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Tunnel boring machine

A tunnel boring machine (TBM) is a specialized mechanical device designed to excavate s by rotating a cutter head equipped with disc cutters or other tools that grind through soil, rock, or mixed ground, creating a circular cross-section while simultaneously installing supportive segments behind the advancing face. These machines, often exceeding 15 meters in diameter and weighing thousands of tons, are propelled forward by hydraulic jacks pressing against the installed , with excavated material removed continuously via conveyor belts, pipelines, or screw conveyors depending on the ground conditions. The concept of mechanized tunneling originated in the early 19th century with Marc Isambard Brunel's invention of the tunneling shield in 1818, patented for use in the project starting in 1825, which allowed workers to excavate safely under the river by providing overhead support against collapse. This rectangular shield marked the precursor to modern TBMs, influencing subsequent developments like James Greathead's improved rotary shield in the 1870s for London's subway system. The first fully mechanized TBM emerged in the mid-20th century, with James S. Robbins designing a rock-cutting machine in 1952 for the project in , , featuring drag bits and roller cutters for efficient hard-rock excavation. TBMs have revolutionized by offering safer, more precise, and faster alternatives to traditional drill-and-blast methods, particularly for long tunnels in or environmentally sensitive areas. Key types include open-face TBMs for stable hard rock, earth pressure balance () machines that maintain face stability in cohesive soils by controlling pressure, slurry shield TBMs for water-saturated soft ground using suspension to support the face and transport spoil, and double-shield TBMs for fractured rock with immediate lining installation. These variations allow adaptation to diverse geologies, enabling projects like the (completed 1994, using 11 TBMs to bore 50 km). Essential components of a TBM include the cutterhead with replaceable disc cutters for rock fracturing, thrust jacks for , a trailing backup system housing generators, control rooms, and , as well as erectors for placing segments that form the tunnel lining. Advances in TBM technology, such as , real-time ground , and hybrid designs for mixed-face conditions, continue to enhance and minimize surface disruption in applications ranging from transportation to utility corridors and hydroelectric schemes.

Fundamentals

Definition and Purpose

A tunnel boring machine (TBM) is a specialized mechanized apparatus designed for excavating tunnels through , , or formations in a continuous, full-face . It operates as a rotary excavation , utilizing a rotating cutterhead equipped with disc cutters or scraper tools to and remove material from the tunnel face, while the machine advances forward under hydraulic . Concurrently, many TBMs install supportive lining, such as segments or rock reinforcement, behind the advancing face to provide and stability. This integrated process distinguishes TBMs from other excavation techniques, enabling efficient tunnel creation with minimal overbreak. TBMs emerged as a transformative alternative to traditional manual labor and explosive-based drilling methods, particularly for long-distance tunnels where conventional approaches were labor-intensive, time-consuming, and prone to delays from cyclical operations. By mechanizing the excavation, TBMs significantly enhance efficiency through continuous advancement rates that can exceed those of drill-and-blast techniques, reducing overall project timelines and costs in suitable ground conditions. Moreover, they prioritize by shielding operators from direct exposure to unstable faces, eliminating the need for explosives that pose risks of misfires or toxic fumes, and limiting intervention in hazardous environments. The primary purposes of TBMs span sectors, including the development of transportation networks such as systems and underpasses to alleviate and enable subterranean routes. They are also essential for utility corridors, facilitating the installation of , , and cable lines beneath existing without interrupting surface activities. In operations, TBMs create access tunnels, shafts, and haulage ways, supporting in challenging underground settings. Among the key benefits, TBMs minimize surface disruption by confining operations underground, preserving overlying structures and landscapes during or environmentally sensitive projects. Their guidance systems ensure precise tunnel alignment, adhering to design tolerances that enhance structural integrity and reduce remedial work. Additionally, by automating much of the excavation and support installation, TBMs drastically cut worker exposure to geological hazards like rockfalls or flooding, thereby lowering injury rates and manpower requirements compared to legacy methods.

