Hello

Welcome lekule blog

Hi, I`m Sostenes, Electrical Technician and PLC`S Programmer.
Everyday I`m exploring the world of Electrical to find better solution for Automation.
together in the world. #lekule86
Join us on

Audi Prototypes Regenerative Suspension on Hybrid Vehicles

Audi's eROT suspension turns the kinetic energy from traveling a bumpy road into fuel efficiency—and smoother rides.

Carmakers consider making use of any kind of energy wasted in a vehicle to increase the fuel efficiency.
As an example, the well-known regenerative braking system recaptures the kinetic energy of a moving car to make it go slower. In its simplest form, regenerative braking—which is mainly utilized in hybrid and EV vehicles—employs an electric motor, configured as a dynamo, to turn the kinetic energy into electricity when the car brakes.

This energy can be stored and used later to power the vehicle or its accessories, taking some of the load off the engine.

Audi's Suspension vs Traditional Hydraulic Suspensions

Audi’s electromechanical rotary damper is another example of spotting a source of wasted energy by carmakers. Traditional hydraulic suspensions damp the up-and-down motion of the wheels by converting the kinetic energy into heat. Therefore, in these systems, the increasing pressure warms up the working fluid and the energy goes to waste.

In contrast, Audi has recently introduced its innovative damper, called eROT, which captures the kinetic energy from vertical movements of the car which are mainly caused by the bumpy roads.
To this end, eROT replaces the traditional hydraulic dampers with a lever arm and a horizontally-oriented electric motor configured as a dynamo. The up-and-down wheel motions are appropriately manipulated by the lever arm and a series of gears to turn the dynamo. The system then channels the recuperated electricity into a tiny 0.5-kWh 48-volt lithium-ion battery.


The eROT. Image courtesy of AutoTimesNews.

The new damper leads to fuel efficiency and effectively reduces air pollution. Test results confirm that eROT is capable of recuperating an average of 100 to 150 watts on a typical German road. It produces three watts on a newly-paved freeway and 613 watts on a rough stretch of tarmac. According to Audi, the eROT can reduce carbon-dioxide emissions by 4.8 grams per mile (3g/kilometer).

The idea of recovering the energy wasted in dampers is not new. The GenShock technology of ZF, introduced in 2013, pursued a similar idea. However, Audi uses horizontally-oriented electromechanical dampers instead of the traditional ones. The new system not only recuperates the energy but also allows more cargo space by eliminating the traditional telescopic shock absorbers which normally poke up into the cabin.

eROT: A More Adjustable Active Suspension

Audi claims that the new system increases suspension adjustability and is more successful than the traditional active suspensions in smoothing the ride on a bumpy road.
An active suspension involves two features:
  • the compression stroke, which determines what the occupants of the car feel going over a bump
  • the rebound stroke, which influences the car’s handling.
Ride comfort and handling, respectively, require soft and firm suspension tuning. This is not easily achieved in the traditional dampers.
However, according to Audi, eROT can tune the dampers' compression and rebound strokes independently of one another. Defining both these characteristics by software, eROT softens the compression stroke and keeps the rebound taut. As a result, the new system provides a better balance between ride comfort and handling.

Audi Suits the Future 48-Volt Cars

Currently, Audi hybrids exploit the 48-volt electrical system as a secondary network which operates in tandem with the primary 12-volt network. A DC converter is required to connect these two systems together. Many analysts believe the 48-volt systems will become necessary in the next few years to support the increasing amount of electronics in cars.


Many cars use a 12-volt primary electrical network in tandem with a 48-volt auxiliary one. Image courtesy of AutoTimesNews.

In addition, use of a 48-volt primary system holds the potential for storing small amounts of electricity produced by regenerative braking and regenerative suspension such as the eROT. Therefore eliminating the need for a DC converter, a 48-volt electrical system perfectly suits Audi’s new damper.

The recuperated electricity from eROT could be used to power the car’s electronics or to power the small motor in "mild hybrid" cars. A mild hybrid uses an electric motor to assist the internal combustion engine. However, these vehicles cannot operate in a fully-electric mode the way a full-hybrid can.


