When we discuss about a motorcycle's performance, we generally speak about its engine power, torque, top speed, how fast it can accelerate, vehicle sound etc. Nevertheless, all these are meaningless if a driver cannot control the machine and/or is not comfortable while riding. There comes the importance of tyres. Tyres are the most crucial parts of a vehicle suspension system.  Tyres are the only component in a motorcycle that constantly stays in contact with the road. The part of tread which is in contact with road surface is called ‘contact patch’ & Is about half the size of a post card.  The overall suspension system (including tyres) ensures the right contact between the tires and the road surface at every stage of driving, thereby ensuring stability and good handling of the vehicle.

As tyres are the only contact with the road, they are responsible for multiple functions, such as –

Transfer the engine power to the road- meeting the demands of acceleration and braking

  Provides right hold (grip) on different surfaces like dry, wet, snow, loose soils etc.

  Helps the rider to steer the vehicle by responding to the handle movements

  Carry the weight of the vehicle & rider

 Ensuring the comfort of the rider by absorbing and dampening shock

Apart from the above aspects, tyres play a vital role in vehicle aesthetics, safety, fuel efficiency etc. These and several other challenges make Motorcycle tyre design a very interesting and responsible subject.

Apart from being a crucial part of a vehicle suspension system, tyres are the only contact between vehicle & road. Motorcycle vehicle dynamics and control characteristics are highly influenced by the tyre design. It is therefore highly imperative for a vehicle chase/suspension designer & tyre designer to work together in tandem. This will ensure that the part designs will complement each other and deliver the characteristic target performance of a motorcycle. A robust interaction mechanism between the R&Ds of OEM [Original Equipment Manufactures] and tyre manufactures is a growing necessity to cater to the ever‐increasing demands of performance entrusted upon the tyre of today. In case of tyres getting designed exclusively for aftermarket, a tyre designer work closely with the vehicle dynamics team to ensure that the retrofit design delivers desired target performance of the vehicle

Some of the major steps involved in motorcycle tyre design are

 Product planning & Tyre “Size” finalization: During this stage a vehicle designer & tyre designer jointly review the vehicle performance requirements and decides the parameters specific to tyre performance. This includes:

Defying the application /terrine: Depending on application, 2 wheelers maybe broadly classified as Sport, Cruiser, Choppers, Touring, scooter, Step through, Sport touring, Enduro etc. Different OEM’s follow different terminologies, but a for a tyre designer to understand the final use by the user is of utmost importance. Demands from a tyre varies with each vehicle category, for example, for a cruiser the tyre is designed to be robust so as to hold up the weight of such heavy bikes and deliver long tyre life, whereas for a Sport touring /super sport bike, tyres are  designed to deliver quick and precise handling with superior grip. These tires are lighter and made by using softer compounds for Superior grip.

Selection of Bias /Bias belted / Radial:   At this juncture, I am not going to delve deeper into a detailed comparison of these constructions – however, it is important to acknowledge that both these construction types have their respective advantages and disadvantages. Each of these constructions has few specific applications where one performs better than the other. The selection of construction type mainly depends on vehicle category (application), vehicle Speed, load on the tyre, stability requirements, handling requirements, etc. for example Bias tyres are used in medium speed but heavy weight vehicles owing to their sturdy sidewalls, whereas Radial tyres are the ideal choice for high speed , vehicles because of their superior dimensional stability.

Selection of Tube type Vs Tubeless:  Functionally both types of tyres have a proven track record for almost all applications. Hence this choice mainly depends on vehicle Rim design, which is decided by the overall aesthetic demand & application of the motorcycle.For high speed application, tubeless is always preferred

Finalizing the Tyre size / Tyre Geometry:  In general, we may call it as tyre “size” – which includes tyre width, tyre diameter, rim diameter etc. Tyre geometry affects the vehicle dynamics like caster, trail, vehicle Center of gravity [CoG], etc. It also influences the area of contact between vehicle and road surface under different riding conditions & load-carrying capacity of the tyres. Furthermore, tyre size significantly influences vehicle aesthetic as well.  Tyre “size” and vehicle rim size are always interconnected. Decision on one influence the decision on the other.  Usually motorcycles have different front and rear tyre sizes depending on vehicle geometry & load distribution. Tyre “sizes” are decided considering all these parameters & the designers ensures that it follows the standards’ guidelines applicable in target countries.