Basic Components

A tunnel boring machine (TBM) consists of several essential mechanical elements designed to facilitate controlled excavation through or . At the forefront is the cutterhead, a rotating fitted with disc cutters for fracturing hard or drag bits and scrapers for softer soils, applying concentrated to chip away material from the tunnel face. The cutterhead typically includes integrated buckets or scrapers to collect debris immediately after cutting, ensuring efficient material handling during rotation. In shielded TBMs, the shield body forms a protective cylindrical casing that encloses the cutterhead and extends rearward, safeguarding the machine's internal components from cave-ins or ground pressure. This structure maintains and allows for the installation of temporary s as the machine advances. Trailing structures, often referred to as the backup system, follow the shield and provide platforms for additional equipment, including lining erectors and utility lines, enabling continuous operation over long distances. In open-face TBMs, hydraulic gripper pads press against the tunnel walls to provide reaction force for advancement and . Propulsion is achieved through hydraulic thrust jacks that push the machine forward, typically exerting forces exceeding several thousand tons; in shielded TBMs against installed lining segments, and in open-face TBMs against the tunnel face while anchored by gripper pads on the tunnel walls. Muck removal systems handle the excavated material, utilizing conveyor belts in dry conditions to transport spoil rearward or pipelines in fluid-saturated environments, where mixture suspends and carries debris to a separation plant. Power and control systems integrate hydraulic actuators for precise movement of the cutterhead, thrust jacks, and grippers; electrical generators or transformers to supply energy for motors and lighting; and an array of sensors monitoring vibration, pressure, alignment, and temperature to ensure operational safety and accuracy. These components work in sequence: the cutterhead excavates while thrust jacks advance the shield or machine, muck is simultaneously removed via conveyors or pipelines, and sensors feed data to control systems for real-time adjustments, allowing the TBM to progress steadily while maintaining tunnel integrity.

History

Early Developments (1800s–1900s)

The development of tunnel boring technology in the 19th century began with rudimentary shielding mechanisms to address the dangers of excavating in unstable, water-bearing soils. In 1818, patented the first tunneling shield, inspired by the protective behavior of shipworms, which allowed workers to excavate safely behind a movable iron frame while installing brick linings to prevent collapses. This rectangular shield was employed during the construction of the starting in 1825, marking the initial practical application of mechanized protection in soft ground tunneling, though progress was slow due to frequent flooding and structural failures. Building on Brunel's concept, James Henry Greathead introduced a more efficient cylindrical shield in 1869, featuring a rotary cutting edge and screw jacks for advancement, which significantly accelerated tunneling in waterlogged conditions. Greathead's device was first used in 1870 for the Tower Subway under the River Thames in , where it bored a 7-foot diameter pilot tunnel at a rate of about 7 yards per day, enabling the installation of cast-iron segments for lining. This innovation was pivotal for the expansion of 's sewer and subway systems in the 1870s and 1880s, overcoming key challenges like soil instability by maintaining constant pressure at the face and allowing simultaneous excavation and lining. In the 1880s, Colonel Frederick Beaumont advanced the field with a compressed-air-powered boring machine, designed in collaboration with Thomas English for the aborted first project. Deployed in 1880 near , this prototype featured rotating cutters driven by pneumatic engines, capable of excavating chalk at rates up to 16 feet per day, and incorporated Beaumont's earlier patents for air-tight shielding to counter water ingress and ground collapse in soft strata. Although the project halted after boring approximately 1.8 km (1.1 miles) due to , the machine represented an early shift toward mechanized full-face excavation, influencing subsequent designs for urban tunneling. Across the Atlantic, early 19th-century efforts culminated in the United States with the deployment of a cast-iron boring machine in 1853 for the Hoosac Tunnel in Massachusetts, the first mechanical device used in American tunneling, which drilled through hard schist at limited speeds of a few inches per hour but demonstrated the feasibility of machine-assisted boring over manual methods. By the 1890s, experimental shields similar to Greathead's were tested for subway projects, addressing soft ground challenges through compressed-air compartments. This era's techniques were critically applied in the early 1900s during the Hudson River tunnels construction (1904–1908), where teams of miners advanced shields under compressed air to excavate water-saturated silt and sand, preventing cave-ins but at the cost of numerous decompression sickness fatalities among workers, highlighting the era's reliance on manual labor within mechanical frameworks.

Modern Advancements (1900s–Present)

