It's not enough to simply inspect your brakes regularly. To insure top performance, you need to understand how operational factors impact brake performance.  
 -  Photo: Jim Park

It's not enough to simply inspect your brakes regularly. To insure top performance, you need to understand how operational factors impact brake performance. 

Photo: Jim Park

We are all familiar with brakes. We use them to stop. That's their function, but in engineering terms, a brake is a device used to convert kinetic energy (motion) into thermal energy (heat) through friction between stationary parts (brake linings) and moving parts (brake drums or rotors). The brake drum and the lining material are designed to dissipate that converted energy, but too much heat that cannot dissipate quickly enough will eventually overwhelm the brakes design capacity rendering them less and less effective, and eventually useless. 

The normal operating temperature of a properly functioning brake is about 500°F. A hot brake that produces a distinctive odor usually accompanied by white or blue smoke is about 800°F. Dangerously overheated brakes can reach temperatures of  1,800°F or higher. These will glow cherry- to bright-red and there's serious risk of a wheel-end or tire fire.

Several things happen to hot drum brakes that will reduce their stopping ability--a condition often referred to as brake fade. Most lining materials lose some frictional capability at high temperatures. Poor quality linings may lose up to a third of their effectiveness at temperatures above 600°F.

On top of that, cast iron brake drums expand as they get hot. The diameter of the drum can increase by as much as forty thousandths (.040) of an inch when it's really hot. An accepted rule of thumb suggests that for every .020 of an inch the drum expands, the push-rod has to travel an additional 1/4 inch to maintain lining-to-drum contact. If a brake was not properly adjusted to begin with, things can go downhill (sorry about that pun) pretty fast. 

The laws of physics work against truck brakes in other ways too. It's accepted that if truck weight is doubled, stopping power must be doubled. But if speed is doubled, stopping power must be increased four times. If both weight and speed are doubled, stopping power must be increased eight times.

In practical terms, that means a fully loaded truck descending a hill at 60 mph will require eight times the stopping power of a lightly loaded truck traveling at 30 mph. Or, the brakes on the faster heavier truck will be doing eight times as much work as the brakes on the slower lighter truck. In other words, the brakes must absorb or dissipate eight times as much heat.

Even small increases in speed can make a big difference to the demands on the brakes. 
 -  Chart: Jim Park

Even small increases in speed can make a big difference to the demands on the brakes.

Chart: Jim Park

Even small increases in speed can make a big difference to the demands on the brakes. An increase in speed from 50 mph to 60 mph --an increase of 25%--would increase the stopping distance on level ground by 56%. You can guess what happen on steep hills at high speed.

*Much of the technical detail here comes from a book called "Air Brakes from the Driver's Seat" by Allan C. Wright, published in 1999. It's now out of print, but in 2004 he assigned the book’s copyright to the Insurance Corporation of British Columbia, and it’s since been incorporated into the ICBC publication “Driving Commercial Vehicles”.

About the author
Jim Park

Jim Park

Equipment Editor

A truck driver and owner-operator for 20 years before becoming a trucking journalist, Jim Park maintains his commercial driver’s license and brings a real-world perspective to Test Drives, as well as to features about equipment spec’ing and trends, maintenance and drivers. His On the Spot videos bring a new dimension to his trucking reporting. And he's the primary host of the HDT Talks Trucking videocast/podcast.

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