How to Choose the Right Cylindrical Roller Bearings

Figure 1: Cylindrical Roller Bearing

Click here to get more.

Manufacturers design bearings to 'bear' or carry a load while restricting motion and reducing friction between moving parts. Cylindrical roller bearings are one type of bearing designed for high-load, circular needs. Ribs guide these cylindrical rolling elements on the inner or outer rings designed to move freely in the axial direction, making this bearing ideal for applications with thermal expansion on the shaft, like an electric motor.

A better understanding of cylindrical roller bearings, their functions, and their advantages and disadvantages helps select the correct bearing for each application.

Table of contents

• What are cylindrical roller bearings?
• Components and materials
• Why use cylindrical roller bearings?
• Cylindrical roller bearings applications
• FAQs

What are cylindrical roller bearings?

A cylindrical roller bearing is a contact-type bearing that is different from other bearings. They use cylinder-shaped rolling parts instead of balls like you'd find in ball bearings. Because cylindrical rollers are in linear contact with the raceways, they have a greater circular load capacity than ball bearings.

Though the rollers are cylindrically-shaped, they are not true cylinders. The rollers are crowned or end-relieved to reduce stress, resulting in low friction. Low friction makes them an ideal choice for high-speed situations. Cylindrical roller bearings are typically lubricated with oil to reduce heat caused by high speeds.

Components and materials

Cylindrical roller bearings are radial-type roller bearings. This class of roller bearing includes tapered, spherical, and needle roller bearings. All cylindrical roller bearings have four essential components: an inner ring, an outer ring, rollers, and a cage. The bearing rings and rollers carry the load, and the cage (Figure 2) keeps the rollers in place.

Cylindrical roller bearings vary from clearance and lubrication options, depending on the manufacturer. They can be made with a cage or as a full complemented part. Some have no ribs on either ring, allowing axial movement of the rings, which can be used as free-end bearings.

Pressed steel or machined brass are the most common materials to form cylindrical roller bearing cages. Still, some use molded polyamide, which makes smoother and quieter running bearings. When necessary, hardened high carbon steel or carburized low carbon steel enhances bending fatigue and handles heavy shock loads.

Figure 2: Double-row cylindrical roller bearing cage and rollers

Single vs multi-row types

Though single row cylindrical roller bearings are the most common type, cylindrical rollers also come in multi-row options.

• Single-row cylindrical rollers are popular because they are separable, making them easier to mount and dismount. However, they do not support heavy or oversized radial loads because they only allow axial loads in one direction.
• Double-row cylindrical roller bearings often solve load capacity challenges. Double-row bearings spread the load over a broader area and handle destabilizing loads or vibrations. In addition, one double-row bearing takes up less space inside the bearing housing than placing two single-row bearings back-to-back. It also optimizes load transfer between the two rows.
• Multi-row, or four-row, cylindrical roller bearings are often used as roll-neck bearings. The four rows of rollers accommodate larger radial loads. Tight diametrical tolerances on contoured rollers allow bearings to distribute loadings evenly. Cages for multi-row rollers commonly use a machined brass finger cage or a mild steel finger cage. Still, larger sizes use a steel pin-type cage with hollow rollers.

Figure 3: Double-row cylindrical roller bearing

Why use cylindrical roller bearings?

With cylindrical roller bearings, the outer load is continuously re-distributed among the rollers. Fewer than half of the total number of rollers carry the application's load as the inner ring rotates. The weight distribution is superior to the load-bearing capacity of ball bearings. It contributes to the service life of the bearing.

Advantages

• Capable of handling higher radial loads when compared to other roller bearings or ball bearings
• Can handle high speeds
• High stiffness
• Can handle both axial and radial loads
• High precision
• Long service life
• Available in single, double, and multi-row configurations to accommodate various load requirements
• Lower friction, temperature, and power consumption

Disadvantages

• Noisier than other bearings
• Higher cost

Cylindrical roller bearing selection criteria

There are several criteria to consider when selecting cylindrical roller bearings. For example, one must consider dimensions, the operational speed and load specifications, unique installation features, and materials' choice. DIN Standards 635-1 outline specific dimensions and symbols for single-row spherical roller bearings, while DIN 635-2 standards refer to double-row configurations.