The mid-20th century marked a pivotal era for tunnel boring machine (TBM) development, with significant breakthroughs enhancing efficiency in challenging geologies. In 1952, James S. Robbins introduced the first modern TBM for the Project in , , specifically engineered for hard rock tunneling using drag bits on the cutterhead, which allowed for more consistent penetration rates compared to earlier manual methods. This innovation shifted tunneling from labor-intensive blasting to mechanized excavation, enabling faster progress in projects like hydroelectric dams. Building on this, the 1970s saw the advent of double-shield TBMs, with Robbins delivering the first such machine in 1972 for Italy's Orichella project; this design featured dual telescoping shields to protect workers and support the tunnel face in fractured or mixed ground conditions, facilitating simultaneous excavation and lining installation. Entering the late 20th and early 21st centuries, TBMs emerged as a key advancement for high-water-pressure environments, exemplified by their use in the project during the 1990s, where machines from manufacturers like Robbins and employed slurry to stabilize the face under the , preventing collapses in water-bearing and clay. This technology bridged earlier shielded concepts to modern applications, maintaining pressure balance during marine tunneling. In the 2010s, integrations progressed, as seen with the TBM in Seattle's replacement project (2013–2017), which relied on inertial navigation for steering in the absence of GPS and required a crew of about 25 for oversight; however, prolonged delays from mechanical failures, including a two-year halt due to overheating and obstructions, underscored the need for enhanced and AI-driven monitoring to preempt issues in future machines. Post-2020 innovations have focused on hybrid TBMs to address variable geologies and promote climate-resilient infrastructure, with Herrenknecht unveiling advanced models in 2023 that seamlessly switch between earth pressure balance and slurry modes for soft-to-hard rock transitions, reducing environmental impacts through optimized energy use and minimal spoil disruption. These machines are integral to mega-projects like the UK's HS2 high-speed rail, where multiple TBMs achieved key breakthroughs in 2025, completing twin-bore tunnels under Birmingham and preparing for Euston extensions to enhance sustainable transport networks. Similarly, extensions to Switzerland's Gotthard Road Tunnel incorporate state-of-the-art hybrid TBMs for a second road tube, with TBM handover in 2024 and boring launched in 2025 to navigate Alpine faults while improving traffic resilience against climate-induced hazards like avalanches. Global adoption has been driven by leading manufacturers forming consortia since the , with —founded in 1977—standardizing designs through innovations like the 1985 Mixshield TBM, which adaptable face support modes have become industry benchmarks, enabling consistent performance across diverse international projects from urban subways to transcontinental links. This collaborative approach has scaled TBM diameters up to 17 meters and integrated modular components for faster deployment worldwide.

Design and Classification

Shield and Support Types

Tunnel boring machines (TBMs) are classified based on their shielding and support mechanisms, which are designed to stabilize the tunnel face and surrounding ground during excavation, adapting to varying geological conditions such as rock stability, soil cohesion, and water presence. These classifications ensure safe advancement by providing thrust reaction, face support, and protection against collapse, with types ranging from open designs for hard rock to pressurized shields for soft, water-bearing grounds. The choice of shield and support type directly influences the machine's performance, safety, and suitability for specific ground conditions, prioritizing minimal disturbance and efficient muck removal. Open or gripper TBMs are utilized in stable, conditions where no full is required, relying on gripper pads mounted on the machine body to press against the tunnel walls for thrust generation during excavation. These machines feature an open cutterhead design that allows immediate access for installing rock supports like bolts and mesh directly behind the face, making them ideal for solid with low water inflow and minimal risk of collapse. In such environments, gripper TBMs achieve high advance rates due to their simplicity and lack of shielding, though they are unsuitable for unstable or soft grounds where face support is needed. Single-shield TBMs incorporate a single cylindrical shield enclosing the cutterhead and thrust cylinders, providing protection for the working chamber in stable to moderately stable or consolidated soils without significant water pressure. The shield reacts against the installed tunnel lining, typically segments erected within the shielded tail, to advance the machine while minimizing ground disturbance in non-water-bearing conditions. This design supports segmental lining installation concurrently with excavation, enhancing efficiency in medium-hard where open-face methods might risk instability. Double-shield TBMs feature a telescoping dual-shield system combining an outer fixed with an inner telescopic , enabling thrust from both gripper pads against the walls and reaction against the for enhanced stability in variable or mixed . Suited for consolidated with potential instability, such as fault zones or squeezing grounds, the inner allows continued operation even if the outer jams, while supporting immediate installation. This configuration excels in challenging conditions like medium-hard transitions, offering flexibility and safety through redundant support mechanisms. Earth pressure balance (EPB) shields maintain face stability in soft, cohesive soils by using the excavated material as a plug within the cutterhead chamber, controlled via a to balance earth pressure and prevent collapse or excessive settlement. These machines are particularly effective in urban settings with silty clays or fine-grained soils under moderate water pressure, where the conditioned muck provides passive support without external fluids. The regulates discharge to sustain pressure equilibrium, allowing safe excavation in low-to-medium permeability grounds while integrating with segmental lining for immediate tunnel support. Slurry shields employ a bentonite-based slurry injected into the cutterhead chamber to support the face in cohesionless, water-bearing sands or gravels, creating a hydraulic suspension that counters inflow and stabilizes unstable soils. The excavated muck is mixed with the and transported via pipelines to a separation plant, where solids are filtered and the recycled, making this type ideal for high-permeability, saturated grounds prone to collapse. This pressurized system minimizes surface in granular formations, with the slurry's density and viscosity tuned to match site-specific hydrostatic pressures for effective face control.

