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Has anyone seen this info online? Its good stuff thought it might be helpfull if anyone needs it, i no i did once and made the Pelican thread proud
What is a Torque Converter? Most automotive enthusiasts know that when they run an automatic transmission they must run a torque converter. They may even consider the converter part of the trans, although the two can be and often are purchased separately. Aeronautical Scientist define a torque converter as “a device for changing the torque speed to gain a mechanical advantage between an input shaft and an output shaft”. The goal for automotive enthusiasts and racers is to gain a maximum mechanical advantage. Automotive enthusiasts also know they can see performance gains in may cases when they change to a higher stall speed torque converter. However, even hard-core enthusiasts often have no idea how a torque converter actually works. After all, it arrives all sealed up. You can’t open it and inspect it, modify or maintain it. You just choose one, install it and hope you’ve made the right choice. Fortunately, torque converters don’t have to be mystery. We will explain what they do, how they do it and why you might want to changes yours. What does a Torque Converter Do? At most basic level, a torque converter connects the engine to the automatic transmission, much like a clutch connects and engine to a manual transmission. The converter housing bolts onto the motor’s flexplate (also known at the flywheel) and the housing spins right along with the motor’s crankshaft. On the output side, the torque converter’s turbine is attached to the transmission input shaft. Inside the torque converter is a stator assembly. Its job is to redirect the trans fluid flow, resulting in torque multiplication and torque multiplication is what allows a converter to provide better low speed acceleration. Most torque converters today will multiply torque by a ratio of at least 2 to 1. For example, if an engine is making 250 lbs.-ft. of torque and your converter is multiplying it by a factor of two, then the transmission will see 500 lbs.-ft. of torque. The torque converter also serves another extremely important function in a car or truck. A vehicle’s engine must be able to connect and disconnect from the differential, so the vehicle can stop moving (i.e., turning the drive wheels) while the engine is still running and the transmission is in gear. In the case of an automatic transmission, is it the torque converter that performs this connect/disconnect function (again, like a clutch in a manual trans. By slipping internally, the torque converter allows a car’s engine to idle while it’s in gear. What does ‘Stall Speed’ mean? Stall Speed is commonly referred to as the RPM speed at which the converter will hold back or limit the engine when the automotive transmission is prohibited. By not allowing the engine further RPM gain, the increase in engine RPM “stalls” or in other words, ceases to increase. The important thing for enthusiasts to remember is, that “stall” speed is a direct relationship between the engines ability to produce power and the torque converters ability to hold the RPM back. Changes to either the engines power output and/or the converter will change the balance and in turn will change the “stall” speed. The RPM at which stall occurs within a converter is a function of engine peak torque. This is why the same high stall converter will not “stall” the same when interchanged between two different engines, producing vastly different power outputs. What are Lockup Converters? Lockup converters contain another part; a torque converter clutch. When the clutch engages, it allows the converter to lock the engine to the transmission input shaft, providing a direct 1:1 connection from the motor to the transmission. Why is this necessary or even desirable? In many ways it comes down to fuel economy. Lockup torque converters have become popular since automakers have been stuck in a sort of Catch 22 type situation. Car buyers overwhelmingly prefer automatic transmissions but they’re not as fuel efficient as a manual transmission and car makers must meet average government mandated fuel economy targets. Overdrive transmissions have been one step along the path toward increased fuel efficiency from an automatic transmission equipped car. Overdrive transmissions allow the motor to turn at a lower RPM during cruising speeds. A higher final drive ratio (numerically lower) does the same thing. However, when the engine spins more slowly, it creates more slippage within the torque converter and more slippage creates more heat. Heat within the torque converter reduces fuel economy and can harm both the torque converter and the transmission. The Solution is for the converter to lock up at a 1:1 ratio. Lockup reduces the slippage, which helps eliminate heat and improves fuel economy. How do I choose the right converter? If your car has been modified to enhance performance, you’ll probably need a converter with a higher stall speed. Most stock converters have a stall speed within the 1500 RPM to 1800 RPM range. When you make performance modifications to your engine, you generally shift the engine’s torque curve upward into a higher RPM range. Therefore, you need a converter with a higher stall speed so that you can launch the car in the “fat” or proper part of the engine’s powerband. If the stall isn’t enough, the car won’t be making optimum power when you launch and you’ll bog the car off the line. If your car’s set up is really mismatched, the motor may even want to stall whenever you attempt to shift into gear at idle. A higher stall speed converter will improve acceleration without having an accurate and precise engine peak torque rating, it is better to conservatively estimate the engine torque rather than overestimate it. Generally speaking, the desired stall speed of a converter should be around 500 RPM-700 RPM below the engine RPM at peak torque. This allows a margin for application of torque reserve on take off. How much stall speed is too high? Obviously, you don’t want to launch the car at an RPM that is past your cars peak power output. There is no point in bypassing the engine’s powerband. You also have to consider the car’s weight, engine size, engine component combination, power output, intended use etc. when deciding which torque converter to use. Some converters are designed for high revving lightweight race cars and some are designed for heavy cars that make a lot of low RPM torque and there are converters designed for virtually everything in between. The key is to match the converter to the motor torque output and to the entire vehicle in question. This is where technical support staff can help. Be sure to choose a good converter shop to purchase your high stall converter. The knowledge and experience of the tech people will mean the difference between purchasing the right converter that is going to work for you or a converter that you’ll constantly be having problems with. Technical staff will ask you questions about the combination, including things like, where your engine makes it’s