Tyre tread profile design:

Contrary to the passenger car tyre designs which have almost flat tread surface, motorcycle tires have a U-shaped profile and a contact patch that changes size and shape during cornering. There is a major difference in the way lateral force is built up in passenger car and two wheelers.  In case of passenger car, mechanism of lateral force builds up is due to slip angle whereas in two-wheeler it is mainly because of the camber or the leaning of the vehicle.  Hence you see a flat tread area for passenger car tyre and U-shaped profile for Motorcycle tyre

This U-shaped profile is an important design factor having a direct influence on vehicle performances such as drivability (handling) durability, ride comfort, noise and wear resistance etc.

These tread contours are designed as the arc of one radius, or a combination of arcs with two or more radii. These profiles ensure the required contact patch availability at different lean angles & are controlled by the lean characteristic of the vehicles. It is very critical to balance the performance of front tyre & rear tyre of s motorcycle for precise handling of the vehicle. The contour designs play an important role in front /Rear tyre balance.

Tyre tread pattern design:

Patterns are molded in the tread area of tyre by repeated arrangement of ‘Groves’ or ‘Blocks’ & are generally referred to as “tread pattern”.

Significance of tread pattern: 

Tread pattern plays a vital role in tyre performance such as:

Optimizing the traction on the riding surface

Eliminating aquaplaning

Optimizing the” Wear” of tread area·  

Ensuring the continuity of tyre performance at different wear Stages [ wear %] of tyre.

Rolling resistance of the tyre

Noise generation

roviding a measurable clue to the owner on time for removal /suitability for continuous usage. etc.

Tread patterns not only helps in achieving the target performance, but also impart unique look to tyres and enhance aesthetics

Tyre patterns are broadly classified into 4 Major headings

• Rib patterns
• Directional
• Block [ Knobby]
• Slick tyres [Pattern less]

Selection of which group of patterns is mainly controlled by the terrain of application, e.g. Directional patterns are preferred in paved roads and knobby pattern ae mainly used on off-road applications. Pattern less tyres are normally used in racing track applications to provide maximum traction.  Vehicles are designed to work in a combination of different terrains – similarly, tread patterns also have subgroups– which are optimized to operate in different combination of terrains. E.g. Semi knobby patterns for on – off allocations, High land – minimum grove patterns for Supersport highway applications etc.

Designer alter the direction of the grove, depth of the grove, number of groves, the ratio between Grove area & non grove area [ Land- sea ratio] , shape of the grove, the width of the grove etc. to optimize the performance of tread pattern. These patterns are designed to perform under different dynamic conditions. Nowadays designers seek the help of computer-aided simulations to predict the performance under different loading /riding conditions to optimize the pattern design.

Tyre as an Aesthetic component

The visual appeal of tyre is significant contributor in the overall aesthetics of a motorcycle. Hence in addition to performing all the functional requirements discussed so far, tyres ought to look good too.

The tread pattern should complement the overall styling language of a motorcycle. This attracts the attention of OEM’s vehicle styling studios towards tyre tread designs as well. In fact, most of the new tyre designs are done first at styling studio and then technically optimized by the tyre engineer to guarantee the functionality.

Material design

Tyre is a composite material made of different rubber compounds and reinforcing materials. Right compound and reinforcing material selection are crucial to achieve the target performance of tyre.

• Reinforcing materials:

Reinforcing materials provides the required strength and stiffness for tyre body [carcass]. This includes “tyre cords” used in tyre body ply & “bead wires” used in bead construction of tyres. Most used tyre cord materials are Nylon 6, Nylon 6-6, Polyester, Aramid, Rayon, Steel, etc.