Wall and Size Variations

Tunnel boring machines (TBMs) incorporate various wall support strategies tailored to ground conditions and project requirements, with segments commonly erected immediately behind to provide and prevent ground collapse during excavation. These segments form a continuous ring lining that supports the tunnel perimeter, often installed using erector arms on the TBM's backup system to ensure precise placement and alignment. Among concrete lining designs, bolted precast segments are widely used, where steel bolts connect adjacent segments to offer temporary reinforcement until the grout annulus between the lining and excavated wall fully cures and bonds. This bolted configuration enhances joint integrity, particularly in soft ground, by distributing loads and minimizing water ingress through double-gasketed interfaces. Non-bolted alternatives, relying on keyways or shear keys, are also employed in some cases to reduce assembly time, though bolted systems predominate for their added security in variable conditions. In contrast, main beam TBMs, suited for stable rock formations, feature an open-trailing configuration that exposes the excavated face for direct manual intervention, allowing installation of rock bolts, steel arches, or without a full concrete lining. Rock bolts are systematically inserted into the crown and sidewalls to anchor the rock mass, while steel arches provide immediate arching support in fractured zones, often combined with for a reinforcement approach. This method avoids the need for immediate precast segments, reducing material costs in competent rock but requiring careful monitoring to prevent instability. TBM diameters vary significantly to match project scales, with classifications broadly dividing machines into , , and categories based on bore size. , typically under 2 meters in diameter, are used for tunnels and jacking, enabling minimally invasive excavation for sewers or cables in settings. TBMs, ranging from 4 to 10 meters, serve and projects, balancing with maneuverability in mixed ground. exceed 15 meters, as exemplified by the 17.45-meter-diameter Bertha machine deployed for Seattle's replacement, which accommodated multi-lane road tunnels while managing high pressures. To address project-specific needs, such as varying or , TBM designs incorporate modular adaptations for mid-project diameter adjustments and navigation through curves or . Variable-diameter TBMs, like the in-situ adjustable model developed for China's project in 2025, allow cutterhead reconfiguration from 8.83 to 12.45 meters without extraction, minimizing downtime and enabling transitions in tunnel cross-section. For and , lining segments are engineered with flexible joints to accommodate up to 1-2 degrees of deviation per ring, ensuring uniform wall support while the TBM's steering cylinders maintain and prevent excessive on the backup structure.

Operation and Systems

Tunneling Process

The tunneling process with a tunnel boring machine (TBM) follows a repetitive designed to excavate, remove spoil, and stabilize the tunnel in a continuous or semi-continuous manner. This typically advances the machine 1–2 meters per stroke, depending on the machine type and ground conditions. The process begins with the rotation of the cutterhead, which is pressed against the tunnel face by hydraulic cylinders, allowing cutters or other tools to and remove material from the face. Once excavation occurs, the resulting muck—excavated or —is immediately extracted to prevent buildup in the excavation chamber. In hard applications, buckets attached to the cutterhead scoop the material, directing it through chutes onto a belt conveyor that transports it rearward for disposal outside the tunnel. For soft ground or mixed conditions, slurry systems suspend the muck in a mixture, which is then pumped out via pipelines, ensuring efficient removal while maintaining face . This muck extraction is integral to each , minimizing downtime and enabling steady progress. Immediately after muck removal, the cycle proceeds to lining installation, where an erector arm—a hydraulic manipulator—positions and assembles segments to form the tunnel lining. These segments are pushed into place around the perimeter behind or main body, providing immediate and serving as the reaction base for in subsequent strokes. mechanics rely on hydraulic that exert against these installed linings (or gripper shoes in open-mode TBMs) to drive the entire machine forward. Steering is achieved through articulation of the cutterhead and selective adjustment of thrust cylinder extensions, allowing precise alignment adjustments over the machine's length. Real-time monitoring is essential throughout the cycle to adapt to varying . Sensors track parameters such as , , and , while probe —using mounted drills near the face—samples ahead to detect changes in quality or inflow, prompting adjustments to operational settings for and efficiency. The cutterhead components, including basic drive motors and cutting tools, play key roles in these steps by enabling controlled excavation. Tunnel completion rates depend on factors like ground stability and machine specifications, generally ranging from 10 to 50 meters per day in typical operations, with higher rates possible in favorable conditions such as uniform . If ground conditions change significantly, the TBM may transition to open excavation methods at the endpoint to connect with surface structures.

