Hybrid Drive System Test Conditions, Function - GF08.30-P-2005RFH
Engine 274.920 in model 205.047/147/247, 253.954
Engine 274.920 in model 205.053/253
Engine 274.920 in model 253.354
Engine 651.921 in model 205.012/212
Engine 654.920 in model 205.013/213
The subfunction "hybrid drive system driving conditions, function" is considered and described from the point of view of the hybrid drive system.
We will not go into more detail here about internal signals and function sequences of the internal combustion engine and the A/T.
Function requirements for hybrid drive system test conditions, general
- Hybrid drive system "READY"
- Selector lever position "D" or "R"
Hybrid drive system test conditions, general
Differentiation of the driving conditions during operation is made between internal combustion engine, hybrid driving mode (drive with internal combustion engine and electrical machine) and electric driving mode (cruising mode, maneuvering).
For the driving operation with an internal combustion engine the electrical machine (A79/1) is mostly run as an alternator (alternator mode).
According to the request and charge level of the high-voltage battery (A100g1), in hybrid driving mode, the torque from the electrical machine operates together (supportively) with the torque of the internal combustion engine. The support occurs during moving off and acceleration (boost mode).
In electrical driving mode driving of the vehicle is purely electrical powered by the electrical machine.
The CDI control unit (N3/9) (for a diesel engine) or ME-SFI [ME] control unit (N3/10) (for a gasoline engine) reads in the following signals in decel mode:
- Accelerator pedal sensor (B37), signal (driver engine load request)
- Electronic Stability Program control unit (N30/4), via the CAN network:
- Wheel speed, signal
- Service brake, status
- Torque reduction, request
- Battery management system control unit (N82/2) via the CAN network:
- High-voltage battery voltage
- Temperature of high-voltage battery
- Radar sensors control unit (N62/1), (with code 23P (Driving assistance package)) via CAN network
- Request for a change of torque
- Power electronics control unit (N129/1) via the CAN network:
- Status of electrical machine
- Torque of electrical machine
- Rotational speed of electrical machine
- Charging voltage/current signal
- Fully integrated transmission control unit (Y3/8n4) via the CAN network:
- Mode
- Gear range status
- Wet clutch status
Function sequence for test conditions
For vehicles with code B53 (acoustic environmental protection), when the internal combustion engine is at a standstill, dependent on the speed (read in by the left front axle RPM sensor (L6/1), right front axle RPM sensor (L6/2), left rear axle RPM sensor (L6/3) and right rear axle RPM sensor (L6/4)) and accelerator pedal position (read in by the accelerator pedal sensor) an audio signal is issued between B370 and 30 km/h by the sound generator (H4/16). At speeds over 30 km/h, the sound generator is deactivated since the rolling and wind noises produced by the vehicle are loud enough to take notice of the vehicle.
The electric vehicle SOGE also active when gear range "R" is engaged and in idle dependent on the legal requirements in the USA.
The sound generator can be deactivated using the menu in COMAND.
The function sequence is described in the following steps:
- Function sequence for drive with the internal combustion engine
- Function sequence for driving off
- Function sequence for boost mode
- Function sequence for electrical operation
- Function sequence for alternator operation
- Function sequence for load point shifting
Function sequence for drive with the internal combustion engine
The drive with the internal combustion engine represents the standard driving mode.
Driving occurs in standard driving mode if
- the power required by the driver cannot be provided by the electrical machine.
- hybrid driving mode is not possible due to an insufficient high-voltage battery charge level.
- the engine oil temperature is too low in relation to the outside temperature.
- An error is reported in the hybrid drive system.
Additional function requirements for driving off
- No critical fault in the drive system
- Vehicle stops.