These materials differ in their chemical composition, tensile strength, elongation properties, impact strength, temperature resistance, rubber adhesion, etc. Tyre engineer must choose the right tyre cords depending on the performance demands of the tyre like load carrying capacity, durability, impact resistance, drivability, speed of operations etc. Cost & availability also are few decisive parameters during selection of reinforcing materials.

Tyre Cord denier, cord style, EPI (Ends Per Inch), angle of cords and number of plies affect the strength of a tyre and are chosen based on engineering, and design criteria.

structural durability of a tyre is Primarily determined by the reinforcing material

• Rubber compound design

Each part of the tyre must dispense different functions and are thus designed with different rubber compounds like tread compound, sidewall compound, carcass compound, bead wire coat compound, etc.  Though all these compounds have their own importance, but tread compound selection is the most critical, as it has a direct impact on tyre traction, handling, wear performance, durability, rolling resistance, etc.

• • Trends of tread compound design:    

Even though smaller number of components are used in a motorcycle tyre, than as compared with passenger car tyres, but performance challenges involved in compounding are far more complex considering less area of tyre in contact with road. 3 major performance requirements in motorcycle tread compound are (1) Grip (2) Rolling resistance [fuel efficiency] and (3) Tyre life which is generally referred as the magic triangle in tyre rubber compounding. This is due to the contradictory response of these 3 performance characteristics to rubber compounding approach. For example, improvement in Grip normally comes with an increase in rolling resistance with conventional compounding as both are related to energy loss. It is always a challenge for tyre compounder to improve all three performance requirements together and this calls for the incorporation of advanced polymers and fillers.

Performance priorities for tread compound changes based on operating terrain, type of vehicle, etc. e.g. Street two-wheeler tread compound designs primarily focus on high grip and high-speed capabilities, whereas an on-off application tyre require higher cut and chunk resistance tread compound.

Demand for lower rolling resistance tyre is showing a steady increase Year-on-Year. Major divers for this growing demand are Electric vehicle introduction & increased focus on vehicle fuel efficiency, in few segments. Tread compounds are expected to deliver lower rolling resistance, without compromising the Grip – typical “magic triangle” puzzle for any tyre compounding engineer. Tyre industry can address this challenge by usage of new generation materials like SSBR, functionalized SSBR, high molecular

Design for manufacturing

For success of any product – Design & manufacturing sync is a must. While designing, to accommodate all functional requirements, a designer cannot ignore the significance of manufacturing process. Hence every tyre design is optimized to satisfy both functional & manufacturability needs. This if not done properly may result in suboptimal performance of the product,

Product Performance Testing

It’s important to review and verify the product performance before releasing it into the market. There are a set of Indoor & Outdoor tests for performance review. A few of them are listed below,

Indoor tests: High-speed drum test, Endurance test, Rolling resistance test, Force and moment testing, Stiffness test, Footprint etc.

Outdoor tests: Ride and Handling testing (track, off-road, public road etc.], Braking test [wet, dry], tyre wear test etc.

Blend of Engineering & Art

Being an integral part of vehicle suspension system & only contact point with road, a tyre plays significant role in motorcycle performance [safety, drivability etc.]. In addition to these performance parameters, tyres have significant influence on the overall styling of the vehicle. It complements the primary theme of the vehicle. A right blend of engineering and art is essential for a successful tyre design. One cannot substitute the other. Amongst different steps of tyre design like, dimension finalization, tread design & martial design etc. the most critical step is tread design (profile, pattern & compound)

Few areas designers are focusing today to  meet the near/middle future demands are

• Lowering the rolling resistance – without compromising grip
• Shortening the time to market.
• virtual simulation of tyre performance

 

References

1.  ‘’The pneumonic tyre’’, National Highway Traffic Safety Administration, Feb 2006
2. T. French, Tyre Technology, Hilger, New York, 1989.
3. Mechanics of Pneumatic Tires, S. K Clark, ed., University of Michigan, US Department of Transportation, National Highway Traffic Safety Administration, Washington, DC, 20590, 1891.