Backup and Support Systems

Backup gantries, also known as trailing gantries, form the modular backbone of TBM support infrastructure, consisting of multi-level decks that trail behind the machine to facilitate ongoing operations. These gantries house essential logistics components, such as rails for muck transport cars or conveyor systems that extend as the tunnel advances, ensuring efficient removal of excavated material from the face to the surface. Ventilation ducts and utility piping for water, compressed air, and power distribution are integrated into the gantry structure, maintaining environmental control and operational continuity throughout the excavation process. Support features within the backup system include grouting setups for stabilizing the surrounding and filling voids behind the segmental , typically involving mixing plants and pumps mounted on the gantries to inject cementitious or chemical grouts as needed. Electrical substations and transformers provide to the TBM and trailing , often with redundant systems to prevent . On-site workshops equipped with tools and spare parts storage allow for immediate repairs, minimizing interruptions during long drives. These elements integrate seamlessly with the forward tunneling process by supplying necessary resources without halting excavation. Safety integrations in the backup systems prioritize worker protection in the confined tunnel environment, featuring emergency escape routes such as refuge chambers mounted on gantries for rapid evacuation during incidents. Fire suppression systems, including automated aerosol or water-based units, are installed across electrical and mechanical areas to mitigate fire risks from hydraulic fluids or electrical faults. Pressurized workspaces, particularly in earth pressure balance TBMs, incorporate hyperbaric chambers to manage decompression for workers exposed to elevated pressures, while gas detectors and emergency stop mechanisms ensure real-time hazard response. For slurry TBMs, slurry pipeline extensions handle slurry lines, routing conditioned material away from the face while maintaining pressure balance and safety protocols.

Applications

Urban and Near-Surface Projects

Tunnel boring machines (TBMs) face unique challenges in urban environments due to the proximity to existing , requiring stringent control of vibrations to prevent structural damage to and disturbances to . Effective management is essential to mitigate risks of flooding and soil instability, particularly in water-bearing strata common beneath cities. Coordination with surface utilities, , and ongoing urban activities demands precise scheduling and real-time adjustments during TBM operations. In near-surface projects, where overburden is shallow, adaptations include deploying smaller-diameter TBMs to minimize excavation volume and reduce disturbance in constrained spaces. Low-noise cutterheads and vibration-dampening technologies help limit acoustic and seismic impacts on nearby structures. systems, using sensors to track , enable immediate corrective actions like adjusting TBM advance rates or injecting to stabilize . Earth pressure balance (EPB) shields are often employed in these settings to maintain face stability in soft, conditions. The project in (2009–2018) exemplifies these approaches, utilizing pressure-balance TBMs to navigate high and mixed soils while implementing vibration monitoring to protect heritage buildings and minimize over 90% of construction complaints related to . In Tokyo's expansions post-2000, shield TBMs adapted for soft alluvial soils employed compact designs and settlement controls to tunnel beneath densely populated areas with minimal surface intervention. Similarly, New York's (phases starting 2007) relied on gripper TBMs in Manhattan's varied urban geology, including soft ground, to bore 1.8 miles of tunnel while coordinating with active street life. Compared to traditional cut-and-cover methods, TBM tunneling in urban and near-surface projects significantly reduces traffic disruptions and surface closures, preserving business operations and commuter flow during . This approach lowers overall environmental impact by limiting excavation exposure and utility relocations in built-up areas.

