IRJET- Design and Development of Kinetic Energy Recovery System (KERS) for Utilization of Waste Energy and Electromechanical Speed Governor for Road-Lane Safety
The document describes the design and development of a Kinetic Energy Recovery System (KERS) and an electromechanical speed governor for road safety. It aims to more efficiently recover and store kinetic energy lost during braking compared to existing systems, which involve multiple inefficient conversions between mechanical and electrical energy. The proposed system uses a planetary gear train and dedicated disk brake to directly convert and store lost kinetic energy in a spiral spring as mechanical energy. It is intended to be integrated with an electromechanical speed governor to automatically activate the KERS and slow vehicles that exceed the speed limit, while still recovering kinetic energy. The system is analyzed through experimental testing and found to increase energy recovery with higher speeds.
Design and Fabrication of Regenerative Braking in EVvivatechijri
Charging has always been an issue in electrical vehicles. In this project, the kinetic energy is
transmitted in the brakes through drive train and is directed by a mechanical system to the potential store during
deceleration. That energy is held until required to the vehicle, wherein it is transformed back into energy and
stored in the battery of the vehicle. The amount of the power available for conservation varies depending on the
type of storage, drivetrain efficiency, and drive cycle and inertia weight. When a normal vehicle applies its brake,
its kinetic energy is transformed to heat because of friction between wheels and brake pad. This heat passes
through the air and the energy is wasted. The total energy lost in this way depends on how often, long and hard
the brake is being applied. An energy conversion action in which a part of the energy of the vehicle is stored by a
battery or storage device is known as regenerative braking. Driving within a city involves more braking
representing a high loss of energy with the opportunity for savings in energy. In the case of public transport
vehicles such as local trains, buses, taxis, delivery vehicles there is even more potential for energy to be
regenerated
Regenerative Braking System
Regenerative braking is a way of taking the wasted energy from the process of slowing down a car and using it to recharge the car's batteries.
Introduction
Literature Review
Recent Research And
Development In Hess
Case Study
Regenerative Braking System In
Bus
Regenerative Braking
System In Railways
Conclusion
Future Scope
References
A kinetic energy recovery system (often known simply as KERS, or kers) is an automotive system for recovering a moving vehicle's kinetic energy under braking. The recovered energy is stored in a reservoir (for example a flywheel or high voltage batteries) for later use under acceleration
These slides use concepts from my (Jeff Funk) course entitled analyzing hi-tech opportunities to analyze how the economic feasibility of kinetic energy recovery systems is slowly becoming better through improvements in batteries, hydraulic pumps, and flywheels. Many of these systems are currently used in Formula 1 race cars because they enable these cars to achieve higher acceleration and longer times between pit stops. For consumers, flywheels may become the energy storage technology of choice for vehicles particularly as improvements in carbon nanotubes and graphene occur.
The rates of improvement for energy and power storage densities for batteries have been very slow and those of flywheels have been much faster. One of the reasons for the rapid improvements in the densities for flywheels is that improvements in the strength per weight of materials have enabled faster rotations and the storage densities are a function of rotation velocities squared. As shown in the slides, carbon fiber has about four times the strength to weight ratio and seven times the energy density of glass. Since carbon nanotubes have strength to weight ratios 15 times higher and graphene has ones 30 times higher than do carbon fiber, energy storage densities of 120,000 kJ/kg or 33.6 kWh are possible with graphene. This energy density is about 100 times higher than is currently available from lithium-ion batteries.