     4.  Handbook of vehicle-road interaction: vehicle dynamics, suspension design, and road damage / edited by David Cebon. p. cm. - (Advances in engineering), ISBN 9026515545

    5. “Tyre and Vehicle Dynamics” , Hans B. Pacejka,  Professor Emeritus Delft University of Technology, Consultant TNO Automotive Helmond

     The author is General Manager - Product Development,2&3-Wheeler tyres, CEAT Tyres

The integration of Radio Frequency Identification (RFID) technology into the tyre industry is gaining momentum, offering solutions for traceability, sustainability and lifecycle management. Beontag, in collaboration with Michelin, is spearheading this innovation by jointly designing specialised RFID tags that can withstand the harsh conditions tyres face, such as extreme heat and pressure. The tags store crucial data, enabling efficient recycling, retreading and warranty management. As the tyre industry evolves, RFID adoption is seen as essential for ensuring authenticity, improving asset management and supporting regulatory frameworks. However, challenges remain in scaling production and increasing industry awareness.

Punch card systems, barcodes, dog tags, biometric scanners etc. are all instruments that offer basic information about humans and commodities for identification, authentication, traceability and retrospection.

The tyre industry is similarly standing at a crossroad where the demand for traceability and retrospection is growing. Tyre manufacturers, retailers, retreaders and recyclers are showing a growing exuberance for digital footprints that can record, summarise and authenticate information related to each existing and new tyres throughout the commodities lifecycle.

And the simple solution catering to such demands is a radio frequency identification (RFID) tags. While the use of RFID tags is new within the global tyre market, these have found a stronghold across retail, logistics, manufacturing, healthcare etc.

The tag is changing the game of traceability within tyre markets as the adoption grows. Technological companies are collaborating with tyre manufacturers to develop tailor-made RFIDs.

International RFID and IoT expert Beontag is one such company that has developed RFID tags for the tyre industry. Divulging deep into the engineering mechanics of the tag, APAC Senior Sales Manager Evelyn Ong told Tyre Trends, “RFID technology used in tyres is significantly different from conventional RFID applications due to the harsh conditions tyres endure, such as high temperature, pressure and wear and tear. Unlike RFID tags used in retail or medical settings, tyre RFID tags must be engineered to survive extreme conditions. As a result, traditional RFID designs, which use PET labels and conductive paste for chip attachment, are unsuitable. Instead, tyre RFID tags rely on a mechanically robust and inductively coupled antenna structure.”

“Designing RFID for tyres required a completely new approach, and the current version (generation four) is believed to be durable enough to last the entire lifecycle of a tyre. This innovation aligns with initiatives like the European Digital Product Passport (DPP), which mandates that products must be identifiable throughout their life cycle. Although RFID chips themselves only store a unique identifier (similar to a FASTag or car license plate), all detailed data such as manufacturing date, plant origin, distribution history, usage, retreading details and material composition is stored in backend software systems. As the tyre moves through the supply chain, each stakeholder adds relevant data to the software based on the RFID, creating a comprehensive database that supports traceability and lifecycle management including recycling or retreading,” she added.

The company’s main RFID tag for the tyre industry includes a chip with memory, enabling it to store data and serve as a digital identifier for the physical tyre using radio waves. This transforms a traditional tyre into a digitally traceable product.

Beontag jointly designed this RFID tag with Michelin, exploring the benefits of embedding a chip in tyres for purposes like asset management and product authentication and was instrumental in driving standardisation across the industry. While Michelin is the first tyre manufacturer to roll out the new ‘smart tyres’ with Beontag technology, the manufacturer recently announced a partnership with Kumho Tire and aims to go into partnership with other brands in the near future.