Major Infrastructure Examples

One of the most iconic applications of tunnel boring machines (TBMs) in transportation infrastructure is the , connecting , , with Coquelles, , via two 50 km rail tunnels and a central service tunnel completed in 1994. Eleven TBMs—six launched from the and five from —bored through chalk marl at depths up to 75 meters beneath the , achieving a breakthrough in December 1990 after starting in 1988. The project, costing approximately £12 billion (equivalent to about £25 billion in 2023), represented an engineering feat with TBMs advancing up to 250 meters per week under high groundwater pressure, enabling travel and reducing London-Paris journey times to 2.5 hours. The in , opened in 2016, stands as the world's longest railway tunnel at 57 km, bored using a fleet of four 15.24-meter-diameter hard rock TBMs from that excavated the twin single-track tubes through the at depths exceeding 2,400 meters. Construction began in 2002, with main tunneling from 2006 to 2010, involving the removal of 28.2 million tonnes of rock and achieving record advance rates of up to 56 meters per day in favorable sections. Costing CHF 12 billion (about $13.7 billion USD), the tunnel cut Zurich-Milan travel time from four hours to 2.5 hours, boosting freight capacity by 50% and demonstrating TBM efficacy in complex geology with minimal surface disruption. In utilities and hydroelectric projects, the Snowy 2.0 pumped storage scheme in utilizes TBMs to bore a 27 km headrace tunnel linking Tantangara and Talbingo reservoirs, enhancing storage with 2,000 MW capacity. Launched in 2019, the project employs four 11.86-meter-diameter TBMs, with tunneling ongoing into the 2020s amid geological challenges like dikes; initial costs estimated at AUD 2 billion have escalated to over AUD 12 billion as of 2025, with further increases under reassessment, and full commissioning targeted for 2028. This initiative, adding 350 GWh of storage, exemplifies TBM use in long, curved alignments for hydro infrastructure, supporting 's grid stability. The repair in the United States addressed leaks in the world's longest water tunnel (137 km) by boring a 4 km bypass tunnel under the using a 3.66-meter-diameter Robbins single-shield TBM, completed in 2019 after starting in 2017. This USD 2.1 billion upgrade (part of broader costs) diverts water around damaged sections, preserving supply for over 9 million New Yorkers without service interruption, and highlighted TBM precision in soft ground at 183 meters depth to avoid contaminating the . Recent transportation projects from 2020 to 2025 further illustrate TBM advancements, such as the UK's , where ten TBMs are boring over 43 km of twin-bore tunnels, including the 16.9 km Northolt Tunnel and 8.4 km , with drives launched since 2021. Phase 1 costs are estimated at £54-66 billion (2023 prices) as of early 2025, with over £40 billion spent by mid-2025 and tunneling for the London-Birmingham segment completed as of October 2025, enabling 360 km/h speeds and reducing journey times by up to 50%. In , the (HSR) project plans approximately 100 km of tunnels across segments like the ~16 km (10-mile) bores, preparing for mega-TBMs (up to 10 meters diameter) in the late , though actual tunneling awaits funding; total costs exceed $100 billion, aiming for 350 km/h service by the to connect major cities.

Challenges and Innovations

Technical and Operational Challenges

Tunnel boring machines (TBMs) encounter significant geological challenges, particularly in abrasive rock formations where accelerates due to and rock-machine interactions. In conditions, disc cutters experience substantial wear, often requiring frequent replacements to maintain cutting efficiency, with metallurgical analyses revealing failures from and after extended use. For instance, studies on micro-TBMs highlight that remains a persistent issue, leading to increased and costs during tunneling through quartz-rich or basaltic rocks. Similarly, in squeezing ground, face poses a major , as converging rock masses can deform the tunnel face, obstruct cutterhead rotation, and compromise overall stability, sometimes rendering TBM drives infeasible without intervention. Operational challenges further complicate TBM deployment, including unexpected machine breakdowns that halt progress for months or years. A notable example is the 2013 incident with the TBM in , where the machine struck an eight-inch steel pipe during excavation, causing overheating, bearing failure, and a prolonged shutdown requiring extensive disassembly and repairs. High upfront costs also strain project budgets, with TBM units typically ranging from $10 million to $100 million depending on diameter, shield type, and customization, representing a substantial capital investment that demands precise planning to avoid financial overruns. Logistical hurdles arise in muck disposal, especially in remote or mountainous areas where transporting large volumes of excavated material—often thousands of cubic daily—requires robust conveyor systems, rail haulage, or pipelines, yet faces delays from limitations and regulatory approvals for spoil sites. Worker for operations in confined spaces within the TBM presents additional challenges, as the enclosed trailing gear and limited access heighten risks of hazardous atmospheres, structural collapses, and restricted evacuations, necessitating specialized in , response, and handling to . To mitigate these issues, pre-tunneling geotechnical surveys are essential, involving , geophysical probing, and testing to predict abrasivity, squeezing potential, and , thereby informing TBM selection and operational parameters as recommended by international guidelines. Modular repair designs facilitate on-site interventions, allowing components like cutterheads or systems to be accessed and replaced without full , as demonstrated in retrofit solutions for ground convergence problems that reduce in challenging conditions.

