range of acceptable slip acceleration
and, if the slip acceleration is found to be unacceptable, record a value of
greatest deviation of the slip acceleration outside of the range of acceptable
slip acceleration along with the corresponding turbine torque at which the
value of greatest deviation occurred In these and additional or alternative
embodiments, the update module can add a signed pressure modifier
correction to the apply adapt cell corresponding to the turbine torque at which
the greatest deviation occurred by retrieving a value of the signed pressure
modifier correction from a predetermined calibration table by the value of the
greatest deviation
[0039] Additional components of control module 30 can include a
computer readable memory storing a data structure containing apply adapt
cells arranged according to turbine torque Similarly, control module 30 can
include a powertrain control module in communication with the memory and
employing the adapt cells to adjust control of a solenoid governing fluid
pressure in the torque converter clutch during a pulldown of the torque
converter clutch The solenoid 72 can be in communication with this
powertrain control module and responsive to control by the powertrain control
module to govern fluid pressure in the torque converter clutch

[0040] Also, control module 30 can have a raw slip speed
calculation module in communication with the third order Kalman filter and
calculating the raw slip speed by comparing a turbine speed to an engine
speed Turbine speed sensor 40 can be in communication with this raw slip
speed calculation module, and can operate to detect speed of the turbine of
the torque converter clutch and generate a signal indicating the raw turbine
speed Similarly, engine speed sensor 38 can be in communication with the
raw slip speed calculation module, and can operate to detect engine speed
and generate a signal indicating engine speed
[0041] In additional or alternative embodiments, another functional
module that can be included in control module 30 can be a rating module
generating a rating of torque converter clutch apply quality in order to provide
feedback to system designers In some embodiments, the pulldown can be
rated as a function of slip rate and apply time with reference to a slip
acceleration versus torque converter clutch quality rating table This rating
can be stored in computer readable memory for reference by system
designers, and/or communicated to system designers by a user interface It
should be readily understood that the rating module can alternatively be
separate from the control module 30, such as in the case of a computer
workstation receiving the slip acceleration data into computer readable
memory and producing the rating for the system designers
[0042] 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
descnbed 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. A torque converter clutch slip rate monitoring system, comprising:
a slip rate calculation module that receives a raw slip speed of a torque
converter clutch and that calculates torque converter clutch slip
acceleration based on the raw slip speed;
a torque converter clutch slip rate monitoring module that detects
deviation of the slip acceleration from a predetermined range during a
pulldown of the torque converter clutch; and
an apply adapt cell update module that performs an adjustment to an
apply adapt cell, wherein the cell being adapted corresponds to a turbine
torque at which the deviation occurred.
2. The system as claimed in claim 1, wherein a data structure that stores
apply adapt cells arranged according to turbine torque.
3. The system as claimed in claim 2, wherein a powertrain control module
that employs the adapt cells to adjust control of a solenoid governing fluid
pressure of the torque converter clutch.

4. The system as claimed in claim 2, wherein a solenoid governing fluid
pressure in the torque converter clutch.
5. The system as claimed in claim 1, wherein said monitoring module
compares the slip acceleration during the pulldown of the torque converter
clutch to predetermined thresholds defining the predetermined range of
slip acceleration and, if the slip acceleration deviates from the range,
records a value of greatest deviation along with the corresponding turbine
torque at which the value of greatest deviation occurred.
6. The system as claimed in claim 5, wherein said update module adds a
signed pressure modifier correction to the apply adapt cell corresponding
to the turbine torque at which the greatest deviation occurred, wherein a
value of the signed pressure modifier correction is retrieved from a
predetermined calibration table by the value of the greatest deviation.
7. The system as claimed in claim 1, wherein a rating module that
generates a rating of torque converter clutch apply quality.

8. The system as claimed in claim 7, wherein said rating module rates the
pulldown based on slip rate and apply time with reference to a slip
acceleration versus torque converter clutch quality rating table.
9. The system as claimed in claim 1, wherein a raw slip speed calculation
module that calculates the raw slip speed by comparing a turbine speed to
an engine speed.