DEMAND AND SUPPLY

The company recently participated in a global tyre exhibition and rationalised its participation with significant long-term potential of the tyre RFID market. “With over 30 billion tyres in circulation globally, the scale of the opportunity is enormous. Having worked in RFID for over 20 years, the technology excels in applications involving products that are physically similar and difficult to differentiate visually like tyres. This makes tyres an ideal use case for RFID,” said the official.

Ong explained that beyond the European Digital Product Passport regulation, a key driver for embedding RFID in tyres is the fundamental need for every product to have a unique identity, whether through a barcode, QR code or digital tag. In the tyre industry, this need has been especially pressing due to the limitations of traditional identification methods like hot stamping, which often wear off over time and result in a loss of traceability.

She noted that the absence of a durable, readable ID creates challenges in verifying authenticity, determining warranty status and tracing the tyre’s origin. For instance, without a reliable identifier, it becomes difficult to confirm whether a tyre is genuinely from Michelin or to retrieve key manufacturing details such as plant location, batch number or intended distribution path.

By embedding RFID tags with unique digital identities, the industry gains the ability to link every part of the tyre’s lifecycle across the value chain. This ensures consistent traceability, facilitates better inventory and warranty management and combats counterfeiting.

“We are actively engaging with the top 10 global tyre manufacturers in the transition towards RFID-enabled tyres. While the European market is leading adoption driven largely by regulatory frameworks, we are also working with tyres manufacturers across the Asia-Pacific region and beyond.

“Although OEMs like Michelin are beginning to integrate RFID tags, starting with high-end passenger tyres, there is a growing and immediate demand from the aftermarket. This secondary market includes fleet operators, leasing companies and pay-per-use models, where the need for tyre tracking is urgent. These businesses want to monitor retreading cycles, ensure asset recovery and verify ownership, especially to prevent tyre theft or unauthorised replacements,” she added.

According to Ong, some aftermarket players are even looking to embed RFID tags independently rather than waiting for OEMs to standardise the process, underscoring strong demand outside the traditional supply chain.

When asked about growth potential between the passenger and commercial segments, she indicated that although current OEM efforts are focused on high-end passenger tyres, interest from the commercial and aftermarket sectors is strong and could drive faster adoption due to practical and financial incentives.

Furthermore, RFID tags play a key role in sustainability by enabling traceability throughout a tyre’s lifecycle. It allows manufacturers to capture crucial data at the point of manufacture, which is essential for tracking and recycling. With RFID, recycling processes become more efficient because tyres can be easily sorted based on type, size and materials. This minimises waste, reduces sorting time and improves the overall effectiveness of recycling efforts.

HURDLES IN ADOPTION

The executive noted that there are unique challenges of designing an RFID tag for tyres given the nature of its operations. To address these hurdles, the company and Michelin jointly designed and extensively validated a specialised RFID tag consisting of a chip and an antenna, which is fully embedded within the tyre.

This tag is designed to be invisible from the outside and integrated into the tyre structure in a way that ensures durability without compromising performance. The antenna’s spring-like structure allows it to expand and contract along with the tyre’s movement without affecting its function.

Crucially, the connection between the chip module and spring antenna is linkless, using inductive coupling instead of mechanical connection. This inductive mechanism ensures reliability even under extreme conditions like high temperature, pressure and physical deformation.

Although the tag is not constantly read during vehicle operation, it must remain functional and readable during inspections or servicing.

Alluding to broader industry challenges towards adoption, Ong said, “Current challenges centre primarily around a lack of awareness and industrialisation of the production process in existing tyre production lines and factories. Unlike retail, where RFID is well-established, the tyre sector is still in the early stages of adoption. Because of this, there is a need to educate the market, build trust and demonstrate real-world use cases. Potential customers are hesitant to act as first movers and prefer to see proven implementations to reduce perceived risk. A hopeful future challenge would be demand outpacing production capacity. However, a more realistic and significant long-term challenge lies in technological evolution, particularly around IC size, performance development and adding more functionality through sensor information.”