Recent Technological Advances

In the 2020s, has significantly enhanced tunnel boring machine (TBM) efficiency through AI-driven and autonomous steering systems. These technologies use algorithms to analyze from sensors, forecasting equipment failures and optimizing operational parameters to minimize . For instance, The Boring Company's Prufrock series, introduced in the early 2020s, incorporates advanced for remote operation and continuous excavation, targeting tunneling speeds exceeding 1 mile per week—six times faster than previous models—while reducing human intervention in hazardous environments. Similarly, integrated connectivity enables autonomous steering adjustments based on geological data, allowing TBMs to maintain precise alignments without constant operator input. Sustainability efforts have focused on electric TBMs and resource-efficient systems to lower emissions and environmental impact, aligning with broader regulatory pushes like the . Battery-powered and hybrid energy storage solutions, such as those deployed in Australian projects, power TBM operations with renewable sources, cutting diesel dependency and by up to 50% in some cases. In slurry-based TBMs, recycled water systems treat and reuse process water, as demonstrated in Melbourne's project, where over 140 Olympic-sized swimming pools' worth of water was conserved, reducing freshwater consumption and waste disposal needs. These innovations align with calls for stricter EU regulations on non-road mobile machinery (NRMM) emissions to promote zero-emission technologies, as outlined in 2024 policy briefings. Hybrid TBM designs have advanced to handle variable geology by enabling mid-tunnel mode conversions, improving adaptability in complex projects. Herrenknecht's Multi-mode TBMs, for example, switch seamlessly between earth pressure balance (), slurry support, and open modes using modular components; Herrenknecht's Variable Density TBMs allow four-mode transitions ( closed mode, slurry with low-density support, slurry with high-density support, and open hard rock mode) without major modifications for heterogeneous ground conditions. Complementing these, 2020s robotics have automated cutterhead maintenance; teleoperated manipulators with eccentric-locking mechanisms replace worn disc cutters in pressurized environments, tested successfully on operational TBMs to enhance safety and reduce intervention times. Further innovations include climate-adaptive materials and digital integration for resilient operations. Eco-friendly additives, such as biodegradable soil conditioners and low-emission lubricants, protect TBM components while minimizing ecological footprints in varying climatic conditions, as seen in China Railway Engineering Group's (CREG) green TBMs launched in 2025. (BIM) integration has revolutionized planning and execution, enabling virtual simulations of TBM paths and fusion for predictive adjustments, which has optimized resource use in projects like European rail tunnels since the early 2020s.

