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In the field of automated equipment manufacturing, polyurethane covered wheels are essential components widely used in conveyor systems, sorting equipment, AGV (Automated Guided Vehicles), and warehouse logistics systems. However, during the procurement process, many engineers and purchasing managers face a critical question: How do I select the right hardness for polyurethane covered wheels based on my equipment operating conditions?
Improper hardness selection can lead to increased noise, accelerated wear, and in severe cases, compromised equipment precision or even safety hazards. This article provides a systematic explanation of polyurethane hardness definitions, testing standards, and selection logic for various automated equipment applications, helping you make informed decisions.
Shore Hardness is an international standard for measuring the resistance of elastic materials (such as rubber and polyurethane) to indentation. It was invented by American engineer Alfred Shore. The three most common Shore hardness scales are:
|
Type |
Application Range |
Reading |
|
Shore A |
Soft rubber, polyurethane elastomers |
0~100 |
|
Shore D |
Hard plastics, semi-rigid materials |
0~100 |
|
Shore 00 |
Extremely soft materials (sponges, gels) |
0~100 |
Polyurethane covered wheels are typically rated using Shore A hardness, ranging from 50A to 98A. A higher number indicates greater hardness.
The Shore hardness durometer works by pressing a standardized indenter into the material surface using a spring of specified force. The hardness value is calculated based on the indentation depth. Deeper indentation means lower hardness; shallower indentation means higher hardness.
Simplified explanation: Think of Shore A hardness like pressing your finger into a cake—the deeper it goes, the softer the cake (lower hardness); if you cannot press it in, the cake is hard (higher hardness).
When procuring polyurethane covered wheels, you may occasionally encounter hardness ratings in Shore D. The fundamental difference lies in the indenter shape and spring force:
• Shore A: Rounded indenter with lighter spring force, for soft materials (most common range: 50A-90A)
• Shore D: Conical indenter with heavier spring force, for harder materials
As a general reference: When Shore A hardness exceeds 90A, the equivalent Shore D reading is approximately 30D-40D. Therefore, if a supplier specifies Shore D hardness, verify whether it suits your actual application requirements.
Based on practical applications in the automated equipment industry, we categorize common Shore A hardness levels for polyurethane covered wheels as follows:
|
Hardness Range |
Material Characteristics |
Typical Applications |
Pros & Cons |
|
Shore A 60-70 |
Soft, highly elastic, excellent shock absorption |
Light-duty conveyors, office automation equipment |
Pros: Quiet, vibration-dampening; Cons: Relatively lower abrasion resistance |
|
Shore A 70-80 (Most Common) |
Balanced performance, moderate elasticity and wear resistance |
General-purpose automated conveyors, sorting equipment |
Pros: Best cost-performance ratio, wide applicability; Cons: Specialized applications may require custom solutions |
|
Shore A 80-90 |
High strength, excellent wear resistance, strong load capacity |
Heavy-duty conveyors, warehouse logistics, AGV |
Pros: Long service life, high load capacity; Cons: Reduced vibration dampening |
|
Shore A 90-95 |
Ultra-high hardness, extreme wear and cut resistance |
Specialized applications, heavy machinery, outdoor equipment |
Pros: Maximum abrasion resistance; Cons: Poor elasticity, higher noise |
A common misconception among procurement professionals is: higher hardness means better quality polyurethane covered wheels. This is a serious selection error.
The core principle of hardness selection is: Match the hardness to the operating conditions, not to the highest numerical value.
Consequences of improper hardness selection include:
• Excessive hardness: Increases equipment vibration and noise, accelerates wear on metal wheel hubs or bearings, may cause floor scratching
• Insufficient hardness: Increased wheel deformation, reduced load capacity, higher rolling resistance leading to increased motor load, shortened service life
Take AGV (Automated Guided Vehicle) as an example: Using 95A hardness polyurethane wheels in high-end office buildings or hospitals—where noise requirements are extremely strict—will result in noticeable driving noise and vibration even with excellent wear resistance. Conversely, using 60A soft wheels in heavy-duty warehouse environments will quickly lead to excessive wheel deformation and insufficient load capacity.