INTEGRATING RFIDS

The RFID chip used in tyres stores a minimum of 96 bits of data, which aligns with the standard size modelled after barcodes. This size is sufficient to encode essential identifying information including a serialised number.

While barcodes only identify products at the SKU level, RFID allows each item to have a unique identifier, making it far more powerful for inventory management. At every stage in the tyre’s lifecycle, it is the responsibility of the user or stakeholder to read the RFID tag and input relevant data into the software system, linking it to the tag’s unique identifier.

One of the most compelling applications of tyre RFID is during the tyre’s second life – especially in retreading. In this stage, the retreader can embed a new RFID tag and effectively reset the tyre’s lifecycle. This allows the retreading company to claim and track the work they’ve done including how many times the tyre has been retreaded and when.

Fleet operators or regulators can use this data to verify authenticity, ensure compliance and manage safety.

At the end of the tyre’s life, especially during the recycling stage, RFID continues to offer value by recording the tyre’s complete journey. Recyclers can access a tyre’s full history by ensuring proper handling and reporting.

The key challenge in placing the RFID tag is ensuring its proper location and integration into the tyre’s structure. This process must be carefully controlled as the tag must not only be positioned in the optimal spot but also withstand the stresses and heat of the curing process. If the tag was placed improperly, it could potentially cause issues with its performance, especially in terms of readability after the tyre is fully cured and ready for use.

COMPETITION AND EVOLUTION

Besides Beontag, there are other companies operating within the tyre RFID space. Alluding to the distinction between them, Ong explained, “The main difference of our product lies in the patented POD design (POD = IC module/package). Our product utilises a special alloy for the antenna, which prevents deformation and ensures consistent diameter and gap size. Additionally, the chip packaging has been specifically designed to offer better protection, reducing the risk of damage and ensuring reliable readings.”

She explained that the company’s business case for RFID technology in the tyre industry is clear and it believes strongly in its potential. She emphasised the importance of spreading awareness about the technology, as Europe will be implementing the technology first, but other regions including APAC and the Americas will be catching up as the technology is proven in the coming years.

Swedish automotive software leader NIRA Dynamics AB and BANF Smart Tire System of South Korea have announced a new partnership aimed at significantly enhancing vehicle safety and predictive maintenance for commercial vehicles. The collaboration will see BANF integrate its high-frequency tyre sensors into NIRA's established software ecosystem.

This strategic alliance aims to disrupt Tyre Pressure Monitoring Systems (TPMS), providing commercial fleets and automakers with unprecedented real-time insights into tyre health and road safety. NIRA Dynamics, founded in 2001, is a global automotive software powerhouse with its technologies deployed in over 120 million vehicles worldwide, including an indirect TPMS (iTPMS) that has surpassed 110 million units sold.

Under the agreement, NIRA will incorporate BANF's triaxial tyre sensors into its Road Surface Information (RSI) and Wheel Safety Insights (WSI) platforms. These platforms already utilise existing vehicle sensor data and proprietary algorithms for functions like tyre grip estimation, tread wear analysis and loose wheel detection.

BANF's key innovation lies in its Smart Profiler system, which wirelessly powers internal tyre sensors directly from the vehicle battery, overcoming the challenge of continuous power and real-time data transmission from rotating tyres. This integration will significantly enhance NIRA's capabilities, particularly for monitoring commercial vehicle loads and dual-tyre setups, by providing sensor data at high sampling rates of 1kHz and 4kHz.

Otto Johansson, Head of Innovation at NIRA Dynamics, said, "This collaboration accelerates our vision of creating a comprehensive vehicle intelligence network. While our software solutions already process data from millions of vehicles, adding specialised hardware enables new use cases in predictive maintenance and ADAS applications."

