Torque Converter

Torque converter coupling between two drive shafts

Libraries:
Simscape / Driveline / Couplings & Drives

Description

The Torque Converter block represents an automotive torque converter that comprises an impeller, a turbine, and a stator. The impeller and the turbine make up the fluid coupling, and the stator increases torque by redirecting the flow returning to the impeller. As the shaft turns the impeller, centrifugal force flings the fluid outward toward the turbine blades, which causes the turbine to spin as the fluid proceeds to the center and out toward the stator. Use the block to connect an engine to an automatic transmission. Connect port I to the engine and port T to the transmission.

Cross-section of a torque converter. The flow moves continuously from the impeller blades to the turbine blades and then back to the impeller blades via the stator.

By default, the block constrains $τ_{T}$ , the torque at port T, and $τ_{I}$ , the torque at port I, to one another for a given time step. You can optionally include the effect of torque transmission time lag that is caused by internal fluid flow and compressibility. To include transmission lag, set Model transmission lag to Specify time constant and initial value. The block introduces the lag and finds the steady state torque at port I such that

$t_{c} (d τ_{I} / d t) + τ_{I} = τ_{I} (s t e a d y s t a t e) .$

The instantaneous function of the capacity factor K determines the steady-state value of τ_I. The block operates in drive mode when power flows from port I to port T. The block operates in coast mode when power flows in reverse. You can simulate the coast mode transition continuously or by using mode charts. The block uses the capacity factor for the torque converter to calculate torque from angular speed.

Two Mode Coast Transition

When you set Coast mode modeling to Two mode, the block uses separate modes for coasting or driving. The block computes the torque from angular speed such that

$τ = K^{*} ω^{2},$

where K^* is the Drive mode capacity factor vector parameter and ω is the angular speed for either port I or port T. The capacity factor is a function of the speed ratio. When in drive mode, the block defines the speed ratio as

$R_{ω} = ω_{T} / ω_{I},$

where ω_T and ω_I represent the speeds at ports T and I, respectively. When in coast mode, the block defines the speed ratio as

${\hat{R}}_{ω} = ω_{I} / ω_{T} .$

Because of the different speed ratio definitions, the block also uses a separate capacity factor for the coast mode, ${\hat{K}}^{*}$ , which is the Coast mode capacity factor vector parameter. The Mode transition parameter determines the speed at which the block changes modes. The graphic illustrates the two modes. Mode chart diagram where the drive mode and coast mode share a transition region. The turbine and impeller speeds match. At the coast mode extreme, the impeller speed is zero. At the drive mode extreme, the turbine speed is zero.

Continuous Coast Transition

When you set Coast mode modeling to Continuous, the block smoothly transitions between drive and coast mode. You can also add dynamics. The block simulation is less accurate when operating near the transition region.

The block defines the speed ratio as $R_{ω} = ω_{T} / ω_{I}$ and the torque ratio as $R_{τ} = τ_{T} / τ_{I}$ . The Capacity factor parameterization parameter controls how the block defines the capacity factor. When you select:

Ratio of speed to square root of impeller torque, the block uses $K = ω / \sqrt{τ_{I}}$ .
Ratio of impeller torque to square of speed, the block uses $K^{*} = τ_{I} / ω^{2}$ .

To improve fidelity, you can include lag due to the transmission in your simulation. When you set Model transmission lag to Specify time constant and initial value, the block adds a constant time delay to the torque transfer.

When you set Coast mode modeling to Continuous:

The impeller shaft must always rotate in a positive direction. Simulation is not valid for $ω_{I}$ < 0.
If you drive the Torque Converter block by using a torque source, such as the Generic Engine block, you must include an inertia in the source to represent the engine, shaft inertia, or other source components. To ensure that the impeller starts by rotating in a positive direction, set the initial speed for this inertia to a positive value.

Examples

Torque Converter in Two-Mode Modeling

Basic operations of a torque converter including lock-up clutch mechanism. You can select three different simulation cases - Basic Lock-up, Drive Mode Test, and Coast Mode Test.

Open Model

Vehicle with Four-Speed Transmission

A complete vehicle with Simscape™ Driveline™ components, including the engine, drivetrain, four-speed transmission, tires, and longitudinal vehicle dynamics. The transmission controller is implemented as a state machine in Stateflow®, selecting the gear based on throttle and vehicle speed.

Open Model

Vehicle with Four-Wheel Drive

A four-wheel drive vehicle starting from rest and ascending a 15 degree incline. Initially the vehicle rolls backwards until the engine develops sufficient torque to counter the slope. The tire compliance dynamics can be seen as the vehicle starts to accelerate. The model variant chosen for all of the tires can be set to the Simple, Friction Parameterized, or Magic Formula tire model using the hyperlinks in the model.

Open Model

Ports

Conserving

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I — Impeller
mechanical rotational

Mechanical rotational conserving port associated with the impeller.

T — Turbine
mechanical rotational

Mechanical rotational conserving port associated with turbine.

Parameters

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Torque Characteristics

Coast mode modeling — Coast transition simulation option
`Two-mode` (default) | `Continuous`

Coast mode transition method. When you select Continuous, the block smoothly transitions between drive and coast mode but has reduced accuracy and robustness when modeling near the transition. When you select Two-mode, the block uses mode charts, which promote better robustness and accuracy when the mode transitions.

Drive mode speed ratio vector — Turbine speed to impeller speed ratios
`[0, .5, .6, .7, .8, .87, .92, .94, .96, .97, 1]` (default) | vector

Speed ratios, $R_{ω}$ , of the drive mode. The vector elements must be in ascending order, start at 0, and end at 1.

$R_{ω} = ω_{T} / ω_{I}$