There are multiple ways that manufacturers can take to ensure a bearing has a long and successful life. The first step is to limit the radial load to between 6–12 per cent of a bearing's dynamic load rating. Although a bearing is able to tolerate a much higher load, its life will be shortened.

Radial load vs axial loadbearing

Dynamic radial load rating is officially defined as: "the constant stationary radial load in which 90 per cent of a group of identical chrome steel bearings, with only the inner ring rotating, can endure for one million revolutions before the first signs of fatigue develop."

We always express load ratings for bearings in Kgf (kilogramme force). That is the force exerted by a mass of one kilogramme at the Earth's surface. Elsewhere, you may see force expressed in Newtons.

As shown above, Bootstrap generates a series of predefined container classes to help you build the layouts you desire. You may customize these predefined container classes by modifying the Sass map (found in _variables.scss) that powers them:

One million revolutions does sound like a large number, but let's examine that a little more. A bearing will only last for just over an hour and a half (100 minutes) if you run it at around 10,000 revolutions per minute (rpm) with the maximum dynamic load applied to it.

Axial loadexample

Containers are a fundamental building block of Bootstrap that contain, pad, and align your content within a given device or viewport.

Axial loadformula

A Newton is defined as the force that will accelerate a mass of one kilogram at the rate of one meter per second per second (or 1 m/s²). Since the force of gravity at the Earth's surface is 9.80665 m/s², 1 Kgf = 9.80665 Newtons but, to keep it simple, we say 1 Kgf = 10 Newtons.

Responsive containers allow you to specify a class that is 100% wide until the specified breakpoint is reached, after which we apply max-widths for each of the higher breakpoints. For example, .container-sm is 100% wide to start until the sm breakpoint is reached, where it will scale up with md, lg, xl, and xxl.

These figures are used in the calculation of life ratings, but bearings should not be subjected to anywhere near such loads in normal application unless you don't expect them to last very long.

Radial loadexample

AISI440C/KS440 stainless steel bearings will support approximately 80 - 85 per cent of the load figures for chrome steel bearings - see how they stack up here. Load ratings for thrust bearings are based on the constant axial load endured for one million revolutions. SMB Bearings’ team of experts can help with providing data for life ratings of a variety of different bearings.

Axialandradialdirection

Please note, these figures are based on pure axial load. Additional radial loads or moment (misalignment loads) will have an impact on the axial load capacity. To exceed the total recommended limits for combined loads will have a detrimental effect on bearing life.

The table below illustrates how each container’s max-width compares to the original .container and .container-fluid across each breakpoint.

Full complement ball bearings use a filling slot machined into the inner and outer rings. Under axial load, this slot can interfere with ball rotation so full complement bearings are not recommended for axial loads.

Containers are the most basic layout element in Bootstrap and are required when using our default grid system. Containers are used to contain, pad, and (sometimes) center the content within them. While containers can be nested, most layouts do not require a nested container.

Radial loadformula

Static radial load rating refers to the purely radial load (or axial load for thrust bearings) which will cause a total permanent deformation of the balls or raceway.

Radial loadbearing

If long life is required, it is preferable to limit the actual load to between 6 per cent and 12 per cent of a bearing’s dynamic load rating. Heavier loads can be tolerated but life will be shortened.

Our determination to remain specialised gives us a high level of product knowledge, providing bearing and lubrication solutions to existing or potential customers, whether individuals or large corporations. We don’t just sell bearings, we help to solve your problems. - Chris Johnson, managing director of SMB Bearings.

By choosing the right type of bearing and considering key factors in the battle to control radial and thrust loads, engineers can ensure they continue to innovate while delivering the highest levels of accuracy, smoothness and bearing life.

Radial load vsthrustload

Static loads approaching this figure may be tolerable for certain applications but not where any smoothness or accuracy is required. Static load ratings for stainless steel bearings are approximately 75 per cent –to 80 per cent of the load ratings for chrome steel bearings.

The next step is to choose the right material.  In SMB Bearings' experience as a specialist in thin-section, corrosion resistant, miniature bearings and ceramic bearings choosing the right type of bearing can also make all the difference. While all radial ball bearings have some thrust load capacity, it's often better to use heavy duty bearings that have deep raceways if greater thrust loads are present as these can withstand axial loads of up to 50 per cent of the static radial load rating.

The load capacity of a bearing may be limited by the lubricant. Certain lubricants are only suitable for light loads while others are designed for high load applications. Load ratings are higher for full complement bearings (see “bearing retainers” in the technical menu). The axial load capacity of a radial ball bearing can be increased by specifying loose radial play.

Heavy duty bearing types such as 6200 or 6300 series may take axial loads of up to 50 percent of the static radial load rating. Thin-section deep groove ball bearings can only support axial loads of between 10 and 30 percent of the bearing's static radial load rating due the shallower raceways.

Although thin-section bearings — where the difference between the inner and outer diameter of the bearing is small — are great for compactness and saving weight. They can only support axial loads of between 10 and 30 per cent of the bearing's static radial load rating due to the shallower raceways. Additional radial loads or moment loads will reduce thrust load capacity even further. Excessive thrust loads on a thin-section bearing can cause the balls to ride dangerously close to the top of the raceway.

For more information and examples on how to modify our Sass maps and variables, please refer to the Sass section of the Grid documentation.