Airport Passenger Boarding Bridge Market Size & Share Analysis - Growth Trends & Forecasts (2025 - 2030)

Global Airport Passenger Boarding Bridges Market Trends and Insights

Ongoing Airport Capacity Expansion Programs Across Global Hubs

Global hubs inject multi-billion-dollar sums into terminal upgrades to relieve gate bottlenecks and comply with sustainability codes. Schiphol’s EUR 6 billion (USD 7.07 billion) five-year capital program focuses heavily on Pier C stand additions requiring new bridges. Munich Airport’s EUR 665 million (USD 783.89 million) Terminal 1 pier stretches 360 m and adds multiple new boarding positions. In the United States, FAA-backed megaprojects at John Glenn International, Tampa, and Pittsburgh exceed USD 1 billion and collectively translate into dozens of bridge orders. Asia-Pacific projects such as Long Thanh International in Vietnam and Changi Terminal 5 in Singapore will each deploy several hundred bridges during phased construction. The cadence of these expansions provides sustained, forecastable demand for manufacturers across the airport passenger boarding bridges market.

Surge in International and Domestic Air Passenger Volumes

Passenger throughput rebounded sharply in 2024 and is expected to cross pre-pandemic peaks in 2025 at many hubs, exerting pressure on gate infrastructure. Groupe ADP recorded 363.7 million travellers in 2024, an 8.1% annual jump. Asia-Pacific traffic is projected to hit 2.9 billion by the mid-2030s, nearly tripling today’s levels. Airlines now factor guaranteed bridge access into route economics, and some operators charge premium rates for jet-way use, improving payback for new installations. As passenger peaks intensify, airports accelerate bridge procurement to avoid stand conflicts and to shorten turnaround times—direct catalysts for growth in the airport passenger boarding bridges market.

Transition Toward Energy-Efficient Electro-Mechanical Systems

Electro-mechanical drives lower energy consumption and simplify maintenance relative to hydraulic units, aligning with climate-related operating targets. HÜBNER Group’s Passenger Boarding Bridge Interface 2.0 introduces tilt-correction and touchless flooring to reduce component wear and operator intervention.^{[1]HÜBNER Group, “Passenger Boarding Bridge Interface 2.0,” hubner-group.com} The White House Council on Supply Chain Resilience has highlighted domestic sourcing of transportation infrastructure as a strategic priority, encouraging US airports to adopt locally built electro-mechanical bridges. Net-zero frameworks across Europe equally mandate deeper reductions in gate power draw, encouraging replacements of legacy stock with high-efficiency alternatives. These policies create a structural tailwind for electro-mechanical penetration and reinforce pricing discipline across the airport passenger boarding bridges market.

Growing Integration of Biometric and Automated Boarding Technologies

Bridges are becoming physical touchpoints for seamless passenger identity confirmation. Zayed International’s Terminal A embeds biometric validation at nine locations along the departing journey, including the bridge-to-aircraft interface. National Safe Skies Alliance guidance positions fingerprint, iris, and facial recognition as integral to next-generation e-gates, driving demand for bridges pre-wired for sensors and data backhaul. Airports aim to cut boarding agents and tighten security simultaneously, placing technology readiness squarely in procurement specifications and opening new differentiation avenues for suppliers within the airport passenger boarding bridges market.

Significant Initial Investment Required for Boarding Bridge Installations

Single bridges cost USD 750,000–1 million, creating budget friction for smaller airports and public-sector owners reliant on constrained capital plans. Arizona’s State Aviation System Plan lists USD 8.7 billion of facility needs over 20 years, with passenger boarding bridges a sizeable line item. The result is staggered procurement schedules or reduced scope, especially in cost-sensitive emerging markets, slowing near-term penetration in the airport passenger boarding bridges market.

High Maintenance Complexity and Total Life-Cycle Cost Burdens

Hydraulic seals, telescoping tunnels, and alignment drives impose specialized upkeep demands. Brussels Airport’s EUR 40 million (USD 47.15 million) replacement of 28 bridges aged beyond 25 years underscores the expensive tipping point at which maintenance eclipses replacement.^{[2]Aviation Week Network, “Brussels Airport to Replace 28 Jet Bridges,” aviationweek.com} Airports juggling multiple bridge brands must stock spare parts and train technicians on disparate control systems. These realities push operators to analyze life-cycle cost in depth and prefer standardized fleets, creating opportunities for service-oriented manufacturers while restraining overall growth.

Segment Analysis

By Type: Movable Bridges Deliver Operational Flexibility

Movable boarding bridges generated 60.01% of 2024 revenue and are forecast to compound at 8.45% annually. Their ability to align with diverse aircraft—from regional jets to Code F wide-bodies—enables airports to widen gate utilisation without structural overhauls. Fixed bridges, although cheaper, remain suited to gates dedicated to a single aircraft family. Movable variations now integrate automated docking, collision-avoidance radar, and condition-based maintenance tools, further widening the value gap. At Key West International, eight new glass-clad movable bridges costing USD 1 million each opened in April 2025, eliminating ground-level boarding and increasing turnaround predictability.^{[3]Key West Airport, “Concourse A Project Update,” keywestairport.com}

Bridge manufacturers tailor telescopic ranges up to 36 m and elevation spans exceeding 8 m to cover the majority of global fleets. As a result, the airport passenger boarding bridges market size attributable to movable systems will rise from USD 1.16 billion in 2025 to roughly USD 1.85 billion by 2030, sustaining an outsized contribution to revenue and installed base expansion. Airports in Asia-Pacific and the Middle East, where fleet mix often changes hour-by-hour, assign premium tenders to suppliers that can validate broad aircraft compatibility. With net-zero agendas adding demand for energy-optimised operations, movable units incorporating regenerative drives or on-bridge photovoltaic panels stand to capture an additional share within the airport passenger boarding bridges market.