Dimensions

One must consider three dimensions when selecting bearings for a specific application, including:

• Bore. The bearing industry has a standard number system for radial bearings with metric diameter bores.
• Outside Diameter. Outside diameter is the overall width of the outer ring. Still, housed units include the housing, while flanged units exclude the flange.
• Overall Width. Overall width of the bearing, or bearing assembly, including the locking collar, if present.

Operating specifications

Axial load support in one direction (single-row) or two directions (double-row), and loading parameters, need to be considered when selecting the correct bearing, including:

• Rated speed
• Static axial or thrust load
• Static radial load
• Dynamic axial or thrust load
• Dynamic radial load

Unique features

An application may also require some unique features. In some instances, bearings are flanged for mounting or locating purposes. A spherical outside diameter has a greater load capacity and allows a bearing to be more tolerant of misalignment but requires more radial space.

Materials

Some applications require thoroughly hardened high carbon bearing quality steel, which is more durable than typical alloy or low carbon steel bearings. Further, material processing can add carbon and alloys to low carbon grades of steel. This process produces a fatigue-resistant case and a rigid, malleable core, improving the bending fatigue to accommodate heavy shock loads.

Applications

Their greater radial load capacity and their ability to accommodate faster speeds, as well as other benefits, make cylindrical roller bearings an ideal solution for a variety of industries, including:

• Oil and gas
• Gearboxes
• Wind turbines
• Machine tool
• Electric motors
• Material handling
• Pumps
• Steel mills

FAQs

Do cylindrical roller bearings have low friction?

Yes. The design of the rollers and surface allows cylindrical roller bearings to manage heavy loading with low levels of friction.

What causes cylindrical roller bearings to fail?

Improper mounting and sealing, lubricant failure, and the presence of debris and contaminants are the most common reasons for bearing failure. In addition, excessive loading can lead to overheating and failure.

What maintenance procedures should I follow?

Cylindrical roller bearings, like all bearings, are subjected to rust, pitting, scratches, and chips. Bearings treated with a surface coating helps to extend the life of the bearing by preventing these instances.

What kind of surface treatments should I use on a cylindrical roller bearing?

Zinc-nickel plating, zinc, and phosphate coatings help protect against rust, pitting, scratching, and chipping.

What is the difference between needle bearings and cylindrical roller bearings?

The length/diameter ratio of needle-bearing rollers is greater than four. In contrast, the length of the rollers in a cylindrical roller bearing is shorter with a larger diameter.

Cylindrical roller bearings are the heavy lifters of the bearing world, designed to handle serious radial loads while keeping machines running smoothly. Whether you’re outfitting a wind turbine, a gearbox, or a conveyor system, picking the right cylindrical roller bearing can make or break your equipment’s performance. But with so many types, sizes, and specs, how do you choose the perfect one? Let’s walk through the key factors to consider, from load capacity to lubrication, and share some pro tips to ensure you get it right.

Why Choosing the Right Cylindrical Roller Bearing Matters 

Cylindrical roller bearings are built to handle heavy radial loads with their line-contact design, making them a go-to for industries like automotive, manufacturing, and renewable energy. Picking the wrong bearing can lead to premature wear, machine downtime, or even catastrophic failure. On the flip side, the right choice boosts efficiency, extends equipment life, and saves you money in the long run.

Why It’s Tricky: With options like single-row, double-row, or full complement bearings, plus variations in materials and cage designs, the decision isn’t always straightforward. That’s why understanding your application’s needs is key.