Light-duty conveyors typically carry loads under 50kg at low speeds (usually below 1m/s), with high requirements for noise control and floor protection.
Recommended Hardness: Shore A 65-75
Selection Rationale:
• Softer wheel surfaces effectively absorb impact forces, reducing product damage during conveying
• Lower noise during floor contact, improving the working environment
• Better protection for precision equipment and floor surfaces
Case Study: A food packaging company's sorting conveyor line originally used Shore A 70 polyurethane covered wheels, achieving quiet operation with a wheel service life exceeding 3 years, reducing overall maintenance costs by approximately 40%.
This equipment operates at high speeds (typically 1-3m/s), handles medium loads (50-500kg), and runs 24/7, demanding exceptional wear resistance and stability.
Recommended Hardness: Shore A 75-85
Selection Rationale:
• This hardness range offers the optimal balance between wear resistance and elasticity
• Capable of withstanding frictional heat buildup during high-speed operation
• Service life typically exceeds 1-2 years, reducing downtime for replacements
Special Note: In cold northern winter environments (room temperature below 5°C/41°F), polyurethane materials become harder. It is recommended to select Shore A 80 or above, or specify cold-resistant polyurethane formulations.
Heavy-duty warehousing equipment handles loads from 500kg to 5 metric tons, operates at high frequency, and often involves steel slide rails or track systems, with stringent requirements for wheel load capacity and stability.
Recommended Hardness: Shore A 85-92
Selection Rationale:
• High hardness ensures minimal deformation under heavy loads, maintaining operational precision
• Superior abrasion resistance for harsh conditions with debris and metal shavings
• When paired with steel or aluminum rails, hard polyurethane layers effectively protect rails from damage
Additional Recommendation: For loads exceeding 5 tons, it is advised to incorporate reinforced wheel hub designs and double-bearing configurations.
AGV polyurethane covered wheel hardness requirements depend on operating environment and floor conditions:
• Indoor epoxy floors: Shore A 75-82 (balancing wear resistance with quiet operation)
• Industrial concrete floors: Shore A 82-88 (handling floor particle abrasion)
• Outdoor or mixed surfaces: Shore A 85-92 (maximum wear resistance required)
AGV selection also requires special attention to wheel dynamic balance precision—unbalanced wheels generate eccentric forces during high-speed operation, accelerating wheel hub bearing wear and affecting AGV navigation accuracy.
Background: A large e-commerce sorting center initially procured Shore A 65 polyurethane covered wheels, expecting quiet operation. However, after just 3 months of operation, the wheels showed severe wear with thickness loss exceeding 40%, and some wheels experienced chunking (polyurethane delamination from the metal hub).
Root Cause Analysis:
• Sorting equipment operating speed reached 2.5m/s, classified as high-speed operation
• Sorting lines ran continuously for over 20 hours daily under high-intensity conditions
• 65A hardness under high-frequency friction generated excessive heat, accelerating polyurethane aging and delamination
Solution: Hardness was adjusted to Shore A 80, and the bonding process was strengthened (enhanced adhesive layer and surface treatment). After adjustment, wheel service life increased from 3 months to over 18 months.
Background: A tertiary hospital introduced AGV logistics systems for pharmaceutical and supply delivery. The hospital had extremely high noise control requirements, with high-quality epoxy resin flooring requiring protection from any scratches.
Selection Strategy:
• Main drive wheels: Shore A 78 (balancing wear resistance and quiet operation)
• Idler wheels and steering wheels: Shore A 72 (prioritizing floor protection and quiet operation)
• All wheels featuring PTFE (polytetrafluoroethylene) surface treatment to reduce friction coefficient
Results: AGV operating noise remained below 45dB with no floor scratches, and wheel service life exceeded 2 years, meeting the hospital's dual standards for environment and equipment quality.
