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In the UK, the typical total stopping distances (thinking distance plus braking distance) used in The Highway Code are quoted in Rule 126 as: [24] 20 mph: 40 feet (12 metres) 30 mph: 75 feet (23 metres) 40 mph: 118 feet (36 metres) 50 mph: 175 feet (53 metres) 60 mph: 240 feet (73 metres) 70 mph: 315 feet (96 metres)
With power typically being the product of force and speed, a motorcycle's power and torque ratings will be highly indicative of its performance. Reported numbers for power and torque may however vary from one source to another due to inconsistencies in how testing equipment is calibrated, the method of using that equipment, the conditions during the test, and particularly the location that ...
The Suzuki SV650 and its variants are street motorcycles manufactured since 1999 ... Braking distance from 60 mph (97 km/h) 36.08 m ... review; Suzuki SV650 (2016-on ...
Motorcycle USA measured acceleration from 0-60 mph in 4.9 seconds and 0 to 1 ⁄ 4 mi (0.00 to 0.40 km) in 14.21 seconds for 2015 model. Braking distance was measured at 148.2 feet from 60-0 mph with ABS disabled and 151.7 feet without ABS disabled. [34]
d MT = braking distance, m (ft) V = design speed, km/h (mph) a = deceleration rate, m/s 2 (ft/s 2) Actual braking distances are affected by the vehicle type and condition, the incline of the road, the available traction, and numerous other factors. A deceleration rate of 3.4 m/s 2 (11.2 ft/s 2) is used to determine stopping sight distance. [6]
Cycle ' s testers were surprised that despite an uncomfortable feel and slight front wheel hop under hard braking and not giving the sensation of stopping particularly fast, it had the shortest stopping distance and highest braking G load of all the bikes, winning best in class measured by stopping power from 60 mph. [18] On the road course ...
Motorcycle braking systems have varied throughout time, as motorcycles evolved from bicycles with an engine attached, to the 220 mph (350 km/h) prototype motorcycles seen racing in MotoGP. Most systems work by converting kinetic energy into thermal energy (heat) by friction.
These sensors calculate variables such as speed, acceleration, yaw rate, and steering angle. [16] CBC then uses these variables to adjust brake pressure, desired yaw rate, brake steer torque, and stopping distance. Experimentation with CBC technology has used Hardware-in-the-Loop (HiL) testing to prove its real-time response to these factors ...