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#16
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- John ASE certified Master Tech W/ X1 Twin City Fleet repair, St. Paul, MN need work done? Have tools will travel
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#17
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www.svxfiles.com The first SuperCharged SVX, the first 4.44 gears, the first equal length headers, the first phenolic spacers, the first Class Glass fiberglass hood, the first with 4, 4.44s in his driveway Fiberglass Hood thread My locker 4.44 Swap link |
#18
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what are the numbers???
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Former: 1994 Barcelona Red(x2), 1995 Brilliant Red, 1992 Liquid Silver, 1992 Ebony(x2), 1992 Pearl White (x2) Current: 2017 Ford Raptor 2017 Kawasaki KLR 1995 Guards Red Carrera 1995 Spec-ish Miata - track car 1957 CJ-5 |
#19
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Tkt
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This article is from turbomagazine Hard case cars are those sport compacts that fall through the cracks in the industry and consequently get zero love in the aftermarket. Nary a bolt-on to be had, these cars rely on the "universal" parts to conjure higher-flowing exhaust systems or intakes. Heck, most owners are lucky to find a good set of tuner wheels. A lot of these lost souls are out there and for those unfortunates who lust for boost, there's light at the end of the tunnel--the Thomas Knight Turbo electric supercharger. Designed as a universal supercharger, there are no ungodly pulley configurations or whacked-out axle drives to deal with. In fact, Thomas Knight Turbo (TKT) likens the installation to that of a high-flow intake. TKT says that for most FWD cars, relocating the battery to the trunk and swapping out the air filter opens up enough room to install the unit. The ESC-400 is the result of 26 years of effort. "I built my first ESC in 1978 while working at Turbo Tech, an FAA and industrial turbo repair station," says TKT's Geoff Knight. "A T11 turbo from a wrecked aircraft was being inspected to see if it caused the engine to fail and it was fine. The FAA never allows parts from any crashed plane to see air time again, so this perfect turbo was deemed un-air-worthy." So he bought it for $25--the core value. An old-time machinist showed Knight how to work the machines there, so he ground off the turbine blades and machined the cartridge for ball bearings. He pressed a 1.5-inch, two-groove pulley on the turbine end of the shaft and installed it into the turbo with the ball bearings. A friend who owned a starter/alternator shop helped him rewind several starters until they made one that produced 5-6 psi spinning 7000 rpm and drew 700 amps at 12V and 400 amps at 24V. Then he mounted a 6-inch, two-groove pulley on it and attached everything to a piece of plywood in the back of his '72 VW Beetle. Running two batteries in series, he routed a 2.5-inch pipe through the rear firewall. It made 6-7 psi at launch and 3 psi at redline. "The VW was fast," says Knight. "Belts flew off every run; no exception. V-belts don't like 30,000 rpm. I tried for years to do better." In the early '80s, Knight raced electric RC boats. He installed an Astro-Flight 25 plane motor in a 26-inch SK-daddle boat and ran 27 mph on 26 1.2V NiCads. He decided to try for the record--29 mph average for two laps. More batteries didn't help. Two motors and shafts added 3 mph, so he ran 30 mph with that setup. "I then tried three motors, and even four but nothing went faster. I was frustrated!" he remembers. Knight then raced 11-foot Hydros for a while and met one of the unlimited drivers at a race. He'd done something similar with model gas boats, so the subject moved to why Knight couldn't go faster. "Simple," he replied, "hydrodynamic drag--too much surface area from too many blades." So Knight eliminated all shafts except one, and ran three motors side-by-side with nylon gears connecting them. That made 35 mph on the first try. By then, the top guys were at 40 mph, so he gave up. Too little, too late. But this lesson eventually led to the production ESC. Through the years, Knight built about 200 different ESC prototypes, but he never had enough electrical power. In 1996 Knight looked into a 90-hp DC motor, but it was bigger than a car engine and weighed 1000 pounds. He decided to lower the engine size to a reasonable amount. Even a 2.0-liter engine making 15 psi at 8000 rpm required a 30-hp DC motor. Knight looked into smaller motors, which were still too big and heavy. "In 1998," says Knight, "I remembered the model boat multiple motors, and realized I may have a solution. Two or more motors; three or four. Why not?" So he applied for patents and researched motors. The 4kw brushless model plane motors were $1,000 each, and each supercharger unit cost $4,500 to make. He made one with three model motors drawing 3,500 watts each at 60 volts. This one used a centrifugal supercharger with gears, then belts, etc. Gears were parasitic, and belts were destroyed in a short time. Frustration set in again, and Knight built one with some 3kw starter motors. These field winding motors had a ton of torque, but grew hot quickly. After rewinding the starters to different levels, he reached 10,000 rpm and 5.0KW per motor. But the belts and other problems made these centrifugal units work only for someone who wouldn't object to replacing bearings and belts all the time. Knight was desperate. He'd just replaced 12 belts in a few days on the ESC and wasn't happy. He had a twin-rotor M62 at the shop with a bad nose drive, so he removed the bad nose drive from the Eaton and machined an adaptor to bolt it up. He was sure it would be a poor performer, but went ahead and bolted it into the car. "It was awesome!" Knight says. "Instant boost, with much faster response than the centrifugal design. Boost was higher at first with the curve going down on a linear path." Now Knight has patents pending on six different designs, and international patents as well. Two years of constant use on the Avenger test mule has proven the Eaton/electric to be indestructible. The Eaton lasts 158K as a belt-driven supercharger. As an ESC they should last 4 million miles. The electric motors have a 1000-hour life expectancy; at 400 seconds per day that's 24 years. If Thomas Knight Turbos has its way, being "on the juice" will soon have a whole new meaning. TKT has certainly performed the proper due diligence on this one and the ESC-400 has the look of a viable solution to those enthusiasts on the wrong side of the forced-induction fence. Time will tell if this technology catches on.
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Victor |
#20
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Granted the guy has had a lot of fun pissing into the wind. However he would have saved himself a lot of agro with a little objective consideration, investigation, and scientific appraisal of the power required and the prospects of success.
The existing belt drive via the alternator, simply is not up to transmitting the required power in any sort of reliable arrangement. "Time WILL tell" as is noted. This sort of endeavour does make fodder for reporters and he is rightly given credit for his fortitude. N.B. We have a member here knows exactly what is involved and it is here that real credit should be directed.
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Trevor, New Zealand. As a child, on cold mornings I gladly stood in cowpats to warm my bare feet, but I detest bull$hit! |
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