2002 Toyota Highlander Limited *leather *sunroof V6 on 2040-cars

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Toyota recalls power window switches for 6.5 million vehicles [UPDATE]

UPDATE: There was one incident of someone in the US getting a burn to the hand from this issue Toyota spokesperson Cindy Knight tells Autoblog that. "We have 11 reports where part of the door trim and/or switch was burnt," she said. The company isn't aware of any crashes from the problem, though. Because of a potential short circuit in the driver's side power window switch, Toyota is recalling 6.5 million vehicles worldwide, Reuters reports. Of those, the automaker says around 2 million are in the US. The affected models here are: 2007 and 2009 Camry and Camry Hybrid 2009-2011 Corolla 2008-2011 Highlander and Highlander Hybrid 2009-2011 Matrix 2006-2011 RAV4 2009-2011 Sequoia 2009-2011 Tundra 2006-2010 Yaris 2009-2011 Scion xB 2009-2010 Scion xD According to Toyota, the switch might not have received adequate lubricant grease during manufacturing, and over time this could lead to a short circuit. In a worst-case scenario, the part might even overheat, melt and cause a fire. As a fix, dealers will inspect the component on these vehicles and apply heat-resistant grease to it, and any broken examples will have an internal circuit board replaced. Toyota already issued one recall for this problem in 2012 when it had to repair 7.5 million vehicles globally from the 2007-2009 model years, including 2.5 million in the US. These latest models had the grease applied in a different way. Related Video: Toyota Recalls Certain Vehicles for Power Window Master Switch October 21, 2015 TORRANCE, Calif., Oct. 20, 2015 – Toyota Motor Sales, U.S.A., Inc. today announced that it is conducting a safety recall of approximately 2,000,000 vehicles related to the driver's side Power Window Master Switch. The involved vehicles include certain: 2007 and 2009 Camry and Camry Hybrid 2009-2011 Corolla 2008-2011 Highlander and Highlander Hybrid 2009-2011 Matrix 2006-2011 RAV4 2009-2011 Sequoia 2009-2011 Tundra 2006-2010 Yaris 2009-2011 Scion xB 2009-2010 Scion xD The Power Window Master Switch in the involved vehicles may have been manufactured with insufficient lubricant grease. If not enough grease is applied, under certain conditions the switch may develop a short circuit that can cause the switch assembly to overheat and melt. A melting switch can produce smoke and potentially lead to a fire. Toyota previously recalled certain 2007-2009 model year vehicles for a similar condition.

Toyota and Subaru file patents for performance FR-S and BRZ

People have longed for a more powerful version of the Subaru BRZ, Scion FR-S, and Toyota GT86 since the triplets arrived on the market. So far, neither partner in the deal has launched a model to fully satiate that hunger. However, the Japanese patent office recently approved documents from Toyota for the design of a vehicle that looks just like the Subaru STI Performance Concept (pictured above). According to AutoGuide, the filing also gives Fuji Heavy Industries credit for the design. The STI Performance Concept debuted at this year's New York Auto Show as an early step in STI's attempt to expand its reach here. The BRZ-derived coupe featured a body with a ground-scraping front bumper, tweaked headlights, wider fenders, a massive rear wing, and diffuser with a center-exit exhaust. All of these elements also show up on the patent renderings. The concept was just as exciting under the hood because STI installed a 2.0-liter, turbocharged boxer four-cylinder from its GT300 racer, and upgrades for the chassis, suspension, and brakes came from the Japanese market's BRZ tS. While the coupe made hearts race, the company was clear it didn't necessarily plan to build the model. Patent filings aren't a guarantee for production, and even if this one does arrive in showrooms, it might not come to the US. That's because Subaru and Toyota have a history of creating Japan-exclusive versions like the tS or Style Cb. That being said, spy shots have revealed a camouflaged GT86 testing in Europe, and rumors indicate more power from the engine. Subie's boss has even confirmed the existence of a partnership to create a next-gen model. Related Video:

How Toyota's 100-year textile history influenced FCV hydrogen fuel cell car

Turns out, Toyota had a surprising ace in the hole when it came to building the new fuel tanks for the FCV hydrogen fuel cell car, which is coming next year. Well before Toyota became the Toyota Motor Company, it was the Toyota Industries Corporation and it made textile looms. This is important because the main structure of the hydrogen tank is wound carbon fiber. When Toyota set out to increase the strength of the tanks to hold hydrogen stored at 10,000 psi (up from 5,000 in the previous tanks), it was able to draw on its 100-year-old history as it designed its car of the future. "A lot of that textile experience came back when we did the tank wrapping." – Justin Ward "We have a lot of experience with textiles," Justin Ward told AutoblogGreen at the 21st World Congress on Intelligent Transport Systems (ITS) in Detroit this week, "and a lot of that textile experience came back when we did the tank wrapping." On top of being able to hold the higher-pressure hydrogen, Toyota's first attempt to build its own hydrogen tank was six times faster than the industry standard, so it saved time and money as well as working better. The company will also be able to inspect its own tanks. Ward is the general manager of powertrain system control at the Toyota Technical Center and hydrogen vehicles are something he knows a lot about. The reason for the stronger, 10,000-psi tanks is because the 5,000-psi tanks only offered around 180-200 miles of range, even with four tanks in the early $129,000 FCHV Highlander hydrogen prototypes. The FCV only has two, but they will able to deliver the 300-mile range that customers told Toyota they wanted. Dropping the number of tanks not only obviously reduced the cost for the tanks themselves but also the number of valves and hoses and other components you need. Despite the benefits of higher compression, going much higher doesn't make sense. 10,000 psi is the "natural progression," Ward said, because "you start to bump up against compression inefficiencies." Think of an air compressor. When hydrogen is produced at a wastewater treatment plant or a reforming site, Ward said, is it at around ambient pressure (14 psi). That has to be raised, using compressors, all the way to 10,000 psi. "That takes energy," Ward said, "and every doubling of pressure adds another doubling of energy needed, so it starts to add up pretty fast if you go too high." Component specifications are also fine at 10,00 psi, but more difficult at higher levels.