Design and Fabrication of Regenerative Braking in EVvivatechijri
Charging has always been an issue in electrical vehicles. In this project, the kinetic energy is
transmitted in the brakes through drive train and is directed by a mechanical system to the potential store during
deceleration. That energy is held until required to the vehicle, wherein it is transformed back into energy and
stored in the battery of the vehicle. The amount of the power available for conservation varies depending on the
type of storage, drivetrain efficiency, and drive cycle and inertia weight. When a normal vehicle applies its brake,
its kinetic energy is transformed to heat because of friction between wheels and brake pad. This heat passes
through the air and the energy is wasted. The total energy lost in this way depends on how often, long and hard
the brake is being applied. An energy conversion action in which a part of the energy of the vehicle is stored by a
battery or storage device is known as regenerative braking. Driving within a city involves more braking
representing a high loss of energy with the opportunity for savings in energy. In the case of public transport
vehicles such as local trains, buses, taxis, delivery vehicles there is even more potential for energy to be
regenerated
Regenerative Braking System
Regenerative braking is a way of taking the wasted energy from the process of slowing down a car and using it to recharge the car's batteries.
Introduction
Literature Review
Recent Research And
Development In Hess
Case Study
Regenerative Braking System In
Bus
Regenerative Braking
System In Railways
Conclusion
Future Scope
References
A kinetic energy recovery system (often known simply as KERS, or kers) is an automotive system for recovering a moving vehicle's kinetic energy under braking. The recovered energy is stored in a reservoir (for example a flywheel or high voltage batteries) for later use under acceleration
These slides use concepts from my (Jeff Funk) course entitled analyzing hi-tech opportunities to analyze how the economic feasibility of kinetic energy recovery systems is slowly becoming better through improvements in batteries, hydraulic pumps, and flywheels. Many of these systems are currently used in Formula 1 race cars because they enable these cars to achieve higher acceleration and longer times between pit stops. For consumers, flywheels may become the energy storage technology of choice for vehicles particularly as improvements in carbon nanotubes and graphene occur.
The rates of improvement for energy and power storage densities for batteries have been very slow and those of flywheels have been much faster. One of the reasons for the rapid improvements in the densities for flywheels is that improvements in the strength per weight of materials have enabled faster rotations and the storage densities are a function of rotation velocities squared. As shown in the slides, carbon fiber has about four times the strength to weight ratio and seven times the energy density of glass. Since carbon nanotubes have strength to weight ratios 15 times higher and graphene has ones 30 times higher than do carbon fiber, energy storage densities of 120,000 kJ/kg or 33.6 kWh are possible with graphene. This energy density is about 100 times higher than is currently available from lithium-ion batteries.
Conventional Braking System
Introduction OfRegenerative Braking System
Necessity Of The System
Elements Of Regenerative Braking System
Different Types Of Regenerative Braking System
Advantages And Disadvantages
Research Papers
Conclusion
Future Scope
References
Energy Management System in Electric Vehicle with PV Fed SRM SystemIJMTST Journal
This project presents the switched reluctance motor (SRM) with hybrid renewable system. Switched
Reluctance Motors (SRM) has a wide range of industrial applications because of their advantages over
conventional AC/DC Drives. This is due to simple construction, ruggedness and inexpensive manufacturing
potential. Various methods have used and applied to control SRM speed generally, the PV-fed EV has a
similar structure to the hybrid electrical vehicle, whose internal combustion engine(ICE) is replaced by the
hybrid system. A hybrid energy system, or hybrid power, usually consists of two or more renewable energy
sources used together to provide increased system efficiency as well as greater balance in energy supply.