NIRA's evolution from software-only tyre pressure monitoring to multi-layered safety systems is evident in its flagship Tyre Pressure Indicator (TPI) technology, which has eliminated the need for physical sensors in many applications, significantly reducing electronic waste. The company has also collaborated with automotive giants like Volkswagen Group on innovations such as Road Surface Alerts.

The partnership also addresses critical safety needs in commercial vehicles. NIRA's Loose Wheel Indicator (LWI), already deployed in Audi vehicles, will now be extended to heavy-duty vehicles through the BANF collaboration, aiming to mitigate the thousands of annual wheel detachment incidents reported.

For fleet operators, the integrated system promises substantial operational benefits. NIRA's Winter Road Insights product, which helps optimise road maintenance, combined with BANF's wear prediction algorithms, is expected to lead to reduced tyre replacement costs and improved fuel efficiency.

Ron Yoogun Lee, Head of Business Development, BANF, said, “Our goal is to enhance cost-effectiveness, save lives and preserve the environment by digitising tyres, which are the last analog domain in the mobility industry.”

Looking ahead, NIRA's technology roadmap includes developing ‘grip maps’ for SAE Level 2-3 autonomous vehicles and leveraging data from millions of vehicles to create AI models for predictive infrastructure maintenance, further solidifying its position at the forefront of automotive innovation.

AI-powered mobile data capture company Anyline has launched TireBuddy, a smartphone-based app designed to modernise tyre inspections in automotive service bays. The app replaces traditional, manual inspection methods with a standardised digital workflow that delivers consistent, data-backed results and clear customer reports.

TireBuddy offers technicians tools to detect tread depth issues, tyre age, alignment concerns and sidewall damage using AI-powered analysis and visual reporting – without the need for additional hardware. Reports can be instantly shared in digital or printed formats, helping to reduce manual entry errors and increase customer trust.

The launch comes ahead of National Tire Safety Week (30 June 30 – 4 July), positioning the app as a timely solution for shops preparing for the summer travel season.

Lukas Kinigadner, Co-Chief Executive Officer, Anyline, said, “TireBuddy is not only about faster inspections — it’s about more trustworthy ones. We’re helping garages and service centres replace subjective tyre checks with data-backed insights and visual reporting that both technicians and customers can rely on.”

Frederic Baroin, Global Head of Automotive Business at Anyline, said, “TireBuddy empowers technicians with real-time, reliable data that strengthens recommendations and builds customer confidence. We designed it to deliver clarity, not complexity, in every inspection.”

By enhancing inspection accuracy and transparency, Anyline said TireBuddy can also drive higher service approvals and boost shop revenue.

Indian tyre maker CEAT said it has purchased the country’s first Scania 460 G prime mover truck to strengthen its research and development operations as the company pushes to expand in overseas markets.

The Mumbai-based manufacturer described the acquisition as part of efforts to upgrade its commercial vehicle tyre testing capabilities to international standards, particularly for certification in Europe and the United States.

The Scania G460 produces 460 horsepower from its 12.7-litre engine and can handle a gross vehicle weight of 150,000 kilograms (330,693 pounds). The truck features Scania’s Super engine technology, which the Swedish manufacturer says improves fuel efficiency while cutting emissions.

CEAT officials stated that the new testing platform will help accelerate product development and reduce costs while meeting stricter global standards.

“This high-performance vehicle is not just a prime mover — it’s a strategic investment in our Commercial Vehicle Tyre Testing Infrastructure, aimed at elevating our research & development capabilities to meet global standards,” the company said in a statement.

The investment comes as Indian tyre companies grapple with volatile raw material prices while trying to capitalize on strong domestic demand from India’s growing automotive sector. Industry analysts say that manufacturers are under pressure to improve efficiency and expand internationally in order to maintain profitability.

CEAT joins other major Indian tyre makers in ramping up research capabilities as they compete for market share both domestically and abroad.

The company said the new truck will support vehicle dynamics testing and help reduce the time needed to bring new commercial tyre products to market.