Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed Calculator

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Stopping Sight Distance

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✖Maximum Frictional Force is the optimum frictional force exerted on the vehicle due to its movement.ⓘ Maximum Frictional Force [F]			+10% -10%
✖Braking Distance is the distance travelled by the vehicle at the point where brake is applied to the point where it stops.ⓘ Braking Distance [l]			+10% -10%
✖Velocity is the rate of change of distance of the vehicle with respect to time.ⓘ Velocity [v_vehicle]			+10% -10%

✖Total Weight of Vehicle is the weight of a vehicle when it is totally loaded consisting weight of passengers, luggage, and other spare parts.ⓘ Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed [W]

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Formula

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Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed

Formula

`"W" = (2*"[g]"*"F"*"l")/"v"_{"vehicle"}^2`

Example

`"275.2492kg"=(2*"[g]"*"233N"*"48m")/("28.23m/s")^2`

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Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed Solution

STEP 0: Pre-Calculation Summary

Formula Used

Total Weight of Vehicle = (2*[g]*Maximum Frictional Force*Braking Distance)/Velocity^2
W = (2*[g]*F*l)/v_vehicle^2
This formula uses 1 Constants, 4 Variables

Constants Used

[g] - Gravitational acceleration on Earth Value Taken As 9.80665

Variables Used

Total Weight of Vehicle - (Measured in Kilogram) - Total Weight of Vehicle is the weight of a vehicle when it is totally loaded consisting weight of passengers, luggage, and other spare parts.
Maximum Frictional Force - (Measured in Newton) - Maximum Frictional Force is the optimum frictional force exerted on the vehicle due to its movement.
Braking Distance - (Measured in Meter) - Braking Distance is the distance travelled by the vehicle at the point where brake is applied to the point where it stops.
Velocity - (Measured in Meter per Second) - Velocity is the rate of change of distance of the vehicle with respect to time.

STEP 1: Convert Input(s) to Base Unit

Maximum Frictional Force: 233 Newton --> 233 Newton No Conversion Required
Braking Distance: 48 Meter --> 48 Meter No Conversion Required
Velocity: 28.23 Meter per Second --> 28.23 Meter per Second No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

W = (2*[g]*F*l)/v_vehicle^2 --> (2*[g]*233*48)/28.23^2

Evaluating ... ...

W = 275.249205045996

STEP 3: Convert Result to Output's Unit

275.249205045996 Kilogram --> No Conversion Required

FINAL ANSWER

275.249205045996 ≈ 275.2492 Kilogram <-- Total Weight of Vehicle

(Calculation completed in 00.004 seconds)

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University of Engineering and Management,Kolkata (UEMK), Kolkata

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< 12 Stopping Sight Distance Calculators

Reaction Time given Stopping Sight Distance and Vehicle Velocity

Go Reaction Time = (Sight Stopping Distance-(Vehicle Speed^2)/(2*[g]*Coefficient of Friction))/Vehicle Speed

Stopping Sight Distance given Vehicle Velocity and Reaction Time of Vehicle

Go Sight Stopping Distance = Vehicle Speed*Reaction Time+(Vehicle Speed^2)/(2*[g]*Coefficient of Friction)

Maximum Frictional Force Developed during Braking Operation of Vehicle

Go Maximum Frictional Force = (Total Weight of Vehicle*Velocity^2)/(2*[g]*Braking Distance)

Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed

Go Total Weight of Vehicle = (2*[g]*Maximum Frictional Force*Braking Distance)/Velocity^2

Velocity of Vehicle given Braking Distance after Braking Operation

Go Velocity = sqrt(2*[g]*Coefficient of Friction*Braking Distance)

Work Done against Friction in Stopping Vehicle

Go Work done against Friction = Coefficient of Friction*Total Weight of Vehicle*Braking Distance

Kinetic Energy of Vehicle at Design Speed

Go Kinetic Energy of Vehicle at Design Speed = (Total Weight of Vehicle*Velocity^2)/(2*[g])

Braking Distance of Vehicle during Braking Operation

Go Braking Distance = Velocity^2/(2*[g]*Coefficient of Friction)

Maximum Frictional Force given Kinetic Energy of Vehicle at Design Speed

Go Maximum Frictional Force = Kinetic Energy of Vehicle at Design Speed/Braking Distance

Stopping Sight Distance given Lag Distance and Braking Distance

Go Sight Stopping Distance = Lag Distance+Braking Distance

Lag Distance given Stopping Sight Distance and Braking Distance

Go Lag Distance = Sight Stopping Distance-Braking Distance

Braking Distance given Lag Distance and Stopping Sight Distance

Go Braking Distance = Sight Stopping Distance-Lag Distance

Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed Formula

Total Weight of Vehicle = (2*[g]*Maximum Frictional Force*Braking Distance)/Velocity^2
W = (2*[g]*F*l)/v_vehicle^2

What is gross weight of a vehicle?

The gross weight of a vehicle (GVW) is the weight of the empty vehicle plus the weight of the maximum payload that the vehicle was designed to carry.

How to Calculate Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed?

Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed calculator uses Total Weight of Vehicle = (2*[g]*Maximum Frictional Force*Braking Distance)/Velocity^2 to calculate the Total Weight of Vehicle, Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed is the weight of a vehicle when it is totally loaded consisting weight of passengers, luggage, and other spare parts. Total Weight of Vehicle is denoted by W symbol.

How to calculate Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed using this online calculator? To use this online calculator for Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed, enter Maximum Frictional Force (F), Braking Distance (l) & Velocity (v_vehicle) and hit the calculate button. Here is how the Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed calculation can be explained with given input values -> 945.6883 = (2*[g]*233*48)/28.23^2.

FAQ

What is Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed?

Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed is the weight of a vehicle when it is totally loaded consisting weight of passengers, luggage, and other spare parts and is represented as W = (2*[g]*F*l)/v_vehicle^2 or Total Weight of Vehicle = (2*[g]*Maximum Frictional Force*Braking Distance)/Velocity^2. Maximum Frictional Force is the optimum frictional force exerted on the vehicle due to its movement, Braking Distance is the distance travelled by the vehicle at the point where brake is applied to the point where it stops & Velocity is the rate of change of distance of the vehicle with respect to time.

How to calculate Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed?

Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed is the weight of a vehicle when it is totally loaded consisting weight of passengers, luggage, and other spare parts is calculated using Total Weight of Vehicle = (2*[g]*Maximum Frictional Force*Braking Distance)/Velocity^2. To calculate Weight of Vehicle given Kinetic Energy of Vehicle at Design Speed, you need Maximum Frictional Force (F), Braking Distance (l) & Velocity (v_vehicle). With our tool, you need to enter the respective value for Maximum Frictional Force, Braking Distance & Velocity and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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