10. The system as claimed in claim 9, wherein a turbine shaft speed
sensor that detects speed of a turbine shaft of the torque converter clutch.
11. The system as claimed in claim 9, wherein an engine speed sensor
that detects engine speed.
12. The system as claimed in claim 1, wherein said slip rate calculation
module is a third order Kalman filter.

13. A torque converter clutch slip rate monitoring method, comprising:
receiving a signal indicative of a raw slip speed of a torque converter clutch;
calculating torque converter clutch slip acceleration as a function of the raw slip
speed of the torque converter clutch;
detecting a deviation of the slip acceleration from a predetermined range during a
pulldown of the torque converter clutch; and
performing an adjustment to an apply adapt cell, wherein the cell being adapted
corresponds to a turbine torque at which the deviation occurred.
14. The method as claimed in claim 13, wherein employing a data structure that
stores apply adapt cells arranged according to turbine torque.
15. The method as claimed in claim 14, wherein employing the adapt cells to
adjust control of a solenoid governing fluid pressure in the torque converter
clutch.
16. The method as claimed in claim 15, wherein controlling the solenoid to
govern fluid pressure in the torque converter clutch.

17. The method as claimed in claim 13, wherein:
comparing the slip acceleration to predetermined thresholds defining the
predetermined range of slip acceleration; and
if the slip acceleration deviates from the range, recording a value of greatest
deviation of the slip acceleration along with the corresponding turbine torque
at which the value of greatest deviation occurred.
18. The method as claimed in claim 17, wherein:
retrieving a value of a signed pressure modifier correction from a
predetermined calibration table by the value of the greatest deviation; and
adding the signed pressure modifier correction to the apply adapt cell
corresponding to the turbine torque at which the greatest deviation occurred.
19. The method as claimed in claim 13, wherein generating a rating of torque
converter clutch apply quality.
20. The method as claimed in claim 19, wherein rating the pulldown based on
slip rate and apply time with reference to a slip acceleration versus torque
converter clutch quality rating table.

21. The method as claimed in claim 13, wherein calculating the raw slip
speed by comparing a turbine speed to an engine speed.
22. The method as claimed in claim 21, wherein employing a turbine shaft
speed sensor to detect speed of a turbine shaft of the torque converter clutch.
23. The method as claimed in claim 21, wherein employing an engine speed
sensor to detect engine speed.
24. The method as claimed in claim 13, wherein employing a third order
Kalman filter to calculate the torque converter clutch slip acceleration.

ABSTRACT

Title: A torque converter clutch slip rate monitoring system.
A torque converter clutch slip rate monitoring system, comprising:
a slip rate calculation module that receives a raw slip speed of a torque converter
clutch and that calculates torque converter clutch slip acceleration based on the
raw slip speed;
a torque converter clutch slip rate monitoring module that detects deviation of the
slip acceleration from a predetermined range during a pulldown of the torque
converter clutch, and
an apply adapt cell update module that performs an adjustment to an apply adapt
cell, wherein the cell being adapted corresponds to a turbine torque at which the
deviation occurred.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=lsvdgYsrXcInVm7BzvCCGQ==&loc=wDBSZCsAt7zoiVrqcFJsRw==

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Patent Number

271347

Indian Patent Application Number

1095/KOL/2008

PG Journal Number

08/2016

Publication Date

19-Feb-2016

Grant Date

17-Feb-2016

Date of Filing

24-Jun-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	HAYTHAMA A. FAYYAD	6700 WHEELER ROAD DEXTER, MICHIGAN 48130
2	WILLIAM R. MAYHEW	2751 MAPLEWOOD AVENUE ANN ARBOR, MICHIGAN 48104

PCT International Classification Number

F16H45/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	11/829,224	2008-03-04	U.S.A.