The current version of eROT is in the prototype stage. However, considering the successful test results, Audi expects to utilize a new version of this energy-saving and ride-perfecting technology on a high-performance 48-volt mild hybrid vehicle in 2017. Employing eROT, the 48-volt vehicle is expected to reduce fuel use by around 0.7 litres per 100km.

Share this:

ABOUTME

Hi all. This is deepak from Bthemez. We're providing content for Bold site and we’ve been in internet, social media and affiliate for too long time and its my profession. We are web designer & developer living India! What can I say, we are the best..

Post a Comment
My photo

Hi, I`m Sostenes, Electrical Technician and PLC`S Programmer.
Everyday I`m exploring the world of Electrical to find better solution for Automation. I believe everyday can become a Electrician with the right learning materials.
My goal with BLOG is to help you learn Electrical.

Labels

LEKULE TV EDITORIALS ARTICLES DC ROBOTICS DIGITAL SEMICONDUCTORS GENERATOR AC EXPERIMENTS MANUFACTURING-ENGINEERING REFERENCE FUNDAMENTAL OF ELECTRICITY ELECTRONICS ELECTRICAL ENGINEER MEASUREMENT TRANSDUCER & SENSOR VIDEO ARDUINO RENEWABLE ENERGY AUTOMOBILE TEARDOWN SYNCHRONOUS GENERATOR DIGITAL ELECTRONICS ELECTRICAL DISTRIBUTION CABLES AUTOMOTIVE MICROCONTROLLER SOLAR PROTECTION DIODE AND CIRCUITS BASIC ELECTRICAL ELECTRONICS MOTOR SWITCHES CIRCUIT BREAKERS CIRCUITS THEORY PANEL BUILDING ELECTRONICS DEVICES MIRACLES SWITCHGEAR ANALOG MOBILE DEVICES WEARABLES CAMERA TECHNOLOGY COMMUNICATION GENERATION BATTERIES FREE CIRCUITS INDUSTRIAL AUTOMATION SPECIAL MACHINES ELECTRICAL SAFETY ENERGY EFFIDIENCY-BUILDING DRONE CONTROL SYSTEM NUCLEAR ENERGY SMATRPHONE FILTER`S POWER BIOGAS BELT CONVEYOR MATERIAL HANDLING RELAY ELECTRICAL INSTRUMENTS ENERGY SOURCE PLC`S TRANSFORMER AC CIRCUITS CIRCUIT SCHEMATIC SYMBOLS DDISCRETE SEMICONDUCTOR CIRCUITS WIND POWER C.B DEVICES DC CIRCUITS DIODES AND RECTIFIERS FUSE SPECIAL TRANSFORMER THERMAL POWER PLANT CELL CHEMISTRY EARTHING SYSTEM ELECTRIC LAMP FUNDAMENTAL OF ELECTRICITY 2 BIPOLAR JUNCTION TRANSISTOR 555 TIMER CIRCUITS AUTOCAD BLUETOOTH C PROGRAMMING HOME AUTOMATION HYDRO POWER LOGIC GATES OPERATIONAL AMPLIFIER`S SOLID-STATE DEVICE THEORRY COMPUTER DEFECE & MILITARY FLUORESCENT LAMP INDUSTRIAL ROBOTICS ANDROID ELECTRICAL DRIVES GROUNDING SYSTEM CALCULUS REFERENCE DC METERING CIRCUITS DC NETWORK ANALYSIS ELECTRICAL SAFETY TIPS ELECTRICIAN SCHOOL ELECTRON TUBES FUNDAMENTAL OF ELECTRICITY 1 INDUCTION MACHINES