Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly Solution

STEP 0: Pre-Calculation Summary
Formula Used
Total Energy of Brake = Temperature Change of Brake Assembly*Mass of Brake Assembly*Specific Heat of Brake Drum
E = ΔT*m*c
This formula uses 4 Variables
Variables Used
Total Energy of Brake - (Measured in Joule) - Total Energy of brake is the sum total of the energy absorbed by the braking system.
Temperature Change of Brake Assembly - (Measured in Kelvin) - Temperature Change of Brake Assembly is the degree by which the temperature of the brake assembly changes during operation.
Mass of Brake Assembly - (Measured in Kilogram) - Mass of Brake Assembly is defined as the summation of mass of all the objects present in the system on which brakes are applied.
Specific Heat of Brake Drum - (Measured in Joule per Kilogram per K) - Specific Heat of Brake Drum is defined as the specific heat of the whole assembly of the brake drum.
STEP 1: Convert Input(s) to Base Unit
Temperature Change of Brake Assembly: 12 Degree Celsius --> 12 Kelvin (Check conversion here)
Mass of Brake Assembly: 1130 Kilogram --> 1130 Kilogram No Conversion Required
Specific Heat of Brake Drum: 320 Joule per Kilogram per Celcius --> 320 Joule per Kilogram per K (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
E = ΔT*m*c --> 12*1130*320
Evaluating ... ...
E = 4339200
STEP 3: Convert Result to Output's Unit
4339200 Joule --> No Conversion Required
FINAL ANSWER
4339200 4.3E+6 Joule <-- Total Energy of Brake
(Calculation completed in 00.020 seconds)

Credits

Created by Kethavath Srinath
Osmania University (OU), Hyderabad
Kethavath Srinath has created this Calculator and 1000+ more calculators!
Verified by Urvi Rathod
Vishwakarma Government Engineering College (VGEC), Ahmedabad
Urvi Rathod has verified this Calculator and 1900+ more calculators!

19 Energy and Thermal Equation Calculators

Radius of Gyration given Kinetic Energy of Rotating Body
Go Radius of Gyration of braked system = sqrt(2*Kinetic energy absorbed by brake/(Mass of Brake Assembly*((Initial angular velocity of braked system^2)-(Final angular velocity of braked system^2))))
Mass of System given Kinetic Energy of Rotating Body
Go Mass of Brake Assembly = 2*Kinetic energy absorbed by brake/((Initial angular velocity of braked system^2-Final angular velocity of braked system^2)*Radius of Gyration of braked system^2)
Initial Angular Velocity of Body given Kinetic Energy of Rotating Body
Go Initial angular velocity of braked system = sqrt((2*Kinetic energy absorbed by brake/Moment of Inertia of braked assembly)+Final angular velocity of braked system^2)
Final Angular Velocity of Body given Kinetic Energy of Rotating Body
Go Final angular velocity of braked system = sqrt(Initial angular velocity of braked system^2-(2*Kinetic energy absorbed by brake/Moment of Inertia of braked assembly))
Moment of Inertia of System given Kinetic Energy of Rotating Body
Go Moment of Inertia of braked assembly = 2*Kinetic energy absorbed by brake/(Initial angular velocity of braked system^2-Final angular velocity of braked system^2)
Kinetic energy of Rotating Body
Go Kinetic energy absorbed by brake = Moment of Inertia of braked assembly*(Initial angular velocity of braked system^2-Final angular velocity of braked system^2)/2
Initial Velocity of System given Kinetic Energy Absorbed by Brakes
Go Initial velocity before braking = sqrt((2*Kinetic energy absorbed by brake/Mass of Brake Assembly)+Final velocity after braking^2)
Final Velocity given Kinetic Energy Absorbed by Brakes
Go Final velocity after braking = sqrt(Initial velocity before braking^2-(2*Kinetic energy absorbed by brake/Mass of Brake Assembly))
Mass of System given Kinetic Energy Absorbed by Brakes
Go Mass of Brake Assembly = 2*Kinetic energy absorbed by brake/(Initial velocity before braking^2-Final velocity after braking^2)
Kinetic Energy Absorbed by Brake
Go Kinetic energy absorbed by brake = Mass of Brake Assembly*(Initial velocity before braking^2-Final velocity after braking^2)/2
Mass of System given Potential Energy Absorbed during Braking Period
Go Mass of Brake Assembly = Potential energy absorbed during braking/(Acceleration due to Gravity*Change in height of vehicle)
Potential Energy Absorbed during Braking Period
Go Potential energy absorbed during braking = Mass of Brake Assembly*Acceleration due to Gravity*Change in height of vehicle
Specific Heat of Brake Drum Material given Temperature Rise of Brake Drum Assembly
Go Specific Heat of Brake Drum = Total Energy of Brake/(Mass of Brake Assembly*Temperature Change of Brake Assembly)
Mass of Brake Drum Assembly given Temperature Rise of Brake Drum Assembly
Go Mass of Brake Assembly = Total Energy of Brake/(Temperature Change of Brake Assembly*Specific Heat of Brake Drum)
Temperature Rise of Brake Drum Assembly
Go Temperature Change of Brake Assembly = Total Energy of Brake/(Mass of Brake Assembly*Specific Heat of Brake Drum)
Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly
Go Total Energy of Brake = Temperature Change of Brake Assembly*Mass of Brake Assembly*Specific Heat of Brake Drum
Brake Drum Rotational Angle given Work Done by Brake
Go Angle of rotation of brake disc = Kinetic energy absorbed by brake/Braking Torque on System
Braking Torque given Work Done by Brake
Go Braking Torque on System = Kinetic energy absorbed by brake/Angle of rotation of brake disc
Total Energy Absorbed by Brake
Go Kinetic energy absorbed by brake = Braking Torque on System*Angle of rotation of brake disc

Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly Formula

Total Energy of Brake = Temperature Change of Brake Assembly*Mass of Brake Assembly*Specific Heat of Brake Drum
E = ΔT*m*c

The Temperature rise is due to?

The temperature rise depends upon the mass of the brake drum assembly, the ratio of the braking period to the rest period, and the specific heat of the material. For peak short-time requirements, it is assumed that all the heat generated during the braking period is absorbed by the brake drum assembly.

How to Calculate Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly?

Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly calculator uses Total Energy of Brake = Temperature Change of Brake Assembly*Mass of Brake Assembly*Specific Heat of Brake Drum to calculate the Total Energy of Brake, The Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly formula is defined as the energy which is being applied by the brakes when the brakes are applied. Total Energy of Brake is denoted by E symbol.

How to calculate Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly using this online calculator? To use this online calculator for Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly, enter Temperature Change of Brake Assembly (ΔT), Mass of Brake Assembly (m) & Specific Heat of Brake Drum (c) and hit the calculate button. Here is how the Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly calculation can be explained with given input values -> 4.3E+6 = 12*1130*320.

FAQ

What is Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly?
The Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly formula is defined as the energy which is being applied by the brakes when the brakes are applied and is represented as E = ΔT*m*c or Total Energy of Brake = Temperature Change of Brake Assembly*Mass of Brake Assembly*Specific Heat of Brake Drum. Temperature Change of Brake Assembly is the degree by which the temperature of the brake assembly changes during operation, Mass of Brake Assembly is defined as the summation of mass of all the objects present in the system on which brakes are applied & Specific Heat of Brake Drum is defined as the specific heat of the whole assembly of the brake drum.
How to calculate Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly?
The Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly formula is defined as the energy which is being applied by the brakes when the brakes are applied is calculated using Total Energy of Brake = Temperature Change of Brake Assembly*Mass of Brake Assembly*Specific Heat of Brake Drum. To calculate Total Energy Absorbed by Brake given Temperature Rise of Brake Drum Assembly, you need Temperature Change of Brake Assembly (ΔT), Mass of Brake Assembly (m) & Specific Heat of Brake Drum (c). With our tool, you need to enter the respective value for Temperature Change of Brake Assembly, Mass of Brake Assembly & Specific Heat of Brake Drum and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
Let Others Know
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!