The PV has different characteristics to ICEs, the maximum power point tracking (MPPT) and solar energy
utilization are the unique factors for the PV-fed EVs. This matter is done by applying the proposed system to
a multi-objective function including both speed error and torque ripple. This controller is implemented for an
8/6, 4-kW SRM. In this paper to coordinate the PV panel, SRM and battery. Hybrid renewables applied in
Energy storage like battery technologies, superconducting magnetic energy, capacitors, compressed air and
pumped storage, seems to be an alternative method that the operator of an electrical power grid can use to
adapt energy production to energy consumption, both of which can vary randomly over time. The simulation
results confirm excellent dynamic performance, reduced torque ripple and current oscillation can be achieved
by using ANFIS
Electric motor drive systems (EMDS) have been recognized as one of the most promising motor systems recently due to their low energy consumption and reduced emissions. With only some exceptions, EMDS are the main source for the provision of mechanical energy in industry and accounts for about 60% of global industrial electricity consumption. Large energy efficiency potentials have been identified in EMDS with very short payback time and high-cost effectiveness. Typical, during operation at rated mode, the motor drive able to hold its good efficiencies. However, a motor usually operates out from rated mode in many applications, especially while under light load, it reduced the motor’s efficiency severely. Hence, it is necessary that a conventional drive system to embed with loss minimization strategy to optimize the drive system efficiency over all operation range. Conventionally, the flux value is keeping constantly over the range of operation, where it should be highlighted that for any operating point, the losses could be minimize with the proper adjustment of the flux level to a suitable value at that point. Hence, with the intention to generate an adaptive flux level corresponding to any operating point, especially at light load condition, an online learning Artificial Neural Network (ANN) controller was proposed in this study, to minimize the system losses. The entire proposed strategic drive system would be verified under the MATLAB/Simulink software environment. It is expected that with the proposed online learning Artificial Neural Network controller efficiency optimization algorithm can achieve better energy saving compared with traditional blended strategies.
A COMPARATIVE STUDY AND ANALYSIS OF THE PERFORMANCE OF VARIOUS REGENERATIVE B...IAEME Publication
Regenerative Braking System (RBS) converts a part of the vehicle’s kinetic energy into a useful form of energy. Thus the fuel requirements and the level of pollutant sexhausted by thevehicle are reduced,and canbecontrolled.VariousRegenerativeBrakingSystems include Mechanical Flywheel RBS, Elastomeric Flywheel RBS,
Hydraulic Power-Assist RBS, Ultra capacitor RBS, etc. In this paper, a typicalmathematical analysis of the performance of Mechanicalflywheel RBS, ElastomericFlywheel RBS, and Hydraulic Power-Assist RBS has been studied on different carmodels based on current research, and a comparison of the efficiencies and fuelsavings by these systems has been done taking into consideration, a basic Volvo car
model. Analysis shows the efficiencies of Elastomeric Flywheel RBS, HydraulicPower-Assist RBS, and Mechanical Flywheel RBS will be in adescending order
regenerative breaking is energy conversion method .by using conventional braking more energy is lossed in the form of heat by using this we can convert this energy into usefull forms
I've found this one here, but it was't goodlooking. So i've made some work on it and share with all of you.
Enjoy it and use it for simple engineering or technology presentations for your English lessons.
In this paper, the regenerative braking system (RBS) is implemented in the hybrid vehicle which is made to run using internal combustion engine and batteries. A regenerative brake is an apparatus, a device or a system which allows the vehicle to recapture and store some part of the kinetic energy that would be 'lost' as heat during applying brake. The total amount of energy lost in this way depends on how many times, how hard and for how long the brakes are applied. Energy lost during braking in this hybrid vehicle is used to recharge the battery. Since regenerative braking results in an additional increase in energy output for a given energy input to a vehicle, the efficiency is improved. It is used to improve the overall efficiency of the vehicle by 25% using RBS. The dynamo is fixed on the rear wheel of the vehicle which is beneficial in two ways, one that it helps to covert the kinetic energy into electrical energy and other that it controls the friction produced inside the wheel which in turn increases the life time of brake pads. Fixed at clearance angle using weld it shifts from wheel hub to wheel rim while application of brake giving more effectiveness to the vehicle.
Conventional Braking System
Introduction OfRegenerative Braking System
Necessity Of The System
Elements Of Regenerative Braking System
Different Types Of Regenerative Braking System
Advantages And Disadvantages
Research Papers
Conclusion
Future Scope
References
Energy Management System in Electric Vehicle with PV Fed SRM SystemIJMTST Journal
This project presents the switched reluctance motor (SRM) with hybrid renewable system. Switched
Reluctance Motors (SRM) has a wide range of industrial applications because of their advantages over
conventional AC/DC Drives. This is due to simple construction, ruggedness and inexpensive manufacturing
potential. Various methods have used and applied to control SRM speed generally, the PV-fed EV has a
similar structure to the hybrid electrical vehicle, whose internal combustion engine(ICE) is replaced by the
hybrid system. A hybrid energy system, or hybrid power, usually consists of two or more renewable energy
sources used together to provide increased system efficiency as well as greater balance in energy supply.