Function sequence for driving off
The vehicle moves according to the torque request of the driver which is read in by the ME-SFI [ME] control unit, initially purely electrically. For a respectively high performance request the internal combustion engine is started, rotational speed-synchronized and then coupled to the traction drive. In the case of strong acceleration the electrical machine is supported by the internal combustion engine, in particular for acceleration from low rotational speeds. In the case of driving off from an operating condition with the internal combustion engine, the wet clutch is used as a starting device.
During driving off the request for torque by the driver is read in by the CDI control unit or the ME-SFI [ME] control unit. The CDI control unit or ME-SFI [ME] control unit calculates and distributes the required starting torque to the internal combustion engine and the electrical machine. To do this the CDI control unit or ME-SFI [ME] control unit requests an additional motorized torque via the power electronics control unit.
The electrical machine is supplied over the power electronics control unit with energy from the high-voltage battery.
Driving off purely electrically can occur, if
- The torque request from the driver alone can be implemented electrically.
- no error is reported in the hybrid drive system.
- The charge level of the high-voltage battery is too high.
If the internal combustion engine is off (e.g. automatic engine stop), the oil supply for the A/T is secured over the electrical auxiliary oil pump (M42).
Function sequence for boost mode
In boost mode the electrical machine supports the internal combustion engine in order to reach the requested specified torque as quickly as possible or to further amplify the drive torque to amplify the maximum achieved internal combustion engine torque. The period and intensity of the boost mode are hereby dependent on the charge level of the high-voltage battery and the position of the accelerator pedal. Torque synchronization between the internal combustion engine and the electrical machine is realized in boost mode during driving off via appropriate actuation of the wet clutch. To do this the ME-SFI [ME] control unit requests actuation of the wet clutch via the CAN network. In boost mode in higher vehicle speed ranges the wet clutch is actuated in such a way that just a regulated zero slip situation is set. In order to match the torque request from the driver, the ME-SFI [ME] control unit requests in the same way from the power electronics control unit, as for electrical operation, a torque from the electrical machine which then operates together with the internal combustion engine on the drive.
In order to meet the request for torque from the driver the CDI control unit or the ME-SFI [ME] control unit makes a request to the power electronics control unit for the maximum available torque from the electrical machine.
The power electronics control unit actuates the electrical machine appropriately based on the signals tolerable discharge voltage/current reported by the CDI control unit or the ME-SFI [ME] control unit.
To do this the CDI control unit or the ME-SFI [ME] control unit requests from the power electronics control unit the previously calculated motorized torque from the electrical machine. This is provided with energy from the high-voltage battery over the power electronics control unit and works together with the internal combustion engine on the drive.
Function sequence for electrical operation
If the transmission mode or the operating mode of electrical drive allows it, the charge level of the high-voltage battery is high enough, the torque request of the driver can be fulfilled purely electrically and no diagnosis or no system error will prevent electrical operation, then this operating condition is adopted. The wet clutch is opened and the internal combustion engine is switched off by the ME-SFI [ME] control unit if certain prerequisites are fulfilled.
At least all of the following prerequisites must be fulfilled and releases awarded:
- Vehicle speed max. 130 km/h
- Transmission oil temperature > 0°C
- gear range plausible
- Adequate vacuum in the brake booster
- Enable issued by ESP®.
- Engine hood closed
- no crash event
- the condition of the 12-V on-board electrical system is OK and release has been issued
- Charge level of high-voltage battery is sufficient
- oil supply to A/T secured
- Driver door closed
- Driver seat belt applied
- interior temperature can be regulated with the current coolant temperature of the internal combustion engine.
- A/C has issued approval.
The function sequence is subdivided into the following transmission modes:
- Function sequence for electrical driving mode
- Function sequence for creeping
- Function sequence for cruising mode
Function sequence for electrical driving mode
In order to meet the request for torque from the driver the ME-SFI [ME] control unit or the CDI control unit makes a request to the power electronics control unit for the required immediate torque from the electrical machine according to the load request.
