The present disclosure relates to an arrangement comprising a motor, a transmission, a transmission control unit and an auxiliary user, the motor being rotatably connected to the transmission and the auxiliary user. The transmission control unit is designed to determine a torque applied to the transmission by using a parameterisable function, wherein the function maps rotational speeds of the motor to a torque applied to the auxiliary user at the rotational speed.

The “factory installed” hydraulic circuitry of an automotive transmission is modified to increase line pressure to permit heavy duty and high performance applications of the transmission, and to prevent the onboard computer from sensing and counteracting the increased line pressure. The “factory installed” Torque Converter Clutch (TCC) regulator valve is modified to prevent over pressuring of this valve which would otherwise result from the increased line pressure. The “factory installed” Torque Converter Clutch control valve is modified to compensate for the increase in line pressure to adjust the application of the valve to prevent rough or abrupt gear shifts and provide smooth application of the torque converter clutch.

A system and method for an automotive transmission includes one or more restrictor devices that are installed within a valve body of the automotive transmission to improve performance by establishing a flow limit along the compensator circuit. The complex fluid circuits of certain automotive transmissions having eight to ten speeds allow line pressure supply to bleed out during certain critical functions, such as low rotations per minute hot engagements, which can severely damage the transmission. By limiting flow, the line pressure supply can be preserved to prevent the compensator circuit from bleeding out in these critical functions. The instant invention limits flow by replacing the standard compensator valve with a compensator valve that has a larger spool diameter. Flow is further reduce by another restriction device placed along the compensator circuit between the compensator valve and the clutch drums.

A method of adjusting and using operating parameters of a transmission of a vehicle may include accessing a stored list of clutch parameters, performing a dynamic condition procedure while the vehicle is driven to revise minimum on-coming apply pressure for each friction element based on a sensed performance of an element within the vehicle powertrain, storing the modified minimum on-coming apply pressures, and operating the vehicle. A related transmission control device operates a transmission using parameters obtained during a dynamic condition procedure.

A method for modifying the hydraulic circuitry of factory installed 46RE, 47RE and 48 RE automotive transmissions internally re-routes the flow of hydraulic fluid within the valve body of the automotive transmission to improve the overall operation of these factory installed automotive transmissions, without adding or installing any external passageway structures to the valve body. The internal re-routing of the hydraulic flow within the valve body is accomplished by replacing the existing separator plate with one or more new cooperating separator plates, and by plugging portions of the existing hydraulic circuitry, to internally re-route the flow of hydraulic fluid within the valve body by blocking certain existing internal hydraulic circuitry and by creating new internal hydraulic circuitry for fluid flow within the valve body. The modified 46RE and 47RE transmissions exhibit improved operating characteristics, simulating the operation of a 48RE automotive transmission.

The hydraulic circuitry of a factory installed automatic automotive transmission is modified to replace an underdrive accumulator spring with a shorter spring and a separate lower rated spring washer operatively associated with the shorter replacement underdrive accumulator spring. The combined replacement spring and spring washer conjointly act on an underdrive accumulator piston to move it in two predetermined distances, in two separate continuous stages, namely, movement of the piston for a first predetermined distance is controlled by the spring washer, while movement of the piston for a second predetermined distance is controlled by the replacement spring. The spring washer has a lower spring rating than the replacement spring, so that less fluid pressure is required to move the piston the total distance traveled, resulting in less fluid pressure applied to an underdrive clutch than in the factory installed transmission. The spring ratings of the replacement spring and the spring washer are selected such that the total fluid pressure required to move the piston both the first and second predetermined distances is less than the fluid pressure required to overcome the resilient force of underdrive piston return springs acting on an underdrive apply piston so that a lower fluid pressure is applied to an underdrive clutch.

The factory installed hydraulic circuitry of an automotive transmission is modified to increase line pressure to permit heavy duty and high performance applications of the transmission, and to prevent the onboard computer from sensing and counteracting the increased line pressure. The factory installed Torque Converter Clutch (TCC) regulator valve is modified to prevent over pressuring of this valve which would otherwise result from the increased line pressure. The factory installed Torque Converter Clutch control valve is modified to compensate for the increase in line pressure to adjust the application of the valve to prevent rough or abrupt gear shifts and provide smooth application of the torque converter clutch.

Methods and systems for generating control instructions for a plurality of transmissions having dissimilar gear configurations via a common software framework are described. In one example, the common software framework provides a graphic interface whereby a user/implementer describes configurations of different transmissions. The software framework generates instructions for different transmission controllers that shift the transmissions.

The factory installed pressure regulator valve of an automotive transmission is replaced by a pressure regulator valve having two separate valve components conjointly movable together in a bore. A protrusion or protuberance extending from the center of one end of one of the valve components defines a fulcrum which abuts against an adjacent end of the other valve component as the two valve components move conjointly and in direct contact with each other within the bore during operation of the pressure regulator valve. Preferably, an opening is provided in a land in one of the valve components to vent hydraulic fluid (transmission oil) to prevent a pressure build-up in the bore which might separate the two valve components from each other during reciprocating movement of the valve components in the bore.

Methods of modifying a GM Powerglide low range servo assembly for high line pressure applications as well as replacement components for Powerglide low range servo assemblies and replacement low range servo assemblies.