The PV has different characteristics to ICEs, the maximum power point tracking (MPPT) and solar energy
utilization are the unique factors for the PV-fed EVs. This matter is done by applying the proposed system to
a multi-objective function including both speed error and torque ripple. This controller is implemented for an
8/6, 4-kW SRM. In this paper to coordinate the PV panel, SRM and battery. Hybrid renewables applied in
Energy storage like battery technologies, superconducting magnetic energy, capacitors, compressed air and
pumped storage, seems to be an alternative method that the operator of an electrical power grid can use to
adapt energy production to energy consumption, both of which can vary randomly over time. The simulation
results confirm excellent dynamic performance, reduced torque ripple and current oscillation can be achieved
by using ANFIS
Electric motor drive systems (EMDS) have been recognized as one of the most promising motor systems recently due to their low energy consumption and reduced emissions. With only some exceptions, EMDS are the main source for the provision of mechanical energy in industry and accounts for about 60% of global industrial electricity consumption. Large energy efficiency potentials have been identified in EMDS with very short payback time and high-cost effectiveness. Typical, during operation at rated mode, the motor drive able to hold its good efficiencies. However, a motor usually operates out from rated mode in many applications, especially while under light load, it reduced the motor’s efficiency severely. Hence, it is necessary that a conventional drive system to embed with loss minimization strategy to optimize the drive system efficiency over all operation range. Conventionally, the flux value is keeping constantly over the range of operation, where it should be highlighted that for any operating point, the losses could be minimize with the proper adjustment of the flux level to a suitable value at that point. Hence, with the intention to generate an adaptive flux level corresponding to any operating point, especially at light load condition, an online learning Artificial Neural Network (ANN) controller was proposed in this study, to minimize the system losses. The entire proposed strategic drive system would be verified under the MATLAB/Simulink software environment. It is expected that with the proposed online learning Artificial Neural Network controller efficiency optimization algorithm can achieve better energy saving compared with traditional blended strategies.
A COMPARATIVE STUDY AND ANALYSIS OF THE PERFORMANCE OF VARIOUS REGENERATIVE B...IAEME Publication
Regenerative Braking System (RBS) converts a part of the vehicle’s kinetic energy into a useful form of energy. Thus the fuel requirements and the level of pollutant sexhausted by thevehicle are reduced,and canbecontrolled.VariousRegenerativeBrakingSystems include Mechanical Flywheel RBS, Elastomeric Flywheel RBS,
Hydraulic Power-Assist RBS, Ultra capacitor RBS, etc. In this paper, a typicalmathematical analysis of the performance of Mechanicalflywheel RBS, ElastomericFlywheel RBS, and Hydraulic Power-Assist RBS has been studied on different carmodels based on current research, and a comparison of the efficiencies and fuelsavings by these systems has been done taking into consideration, a basic Volvo car
model. Analysis shows the efficiencies of Elastomeric Flywheel RBS, HydraulicPower-Assist RBS, and Mechanical Flywheel RBS will be in adescending order
regenerative breaking is energy conversion method .by using conventional braking more energy is lossed in the form of heat by using this we can convert this energy into usefull forms
I've found this one here, but it was't goodlooking. So i've made some work on it and share with all of you.
Enjoy it and use it for simple engineering or technology presentations for your English lessons.