The power electronics control unit actuates electrical machine the appropriately on the basis of signals "tolerable discharge voltage" and "tolerable discharge current", reported by ME-SFI [ME] control unit or the CDI control unit. To do this the ME-SFI [ME] control unit or the CDI control unit requests from the power electronics control unit the previously calculated motorized torque from the electrical machine. This is provided with energy from the high-voltage battery over the power electronics control unit and acts on the drive. To do this the high-voltage battery supplies the power electronics control unit with a direct voltage, which is converted into a 3-phase AC voltage.
The ME-SFI [ME] control unit or the CDI control unit makes the request via the CAN network to the fully integrated transmission control unit for actuation of the wet clutch in order to disconnect the internal combustion engine from the drive. After appropriate feedback the ME-SFI [ME] control unit switches the internal combustion engine off over the opened wet clutch. If during the automatic engine stop a release is retracted or a prerequisite is no longer fulfilled, the internal combustion engine will automatically be started without any defined action on the part of the driver.
Function sequence for creeping
The creeping that is typical of automatic transmission is simulated electrically via the electrical machine or via the internal combustion engine and slipping of the wet clutch if the brake pedal and the accelerator pedal are not actuated. For creeping in electrical mode the electrical machine is supplied with a low current and operates directly on the drivetrain with acts with the torque that is generated in this way. For a situation such as a low charge level of the high-voltage battery the creeping is realized over the internal combustion engine and the slip of the wet clutch.
Additional function requirements for alternator operation
- SOC (State of Charge) < 60%
- No boos mode, no regenerative braking or load point shifting
Function sequence for cruising mode
If the brake and accelerator pedal are not actuated for a rolling vehicle, the internal combustion engine is disconnected from the engine in the transmission mode Economy (E) up to a speed < 160 km/h through opening the wet clutch of the drive and switched off.
For a slightly actuated accelerator pedal, the electrical machine supports the drive for an adequately high charge level of the high-voltage battery in order to counteract the falling vehicle speed.
To do this the CDI control unit or the ME-SFI [ME] control unit requests an engine-generated torque from the power electronics control unit via the CAN network. This actuates according to the request from the electrical machine.
Function sequence for alternator operation
During alternator operation the electrical machine, driven by the internal combustion engine, is used as an alternator in order to generate electrical energy.
In order to do this, the rotational energy of the crankshaft is taken up by the rotor of the electrical machine. Rotation of the rotor causes an AC voltage to be induced in the three stator windings. The electrical energy in the form of a 3-phase AC voltage that is generated in this way is limited, monitored and converted into high voltage direct voltage by the power electronics control unit.
The power electronics control unit uses the energy generated to supply the high voltage on-board electrical system, the electrical A/C compressor (A9/5) and the 12 V on-board electrical system and its assembly parts.
Additional function requirements for load point shifting
- SOC (State of Charge) < 60%
- No boost mode, no regenerative braking
Function sequence for load point shifting
The possibility of take up of recuperation energy by the high-voltage battery increases with increasing deviation from the optimal charge level of the high-voltage battery (SOC operating point). This means, if the high-voltage battery is charged or discharged for a low or very high SOC value, increased energy losses are incurred in the form of heat. In order to reduce this and to keep space open for potentially arising regenerative energy, the high-voltage battery is discharged with the support of the combustion engine by the electric machine upon exceeding a defined SOC value.
In this way the load point of the internal combustion engine is shifted. That means that the torque of the internal combustion engine is reduced by the CDI control unit or the ME-SFI [ME] control unit.
The objective is to keep the shift in the load point within the load point range with good efficiency as far as possible. The load point shift is also used to put additional load on the internal combustion engine. In this way the CATs are brought up to operating temperature more quickly and the exhaust temperature required for regeneration of the diesel particulate filter is reached (for a diesel engine).
| Electrical function schematic for vehicle statuses of the hybrid drive system | PE08.30-P-2069-97FBH | ||
| Overview of system components, hybrid drive system | GF08.30-P-9999RFH |