power, cam specification, your vehicle weight and so forth, in order to help find the right converter for your overall combination. You don’t want to get a higher stall speed than you need. That’s because high stall speeds create more slippage, which in turn generates more heat, which is hard on the converter and transmission. If you are going to run a converter with a higher than stock stall speed, you’ll want to install a transmission cooler to extend the lifetime of your components. Amazingly enough, 85% of transmission failures are due to excessive heat. Higher stall speed converters also generally are not available with a lockup clutch. Again, this means more slippage, more heat and less fuel economy, but the tradeoff may be more than worthwhile for high torque applications, since a higher stall speed can subsequently improve a vehicle’s responsiveness. Why is the stall speed in most stock vehicles so low compared to the 2000 plus RPM stall converters recommended for even mild performance vehicles? Most performance engines are modified to produce additional horsepower and torque. The engine’s torque curve is normally raised much higher in RPM range than stock before they begin to produce real power. The higher stall speed converters allow the engine RPM to enter the bottom range of the power curve and provide the optimum acceleration of the vehicle. If more stall speed is good, is a lot more stall better? More stall speed is only good of your engine’s torque curve matches it. Too much stall speed is as bad as using too little. Increasing stall speed increases heat in the transmission. Excessive unusable stall speed is therefore detrimental. A friend bought a converter that was supposedly a 2800RPM Stall, but he only got 2000 RPM out of it. Why is this? He may have an engine that’s incapable of providing 2800RPM-stall. Either the engine produces less actual torque than what he estimates for the engines power curve. It could be due to camshaft specs, the engine is set up to produce optimum power for a much higher RPM and is producing very little torque in the 2500 to 3000 RPM range. Many people attempt to check the stall speed by holding the brake and stepping on the gas with car in gear. This usually will not produce the true stall speed, as the brakes will not hold the engine and the types will start to spin first. The best indication of the true stall speed is to launch the car at wide-open throttle and note the engine RPM. Stall speed is very difficult to determine unless your cars transmission is equipped with a transmission brake to lock your drive train. Testing stall speed by holding the wheel brakes and running the engine against the locked brakes will usually result in wheel rotation before true stall speed is reached. The engine simply overpowers the ability of the brakes to hold the car. When rotation starts you are no longer at stall. For this reason people talk about brake stall, which is not a true stall. As mentioned earlier the alternative method of measurement is to launch the car at wide-open throttle and observe the engine RPM reached at launch. This is called flash stall. How does a camshaft change (lift, duration & lobe separation) effect my converter choice? The camshaft and converter are more closely tied than any other components in the car. If you chose a cam that produces power at higher RPM ranges, you must have a converter that coincides with that range. Engine output is what really determines stall speed for a given converter. This is particularly true when changing camshafts, heads, carburetor, installing turbos etc. All these will affect the stall speed of the converter. If you increase the available power output of your engine, the converter stall speed will be higher. This might be nowhere near the optimum stall speed for the engines configuration, to the point where the overall performance may not only remain unchanged but could actually suffer. This is where a lot of enthusiasts get caught out. They install a high stall converter, say a 2200 RPM stall speed and then over time, continue to modify their engine to produce more horsepower & torque, forgetting that their 2200 RPM converter is no longer suitably matched to the engines higher power & output. Is Stall speed the only consideration when selecting a high stall converter? While stall speed is very important, it is by no means the only consideration when selecting a high stall converter. Torque multiplication at launch and high-end efficiency are equally important. Stall speed can be attained in many ways that hurt the converter performance in other areas. Stall can be obtained at the expense of looseness at low speeds and loss of performance at higher speeds after launch. It’s best to have a converter that produces the right stall without sacrificing performance. If I buy a higher stall converter for my stock engine, will my car sit still while the RPM’s come up to the higher stall speed? No. A higher stall speed converter is simply less efficient at RPM’s below its intended stall speed. It will act quite normally for every day street use. Does stall Speed affect normal driving? Normal driving is not affected by stall speed up to approximately 3000 RPM, particularly with a well built converter. A car will begin to roll normally when a higher stall speed converter used. Quick acceleration will be favorably influenced by stall speed. A very high stall speed (above 3000 RPM) would not be satisfactory for every day street use. How can I be sure that the converter I am buying is a genuine Accelerator High Stall Converter? Accelerator stamps each specific converter with an alphanumerical code, which tells us what components have been used to build the converter and for what application it was intended. Accelerator – The people, Technical Service & Product Support? The owners and technicians at Accelerator High Stall Converters reflect many years of hard earned experience. All of the team have unique backgrounds and put a premium on performance. The expertise and racing experience of the team allows each person to be active in developing and supplying products, demanded by performance and racing enthusiasts. The experience is focused to bring you the customer, the best products the industry can offer. The technical department consists of professionals in the transmission, converter, performance engine building & drag racing industries. They are able to best advise you on the right stall speed converter for your application.
_________________ Now, I've got a message for all the other drivers out there. If you smell a delicious, crispy smell after the race, it's not your tailpipe. It's just a little of Shake...and Bake! |
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ford-racer46 |
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Just by the way this isnt my work! just a cut and copy for people who need it on FORDMODS!
_________________ Now, I've got a message for all the other drivers out there. If you smell a delicious, crispy smell after the race, it's not your tailpipe. It's just a little of Shake...and Bake! |
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