In this paper, the regenerative braking system (RBS) is implemented in the hybrid vehicle which is made to run using internal combustion engine and batteries. A regenerative brake is an apparatus, a device or a system which allows the vehicle to recapture and store some part of the kinetic energy that would be 'lost' as heat during applying brake. The total amount of energy lost in this way depends on how many times, how hard and for how long the brakes are applied. Energy lost during braking in this hybrid vehicle is used to recharge the battery. Since regenerative braking results in an additional increase in energy output for a given energy input to a vehicle, the efficiency is improved. It is used to improve the overall efficiency of the vehicle by 25% using RBS. The dynamo is fixed on the rear wheel of the vehicle which is beneficial in two ways, one that it helps to covert the kinetic energy into electrical energy and other that it controls the friction produced inside the wheel which in turn increases the life time of brake pads. Fixed at clearance angle using weld it shifts from wheel hub to wheel rim while application of brake giving more effectiveness to the vehicle.
FABRICATION AND ANALYSIS OF REGENERATIVE BRAKING SYSTEM
Similar to IRJET- Design and Development of Kinetic Energy Recovery System (KERS) for Utilization of Waste Energy and Electromechanical Speed Governor for Road-Lane Safety
Regenerative braking system is a small, but an eventual method for converting unwanted heat energy into electrical energy. The energy generated is stored in the battery. This helps in reducing the usage of the external battery for charging purposes. These types of brakes helps in increasing the driving range for the electric vehicles as they can travel for longer periods. Regenerative braking system also in improving the fuel economy. It is a way of increasing the efficiency rate of the vehicles. Instead, of converting the kinhetic energy into thermal energy through friction braking this system can convert a good fraction of kinetic energy into electric energy and charge the battey using the principle of alternator. Mr. Shivam Sharma | Ashish Narayan Singh | Rahul Yadav | Abhinav Jha | Kumar Vanshaj | Md. Fahim ""Regenerative Braking System"" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-4 , June 2019, URL: https://www.ijtsrd.com/papers/ijtsrd23546.pdf
Paper URL: https://www.ijtsrd.com/engineering/mechanical-engineering/23546/regenerative-braking-system/mr-shivam-sharma
A Case Study on Hybrid Electric Vehicles.pdfbagulibibidh
A Hybrid Electric Vehicle (HEV) is a modern combination of an internal combustion
engine (ICE) and an electric propulsion system (hybrid drivetrain). The electric
powertrain is used in an HEV to achieve better fuel economy than a conventional
vehicle for better performance. HEVs can be classified according to powertrain,
hybridization, and Energy Management Systems (EMS). Modern HEVs use energy-
efficiency technologies such as regenerative braking that converts the vehicles kinetic
energy into electric energy that is stored in battery or supercapacitors. The battery is
connected to an ECU (Electronic Control Unit) and a BMS (Battery Management
System). To maintain the cooling of the engine and BMS it is connected to a coolant.
In this case study we are going to study about the following things in an HEV :-
1. Hybrid Electric Vehicle (HEV) subsystems
2. Toyota Prius Powertrain
3. Transmission system in HEV
4. Use of Brushless DC Motor (BLDC) and Permanent Magnet Synchronous Motor
(PMSM)
5. The steering system
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7. Suspension system with construction, working, type and necessity
Similar to IRJET- Design and Development of Kinetic Energy Recovery System (KERS) for Utilization of Waste Energy and Electromechanical Speed Governor for Road-Lane Safety (20)
Automobile Management System Project Report.pdfKamal Acharya
The proposed project is developed to manage the automobile in the automobile dealer company. The main module in this project is login, automobile management, customer management, sales, complaints and reports. The first module is the login. The automobile showroom owner should login to the project for usage. The username and password are verified and if it is correct, next form opens. If the username and password are not correct, it shows the error message.
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This paper addresses the vulnerability of deep learning models, particularly convolutional neural networks
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Discover the different forklift classes and their specific applications. Learn how to choose the right forklift for your needs to ensure safety, efficiency, and compliance in your operations.
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The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
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IRJET- Design and Development of Kinetic Energy Recovery System (KERS) for Utilization of Waste Energy and Electromechanical Speed Governor for Road-Lane Safety