Background: Stackers in an automated warehouse needed to operate on storage rack rails with maximum load per lift reaching 3 metric tons. Rails were cold-drawn steel with stable operating speed requirements.
Selection Strategy:
• Shore A 90 hardness polyurethane covered wheels for maximum wear resistance
• Wheel surface designed with special grooves to enhance rail grip and water drainage
• Metal wheel hubs made from No. 45 steel with tempering treatment to HRC 45+
Results: Stacker operational precision maintained within ±1mm, wheel service life exceeded 5 years under high-intensity operation, with significantly reduced maintenance costs.
Absolutely. The same Shore A 80 hardness rating from different manufacturers can vary significantly due to differences in polyurethane formulations (polyester-based vs. polyether-based), process parameters (casting temperature, curing time), and raw material quality—all affecting final product wear resistance, resilience, temperature resistance, and service life. Therefore, selection should not be based solely on hardness numbers; supplier formulation capabilities and process control levels are equally important.
Yes. Polyurethane materials gradually undergo aging during extended use, manifesting as increased hardness (embrittlement) and reduced elasticity. Key factors affecting aging include: operating temperature (high temperatures accelerate aging), UV exposure, chemical attack from lubricants or solvents, and sustained dynamic loads. Aging rate correlates closely with product quality and operating conditions—high-quality polyurethane covered wheels age significantly slower than inferior products.
The most reliable method is using a Shore durometer for on-site measurement. If a durometer is unavailable, a simple manual test: press the wheel surface with your hand—high-hardness wheels show virtually no deformation, while low-hardness wheels show noticeable indentation. Note: This method provides only rough assessment and cannot replace durometer measurement.
Generally, drive wheels, idler wheels, and steering wheels on the same equipment can use different hardness configurations to achieve performance and cost balance. However, prerequisites include: all wheels must have consistent diameter (otherwise load distribution will be uneven), and the hardness combination must undergo mechanical analysis to ensure normal equipment operation and drive system service life. It is recommended to conduct hardness selection under supplier engineering guidance.
Most reputable polyurethane covered wheel manufacturers offer non-standard hardness customization. If your application analysis requires hardness between standard values (e.g., 77A between 75A and 80A), customization is available. Note: Non-standard hardness typically has minimum order quantity requirements (MOQ), and unit price will be higher than standard inventory hardness. Confirm with your supplier in advance.
Selection is not about choosing 'the highest hardness' but 'the most suitable hardness.' Here is a simplified selection decision logic:
|
Equipment Type |
Recommended Hardness |
Key Selection Criteria |
Notes |
|
Light-duty conveyors / Office automation |
Shore A 65-75 |
Quiet operation, floor protection |
Avoid high-speed operation |
|
General sorting / E-commerce logistics |
Shore A 75-85 |
Balance of wear resistance and elasticity |
Consider low-temperature hardness compensation |
|
Heavy-duty warehousing / Automated warehouses |
Shore A 85-92 |
High load capacity, maximum wear resistance |
Coordinate with reinforced wheel hub design |
|
AGV (Indoor) |
Shore A 75-82 |
Quiet operation, floor protection |
Pay attention to dynamic balance precision |
|
Outdoor / Specialized applications |
Shore A 90-95 |
Extreme wear resistance |
Accept reduced elasticity |
• Do not make procurement decisions based solely on hardness values; conduct comprehensive evaluation based on equipment operating conditions
• Prioritize suppliers with formulation R&D capabilities and process control systems
• Before bulk procurement, request samples for actual operating condition testing (minimum 1-2 weeks)
• Establish supplier technical files, recording actual service life data for different batches
• Specify hardness testing standards and acceptance methods in contracts to avoid disputes
• For critical equipment (AGV, heavy-duty stackers), conduct technical reviews and on-site condition assessments before procurement