Key Factors to Consider When Selecting Cylindrical Roller Bearings

Let’s break down the main criteria to guide your decision. Think of these as the building blocks for finding the perfect bearing.

Load Capacity and Type

Cylindrical roller bearings shine at handling radial loads (forces perpendicular to the shaft), but some designs can also manage axial (thrust) loads.

· Radial Load: Single-row bearings like NU or N types are great for pure radial loads. If your application involves heavy radial forces, like in a steel mill, prioritize high-capacity designs.

· Axial Load: NJ or NUP bearings have ribs to handle limited axial loads in one or both directions. For heavy axial loads, consider cylindrical thrust roller bearings.

· Combined Loads: If your setup faces both radial and axial forces, double-row or multi-row bearings might be the answer.

Insight: Always calculate your application’s load requirements using tools like bearing load calculators or consult manufacturer data to avoid undersizing, which can lead to early failure.

Speed Requirements

Speed matters. Cylindrical roller bearings can handle high speeds, but their limit depends on the design:

· Cage vs. Full Complement: Bearings with cages (e.g., brass or polyamide) reduce friction, making them better for high-speed applications like electric motors. Full complement bearings, packed with more rollers, prioritize load capacity but generate more friction, limiting speed.

· Precision: Double-row bearings offer higher precision for high-speed applications like machine tool spindles.

Insight: Check the bearing’s limiting speed rating in the manufacturer’s catalog. For high-speed setups, opt for bearings with low-friction cages and oil lubrication.

Size and Dimensions

Bearings must fit your shaft and housing perfectly. Key measurements include:

· Inner Diameter (ID): Matches the shaft size.

· Outer Diameter (OD): Fits the housing.

· Width: Ensures proper load distribution.

Use ISO standards (e.g., ISO 15 for bearing dimensions) to ensure compatibility. Oversized or undersized bearings can cause misalignment or excessive wear.

Bearing Type and Configuration

Cylindrical roller bearings come in several configurations, each suited for specific needs:

· Single-Row (NU, NJ, N, NUP): Versatile, separable designs for easy installation. NU and N handle radial loads only, while NJ and NUP manage some axial loads.

· Double-Row: Higher load capacity and precision for applications like compressors.

· Four-Row: Built for extreme loads in steel mills or heavy machinery.

· Full Complement: No cage, maximum rollers for heavy loads but lower speeds.

Table: Cylindrical Roller Bearing Types and Uses

Type

Features

Best For

Single-Row (NU, NJ)

Separable, moderate load

Gearboxes, pumps

If you are looking for more details, kindly visit Shangyou.

Double-Row

High load, precision

Machine tools, compressors

Four-Row

Extreme load capacity

Steel mills, heavy machinery

Full Complement

Maximum load, higher friction

Cranes, low-speed equipment

Material and Durability

Bearings are typically made from high-carbon or alloy steel for strength, but material choice impacts performance:

· Standard Steel: Durable for most applications, like automotive or industrial machinery.

· Stainless Steel: Resists corrosion in wet or chemical environments, like food processing.

· Ceramic Hybrids: Combine steel races with ceramic rollers for high-speed, low-friction applications like aerospace.

Insight: For harsh environments, like marine or chemical plants, stainless steel or coated bearings can extend service life significantly.

Lubrication Needs

Lubrication reduces friction, prevents wear, and acts as a coolant. Options include:

· Grease: Low maintenance, ideal for sealed bearings in moderate-speed applications.

· Oil: Better for high-speed or high-temperature setups, as it dissipates heat effectively.

Check the bearing’s lubrication requirements in the manufacturer’s specs. Some bearings come pre-lubricated, while others need regular maintenance.

Insight: Over-lubrication can cause overheating, while under-lubrication leads to wear. Follow the manufacturer’s guidelines or use automatic lubrication systems for consistency.

Environmental Conditions

Your operating environment plays a big role:

· Temperature: High temperatures (e.g., steel mills) require heat-stabilized bearings or oil lubrication. Low temperatures need special greases to prevent hardening.

