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Continental Introduces LED Driving Lights for Off-Highway Use
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By Counterman
Rislone announced its new
link hidden, please login to view (p/n 4400), which it said improves oil performance to eliminate dry starts, reduce friction and wear, prevent oil breakdown and extend engine life. “Its concentrated formula delivers legendary Rislone Hy-per Lube performance in a compact, easy-to-use, and shelf-friendly bottle,” the company added. Hy-per Lube Engine Supplement is a premium additive blend formulated to work with all motor oils, including conventional, high-mileage, and synthetic, to make older, high-mileage, and high-performance engines run better and last longer than they would with oil alone, according to
link hidden, please login to view. It’s also suitable for use in manual transmissions, differentials and axles. Rislone said it previously offered the supplement in a one-quart bottle, making it easy to swap a quart of oil for a quart of Hy-per Lube at every oil change. Now that most consumers buy oil in larger jugs, Rislone added it took the opportunity to reduce the package size — and the price. Concentrating the formula enabled Rislone to package it in a 16.9 oz. bottle without diluting performance. The smaller bottle also reduces packaging waste and storage space.
“Adding Hy-per Lube Engine Supplement to petroleum or synthetic oils turns them into hyper-performance lubricants that deliver heavy-duty protection for all driving demands across a wide range of engine and vehicle types,” said Clay Parks, Rislone vice president of development. “In these days of high prices, we’re proud to have found a way to lower ours. Our concentrated formula saves consumers money at the counter and in years to come by helping their engines last longer.”
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By Counterman
link hidden, please login to viewannounced it is now offering Advantage automated series clutch and Cummins flywheel kits for the Eaton-Cummins Endurant automated manual transmission (AMT). The two will be sold in the same kit for the first time, according to Eaton. An
link hidden, please login to viewnews release announcing the product launch explained that a flywheel, which is the interface between the engine and clutch, is bolted to the engine and spins when in operation. The clutch cover, which is bolted to the flywheel, also spins, and the driven disc of the clutch engages against the flywheel, which over time can cause wear. “Today’s manufacturers recommend that flywheels should be replaced, rather than the previous practice of resurfacing worn flywheels,” said Leandro Girardi, director, aftermarket, Eaton’s Mobility Group. “This ensures the flywheel fits correctly to engage with the clutch, and prevents fault codes, excessive wear and vibrations.”
Eaton said its Advantage Automated clutch is the original equipment clutch used in the Endurant transmission.
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By GreenGears Auto Limited
The automotive industry is undergoing a profound transformation, driven by the synergistic forces of connectivity and autonomous driving. These technological advancements are poised to reshape the transportation landscape, promising safer, more efficient, and more accessible mobility solutions for individuals and societies alike.
Connectivity, the ability of vehicles to communicate with each other and their surroundings, is laying the foundation for intelligent transportation systems that can revolutionize the way we navigate our roads. Autonomous driving, on the other hand, envisions a future where vehicles can operate without human intervention, offering the potential for unprecedented levels of safety and convenience.
This in-depth exploration delves into the complexities of connectivity and autonomous driving, examining their underlying technologies, current progress, challenges, and the transformative impact they are expected to have on our world.
The Evolution of Connectivity: From Isolated Vehicles to Interconnected Networks
Historically, vehicles have been isolated entities on the road, relying solely on the driver's perception and decision-making. However, the advent of connectivity has transformed cars into sophisticated communication hubs, capable of gathering and exchanging vast amounts of data in real-time.