INSULATIONS USB ALGEBRA REFERENCE HMI[Human Interface Machines] INDUCTION MOTOR KARNAUGH MAPPING USEUL EQUIATIONS AND CONVERSION FACTOR ANALOG INTEGRATED CIRCUITS BASIC CONCEPTS AND TEST EQUIPMENTS DIGITAL COMMUNICATION DIGITAL-ANALOG CONVERSION ELECTRICAL SOFTWARE GAS TURBINE ILLUMINATION OHM`S LAW POWER ELECTRONICS THYRISTOR BOOLEAN ALGEBRA DIGITAL INTEGRATED CIRCUITS FUNDAMENTAL OF ELECTRICITY 3 PHYSICS OF CONDUCTORS AND INSULATORS SPECIAL MOTOR STEAM POWER PLANTS TESTING TRANSMISION LINE C-BISCUIT CAPACITORS COMBINATION LOGIC FUNCTION COMPLEX NUMBERS CONTROL MOTION ELECTRICAL LAWS INVERTER LADDER DIAGRAM MULTIVIBRATORS RC AND L/R TIME CONSTANTS SCADA SERIES AND PARALLEL CIRCUITS USING THE SPICE CIRCUIT SIMULATION PROGRAM AMPLIFIERS AND ACTIVE DEVICES APPS & SOFTWARE BASIC CONCEPTS OF ELECTRICITY CONDUCTOR AND INSULATORS TABLES CONDUITS FITTING AND SUPPORTS ELECTRICAL INSTRUMENTATION SIGNALS ELECTRICAL TOOLS INDUCTORS LiDAR MAGNETISM AND ELECTROMAGNETISM PLYPHASE AC CIRCUITS RECLOSER SAFE LIVING WITH GAS AND LPG SAFETY CLOTHING STEPPER MOTOR SYNCHRONOUS MOTOR AC METRING CIRCUITS BECOME AN ELECTRICIAN BINARY ARITHMETIC BUSHING DIGITAL STORAGE MEMROY ELECTRICIAN JOBS HEAT ENGINES HOME THEATER INPECTIONS LIGHT SABER MOSFET NUMERATION SYSTEM POWER FACTORS REACTANCE AND IMPEDANCE INDUCTIVE RECTIFIER AND CONVERTERS RESONANCE SCIENTIFIC NOTATION AND METRIC PREFIXES SULFURIC ACID TROUBLESHOOTING TROUBLESHOOTING-THEORY & PRACTICE 12C BUS APPLE BATTERIES AND POWER SYSTEMS DC MOTOR DRIVES ELECTROMECHANICAL RELAYS ENERGY EFFICIENCY-LIGHT INDUSTRIAL SAFETY EQUIPMENTS MEGGER MXED-FREQUENCY AC SIGNALS PRINCIPLE OF DIGITAL COMPUTING QUESTIONS REACTANCE AND IMPEDANCE-CAPATIVE SEQUENTIAL CIRCUITS SERRIES-PARALLEL COMBINATION CIRCUITS SHIFT REGISTERS WIRELESS BUILDING SERVICES COMPRESSOR CRANES DIVIDER CIRCUIT AND KIRCHHOFF`S LAW ELECTRICAL DISTRIBUTION EQUIPMENTS 1 ELECTRICAL DISTRIBUTION EQUIPMENTS B ELECTRICAL TOOL KIT ELECTRICIAN JOB DESCRIPTION INDUSTRIAL DRIVES LAPTOP SCIENCE THERMOCOUPLE TRIGONOMENTRY REFERENCE UART oscilloscope BIOMASS CONTACTOR ELECTRIC ILLUMINATION ELECTRICAL SAFETY TRAINING ELECTROMECHANICAL FEATURED FILTER DESIGN HARDWARE JUNCTION FIELD-EFFECT TRANSISTORS NASA NUCLEAR POWER VALVE COLOR CODES ELECTRIC TRACTION FLEXIBLE ELECTRONICS FLUKE GEARMOTORS INTRODUCTION LASSER PID PUMP SEAL ELECTRICIAN CAREER ELECTRICITY SUPPLY AND DISTRIBUTION MUSIC NEUTRAL PERIODIC TABLES OF THE ELEMENTS POLYPHASE AC CIRCUITS PROJECTS REATORS SATELLITE STAR DELTA VIBRATION WATERPROOF