· Contamination: Dusty or wet environments call for sealed or shielded bearings to keep out debris.

· Vibration: High-vibration applications, like mining equipment, need robust bearings with strong cages.

Step-by-Step Guide to Choosing Cylindrical Roller Bearings

Here’s a practical checklist to streamline your decision:

1. Define Load Requirements: Calculate radial and axial loads using engineering software or manufacturer tools.

2. Determine Speed Needs: Check your application’s RPM and match it to the bearing’s limiting speed.

3. Measure Dimensions: Ensure the bearing’s ID, OD, and width fit your shaft and housing.

4. Select Bearing Type: Choose single-row, double-row, or full complement based on load and speed.

5. Consider Materials: Pick steel, stainless, or ceramic based on environmental conditions.

6. Plan Lubrication: Decide between grease or oil, and set a maintenance schedule.

7. Account for Environment: Factor in temperature, contamination, and vibration.

8. Consult Manufacturer Data: Use catalogs from trusted brands like SKF, NSK, or Timken for detailed specs.

9. Test and Validate: If possible, test the bearing in your application to confirm performance.

Insight: Working with a bearing supplier like WKB-Bearing can simplify the process. We can provide tailored recommendations and access to high-quality cylindrical roller bearings for your specific needs.

Insights into Cylindrical Roller Bearing Selection

· Alignment is Critical: Misalignment can cause uneven loading and premature failure. Use precision alignment tools during installation.

· Cost vs. Performance: High-end bearings (e.g., ceramic hybrids) cost more upfront but save money through longer life and reduced downtime.

· Future-Proofing: Choose bearings with scalable designs (e.g., double-row for precision) to accommodate future upgrades.

Frequently Asked Questions (FAQ)

What are cylindrical roller bearings?
Cylindrical roller bearings use cylindrical rollers to support heavy radial loads with line contact, reducing friction in applications like gearboxes and wind turbines.

How do I choose the right cylindrical roller bearing?
Consider load capacity, speed, dimensions, bearing type, material, lubrication, and environmental conditions. Consult the manufacturer's data for precise specs.

What’s the difference between single-row and double-row cylindrical roller bearings?
Single-row bearings are separable and handle moderate loads, while double-row bearings offer higher load capacity and precision for demanding applications.

What are the advantages of cylindrical roller bearings for high-load applications?
They provide high radial load capacity, durability, and separable designs for easy installation, making them ideal for heavy machinery.

How does lubrication affect cylindrical roller bearing performance?
Proper lubrication reduces friction, prevents wear, and cools the bearing. Grease suits low-maintenance setups, while oil is better for high-speed or high-temperature applications.

What are the best cylindrical roller bearings for high-speed applications?
Single-row or double-row bearings with low-friction cages (e.g., brass or polyamide) and oil lubrication are ideal for high-speed setups like machine tools.

How do environmental conditions impact cylindrical roller bearing selection?
High temperatures require heat-stabilized bearings, while dusty or wet environments need sealed or shielded designs to prevent contamination.

References

· Tameson. (). How to Choose the Right Cylindrical Roller Bearings.

· SKF. (n.d.). Cylindrical Roller Bearings.

· NSK Americas. (n.d.). Cylindrical Roller Bearings Selection Guide.

· Timken. (). Engineering Manual: Cylindrical Roller Bearings.

· Machine Design. (). How to Select the Right Bearing for Your Application.

· GlobalSpec. (n.d.). Cylindrical Roller Bearings - Types and Applications.

· Bearing News. (). Choosing the Right Bearing for Industrial Applications.

· Emerson Bearing. (). Cylindrical Roller Bearings: Selection and Maintenance.

· ScienceDirect. (n.d.). Roller Bearings - Design and Applications.

If you are looking for more details, kindly visit four row cylindrical roller bearings.