This transformation has been made possible by a convergence of technological advancements, including:
Sensor Technology: Vehicles are now equipped with a wide range of sensors, including cameras, radars, lidars, and ultrasonic sensors, that enable them to perceive their surroundings in detail. These sensors collect data about the vehicle's position, speed, proximity to other objects, and road conditions. Wireless Communication: Technologies like Dedicated Short-Range Communications (DSRC) and Cellular Vehicle-to-Everything (C-V2X) allow vehicles to communicate wirelessly with each other and with infrastructure elements like traffic lights and road signs. Cloud Computing and Data Analytics: The vast amounts of data generated by connected vehicles are processed and analyzed in the cloud, enabling real-time decision-making and the development of intelligent transportation systems. Types of Connectivity:
Connectivity in the automotive realm manifests in various forms, each with its own distinct benefits:
Vehicle-to-Vehicle (V2V) Communication: Enables direct communication between vehicles, allowing them to share information about their speed, location, and intended maneuvers. This creates a virtual awareness network, enhancing safety by alerting drivers to potential hazards and enabling cooperative driving behaviors.
Vehicle-to-Infrastructure (V2I) Communication: Facilitates communication between vehicles and roadside infrastructure, such as traffic lights, road signs, and toll booths. This allows for optimized traffic flow, reduced congestion, and improved safety through real-time information sharing.
Vehicle-to-Network (V2N) Communication: Connects vehicles to cloud-based services and applications, providing access to real-time traffic updates, navigation assistance, and other infotainment features.
Vehicle-to-Pedestrian (V2P) Communication: Enables vehicles to communicate with pedestrians and cyclists, particularly in urban environments. This can enhance safety for vulnerable road users by alerting them to the presence of vehicles and potential dangers.
Benefits of Connectivity:
The widespread adoption of connectivity has the potential to unlock numerous benefits for individuals, society, and the environment:
Enhanced Safety: By facilitating real-time data exchange and situational awareness, connectivity can help prevent accidents and reduce fatalities on the roads. Features like collision avoidance systems, lane departure warnings, and blind spot monitoring leverage connectivity to provide drivers with timely alerts and assistance.
Improved Traffic Flow: Connectivity enables intelligent transportation systems to optimize traffic flow by adjusting signal timings, providing real-time traffic information, and recommending alternative routes. This can lead to reduced congestion, shorter travel times, and improved fuel efficiency.
Enhanced Convenience and Comfort: Connected vehicles offer a plethora of features that enhance the driving experience, including:
Remote vehicle access and control In-car entertainment and infotainment systems Personalized navigation and route optimization Real-time vehicle diagnostics and maintenance alerts Over-the-air software updates Environmental Sustainability: By optimizing traffic flow and promoting fuel-efficient driving behaviors, connectivity can contribute to reducing greenhouse gas emissions and improving air quality.
The Path to Autonomous Driving: From Assisted to Fully Autonomous
Autonomous driving, often referred to as self-driving technology, aims to automate the driving experience entirely, freeing drivers from the need to control the vehicle. This technology is being developed in stages, with increasing levels of autonomy, as defined by the Society of Automotive Engineers (SAE):
Levels of Autonomous Driving
Level Description 0 No automation. The driver is fully in control of the vehicle at all times. 1 Driver assistance. The vehicle provides limited assistance with tasks such as steering or accelerating, but the driver remains primarily in control. 2 Partial automation. The vehicle can control both steering and acceleration/deceleration under certain conditions, but the driver must remain alert and ready to take control at any time. 3 Conditional automation. The vehicle can perform all driving tasks under specific conditions, but the driver may still need to intervene in certain situations. 4 High automation. The vehicle can perform all driving tasks under most conditions, and the driver may be able to disengage completely. 5 Full automation. The vehicle can perform all driving tasks under all conditions, and there is no need for a human driver. Key Technologies Enabling Autonomous Driving
The development of autonomous vehicles relies on a complex interplay of various technologies:
Sensor Fusion: Combines data from multiple sensors like cameras, radars, and lidars to create a comprehensive and accurate picture of the vehicle's surroundings. Artificial Intelligence (AI) and Machine Learning: Enables the vehicle to perceive, interpret, and respond to its environment in real-time, making decisions based on complex algorithms and learned patterns. High-Definition Mapping: Provides detailed maps of the environment, including road layouts, lane markings, traffic signs, and other relevant information. Vehicle Control Systems: Actuators and control systems enable the vehicle to execute commands from the autonomous driving system, such as steering, accelerating, braking, and changing lanes. Current State of Autonomous Driving
While fully autonomous vehicles (Level 5) remain a long-term goal, significant progress has been made in developing and deploying lower levels of autonomy.