By Model: Apron-Drive Dominance and Over-the-Wing Momentum

At the stand level, apron-drive bridges, positioned on rotundas, controlled 41.78% of the 2024 turnover. Their robust steel truss, dual telescoping bodies, and rotunda rotation up to 180 degrees make them the workhorse for large-gate layouts worldwide. Yet Over-the-Wing (OTW) bridges are accelerating at 9.01% CAGR, spurred by regional jet proliferation and stand-constrained projects in Japan and India. OTW units mount behind the wing root, freeing a contiguous stand for baggage and catering vehicles.

Dual-boarding configurations also scale, where A350-1000s, B777-9s, and A380s dominate traffic banks. San Francisco International’s dual-level gates enable simultaneous upper- and lower-deck entry, cutting boarding time by almost 40%. Although niche in volume, such specialized models command high ASPs that lift segment revenue. Overall, the airport passenger boarding bridges market continues to diversify its model mix, mapping bridge geometry to fleet planning and terminal flow objectives.

By Technology: Electro-Mechanical Systems Capture Efficiency Gains

Electro-mechanical drives captured 65.29% share in 2024 and are on course for an 8.12% CAGR. They replace hydraulic pumps with gear motors and screw jacks, eliminating oil spill risks and trimming energy draw by as much as 30%. Lifecycle service contracts benefit from predictive analytics, which can interrogate motor torque and temperature in real time. Seen across hubs pursuing carbon budgets, this transition will push the market size contribution of the airport passenger boarding bridges from electro-mechanical models to about USD 1.78 billion by 2030.

Hydraulic units will persist in areas with extreme ambient temperature swings or limited power supply. Yet, new value propositions such as reversible drive-regeneration or battery-backup docking modes are tilting customer preference. Policy incentives under the EU Green Deal and the US Inflation Reduction Act reinforce purchasing equipment, materially reducing Scope 2 emissions, lifting electromechanical adoption further inside the airport passenger boarding bridges market.

By Structure: Steel-Walled Reliability Meets Glass-Walled Passenger Experience

Steel-walled bridges comprised 68.85% of 2024 sales thanks to ruggedness, lower first cost, and compatibility with diverse climates. However, glass-walled units are winning projects at premium terminals where natural light, airfield views, and brand image command weight. Brussels Airport and Schiphol have each pivoted to floor-to-ceiling glazed tunnels that enhance way-finding and reduce perceived waiting time. Changi Terminal 5’s design brief similarly specifies high-transparency boarding corridors.

Thermal performance coatings, laminated safety panes, and smart-tint technology mitigate the glare and heat-load challenges historically associated with glass. As LED lighting and HVAC are embedded into bridge ceilings, utilities can be fine-tuned, cutting operating cost differences with steel. Given these trends, the glass segment’s contribution to the airport passenger boarding bridges market will double between 2025 and 2030, while steel remains foundational for rugged or cost-driven deployments.

Geography Analysis

Asia-Pacific accounts for 31.72% of 2024 revenue and is projected to post the fastest 8.87% CAGR through 2030. China targets more than 270 commercial airports by 2025, and India plans 220 new facilities by 2035, guaranteeing sustained procurement cycles. Vietnam alone expects 30 new airports to serve 653 million passengers by 2030, a scenario that will swell the airport passenger boarding bridges market size on the sub-regional level.^{[4]U.S. International Trade Administration, “India Airport Expansion Outlook,” trade.gov} Simultaneously, mega-projects like Long Thanh International and Changi Terminal 5 each incorporate bridge counts in the high hundreds, setting scale benchmarks across the market.

North America’s outlook pivots on replacement and modernization. The FAA allocated USD 289 million in 2025 Airport Infrastructure Grants to 129 US airports, many earmarked for passenger boarding bridge programs. JFK’s USD 4.2 billion Terminal 6 will field 10 gates sized for wide-body aircraft, while Pittsburgh, Tampa, and Boston airports embed bridge enhancement inside multi-billion redevelopment packages. Sustained spend on life-cycle upgrades keeps the region critical to global vendor order books even as greenfield construction slows.

Europe maintains steady demand via renewal and sustainability retrofits. Schiphol’s Pier upgrades, Munich’s new T1 satellite, and Heathrow’s GBP 2.3 billion (USD 3.13 billion) two-year acceleration plan include bridge modernizations to align with net-zero ops. EU regulations on energy performance further channel purchases toward electro-mechanical platforms, deepening unit values within the airport passenger boarding bridges market.

The Middle East is witnessing outsized bridge requirements at giga-projects. Dubai’s USD 35 billion Al Maktoum expansion foresees 400 stands equipped with more than 800 bridges, while Saudi Arabia’s King Salman International plots a multistage rollout to 120 million passengers by 2030. Zayed International’s biometric-ready bridges highlight the region’s swift move toward tech-integrated infrastructure. Across Africa, growth is led by Addis Ababa and Nairobi expansions, though volumes remain smaller.