Advanced Driver-Assistance Systems (ADAS): Features like adaptive cruise control, lane keeping assist, and automatic emergency braking 1 are becoming increasingly common in new vehicles, representing Level 1 and Level 2 autonomy. Robotaxis and Autonomous Shuttles: Several companies are testing and deploying autonomous vehicles in controlled environments, such as designated areas within cities or university campuses. These vehicles often operate at Level 4 autonomy, with limited human supervision. Commercial Applications: Autonomous trucks and delivery vehicles are being developed and tested for logistics and transportation applications, offering the potential for increased efficiency and reduced costs. Challenges and Concerns
Despite the significant progress, several challenges and concerns remain on the road to fully autonomous driving:
Technological Limitations: Current sensor technologies and AI algorithms still struggle to handle complex and unpredictable scenarios, such as adverse weather conditions, construction zones, or interactions with pedestrians and cyclists. Safety and Liability: Ensuring the safety of autonomous vehicles and determining liability in the event of accidents are critical concerns that need to be addressed through robust testing, validation, and regulatory frameworks. Public Acceptance: Gaining public trust and acceptance of autonomous vehicles will require addressing concerns about safety, job displacement, and the potential for misuse of the technology. Infrastructure: Widespread adoption of autonomous vehicles will necessitate significant investments in infrastructure, including intelligent transportation systems, high-definition maps, and communication networks. The Transformative Impact of Connectivity and Autonomous Driving
The convergence of connectivity and autonomous driving has the potential to revolutionize the transportation sector and society as a whole:
Improved Safety: By eliminating human error, which is a leading cause of accidents, autonomous vehicles have the potential to significantly reduce fatalities and injuries on the roads. Studies suggest that autonomous vehicles could reduce traffic fatalities by up to 90%.
Increased Efficiency: Connected and autonomous vehicles can optimize traffic flow, reduce congestion, and improve fuel efficiency. This can lead to significant time and cost savings for individuals and businesses, as well as a reduction in greenhouse gas emissions.
Enhanced Accessibility: Autonomous vehicles can provide mobility solutions for individuals who are unable to drive, such as the elderly or those with disabilities, enhancing their independence and quality of life.
New Business Models: The advent of autonomous vehicles could give rise to new business models and services, such as ride-hailing, car-sharing, and delivery fleets. These models could transform the way we think about transportation, making it more accessible and affordable for everyone.
Urban Transformation: Autonomous vehicles could lead to a redesign of urban spaces, with less need for parking lots and potentially more space for green areas and pedestrian zones.
The Road Ahead: Navigating the Challenges and Opportunities
The path to a fully connected and autonomous transportation future is filled with both challenges and opportunities. As technology continues to advance and regulatory frameworks evolve, we can expect to see a gradual but steady shift towards a more automated and interconnected transportation landscape.
The automotive industry, along with governments, technology companies, and other stakeholders, will need to collaborate to address the challenges and ensure the safe and responsible deployment of these technologies. Public education and engagement will also be crucial in building trust.
www.GreenGearsAuto.com
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By Counterman
link hidden, please login to view announced the release of 27 new numbers, all of which are in stock and ready to ship. The new numbers include: 8 Complete Strut Assemblies; 11 Suspension Struts; 2 Shock Absorber Assembly Kits; 4 Light Duty Shock Absorbers; and 2 heavy Duty Shock Absorbers.
link hidden, please login to view said the new numbers cover applications like the BMW 3 Series, Freightliner, Hyundai Sonata, Infiniti QX60, International Series Trucks, Land Rover, Peugeot, Volkswagen Jetta and more. The post
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