References

  1. [1]
    [PDF] Tunnel Operations, Maintenance, Inspection, and Evaluation ...
    Bored Tunnels. 1.4.1.3. A Tunnel Boring Machine (TBM) is a shield with bits mounted on a rotating cutter head that excavates a circular opening. Ground ...
  2. [2]
    [PDF] FHWA Technical Manual for Design and Construction of Road Tunnel
    This FHWA manual is intended to be a single-source technical manual providing guidelines for planning, design, construction and rehabilitation of road tunnels, ...
  3. [3]
    Thames Tunnel | ASCE
    But in 1818, Marc Isambard Brunel patented a revolutionary new tunneling device: a special rectangular, cast-iron shield that supported the earth while ...
  4. [4]
    Tunnel Boring Machines: Revolutionising Underground Co
    The first tunnelling machine was designed by engineer Marc Brunel (son of Isambard) in the 19th century. It was used to help build the Thames tunnel in 1843.Missing: key facts<|control11|><|separator|>
  5. [5]
    History - The Robbins Company
    In 1952 James Robbins developed the first modern Tunnel Boring Machine for the Oahe Dam Project in South Dakota, USA. The machine used drag bits and dumbbell- ...
  6. [6]
    [PDF] Tunnel Boring Machines - IMIA
    The tunnel boring machine is a machine which has been developed in recent years and has revolutionised the tunnelling industry both making tunnelling a safer, ...
  7. [7]
    The Evolution of Tunnel Boring Machines - Construction Physics
    Oct 6, 2023 · TBMs have evolved along two parallel paths of technological development. The first is the development of machines for tunneling through soil and soft ground.Missing: definition facts
  8. [8]
    Tunnel-boring machine: how does it work, types and requirements
    A tunnel-boring machine (TBM) is a machine that can dig full-face tunnels underground; this means it is done in a single mechanical operation by drilling.
  9. [9]
    Tunnel Boring Machine - an overview | ScienceDirect Topics
    A tunnel boring machine (TBM) is a complex electromechanical product used in tunnel construction that can exhibit more complicated fault situations.
  10. [10]
    BORED TUNNELS
    What is tunnel boring? The bore construction method for tunnels involves digging a tube-like passage through the earth. This usually refers to mountain ...
  11. [11]
    Tunnel Boring Machines: Shipping These Underground Giants
    May 18, 2024 · These engineering giants are pivotal in constructing subways, roads, and utility pathways and can be used in the mining industry.
  12. [12]
    IoT: who are the leaders in tunnel boring machines for the mining ...
    Apr 30, 2024 · TBMs have been used for a variety of purposes as part of new and expanding mining projects, including new access, ore and waste conveyance, ...
  13. [13]
    Tunnel Boring Machine (TBM): Crucial (and optimal) systems and ...
    Tunnel Boring Machine (TBM) have revolutionized the approach to tunnel construction providing a precise and efficient mechanized solution.
  14. [14]
    Gripper TBM - Herrenknecht AG
    Gripper TBMs are for hard rock, using a rotating cutterhead and gripper shoes for bracing. They are efficient for fast tunnelling in hard rock.<|separator|>
  15. [15]
    EPBS Shield - About Tunnelling - ITA-AITES
    Main components · Cutterhead: Which rotates with cutting spokes · Protective Shield similar to that used for closed slurry shields · Screw conveyor, which ...
  16. [16]
    Slurry Shield - About Tunnelling - ITA-AITES
    Main components · Cutterhead, fitted out with discs, blades or teeth · Protective Shield, containing all the main components of the machine. · Longitudinal Thrust ...
  17. [17]
    Tunnel Boring Machines - The Robbins Company
    Robbins TBMs are reliable, fast, and efficient, with proven designs for rock tunnels. They offer support, spare parts, and training, and are designed for ...Double Shield · Single Shield · Crossover Machines · Back-Up Systems
  18. [18]
    [PDF] Tunnel Boring Machines - Kawasaki Heavy Industries
    One is a disk- front-crushing-type (mainly used for Slurry Shield. Machines) which crushes boulders by front disk and then carries them into the cutter chamber.
  19. [19]
    [PDF] Instrumentation of a Reconditioned Robbins Tunnel Boring Machine
    Dec 20, 2000 · The instrumentation installed on this “vintage” TBM included temperature sensors, vibration sensors (accelerometers), hydraulic pressure sensors ...
  20. [20]
    Tunnel Boring Machines: How They Work and How They are Installed
    Feb 3, 2025 · How Tunnel Boring Machines Work · The cutter head rotates and excavates the tunnel face · Hydraulic jacks push the machine forward · Precast ...
  21. [21]
    James Henry Greathead | Railway Engineer | Blue Plaques
    Completed in 1870, it was built using a cylindrical boring device designed by Greathead that enabled tunnels to be driven through soft, waterlogged ground. He ...
  22. [22]
    James Greathead and tunnels under London
    Even so, when the French engineer Marc Brunel began work on the first tunnel under the River Thames in 1825, he was confident that his new 'shield' invention ...
  23. [23]
    Channel Tunnel 1880 Attempt - Subterranea Britannica
    Dec 1, 1988 · Both tunnels were to have been bored using a compressed air boring machine invented and built by Colonel Fredrick Beaumont MP. Beaumont had been ...Missing: Alfred shield
  24. [24]
    Model of a Tunnel boring machine
    Tunnel boring machine, model, scale 1:8, patented by Thomas English No.4347, 1880, and components. Machine used by Col. Beaumont in Channel Tunnel heading.
  25. [25]
    (PDF) Tunneling Under the Hudson and East Rivers in the Early 1900s
    Apr 5, 2016 · In New York City more than a dozen subaqueous tunnels were mined between 1900 and 1920 under both the Hudson and East Rivers.
  26. [26]
    Hard-Rock Tunnel Boring Machines
    Dec 23, 2014 · The first TBM intended to cut hard rock was the Wilson Patent Stone Cutting Machine. It was invented in 1851 and was mobilized to the east portal of the famous ...Missing: Bragg | Show results with:Bragg
  27. [27]
    60 Years of Tunnelling
    Robbins created the modern tunnel boring machine in 1952, revolutionizing tunnelling. They now supply a wide range of tunnelling products, and celebrated 60 ...
  28. [28]
    The Channel Tunnel - The Robbins Company
    In December 1990, the French and British TBMs met in the middle and completed the Channel Service Tunnel bore. In all of the tunnels the French TBM was ...
  29. [29]
    1990- | Kawasaki Heavy Industries, Ltd.
    In July 1987, Kawasaki received an order for two tunnel boring machines (TBMs) with diameters of 8.17 meters for the underwater railroad for the Channel ...
  30. [30]
    Hard grind: The epic journey of the world's biggest tunnel boring ...
    May 1, 2017 · Named after Seattle's first woman mayor, Bertha is what is known as a soft rock TBM, as opposed to a hard rock TBM. The latter, as the name ...Missing: GPS | Show results with:GPS
  31. [31]
    Predictive Maintenance For Tunnel Boring Machines - Groundup.ai
    Bertha, the world's largest TBM in Seattle, was brought to a halt for 2 years after working for only 3 days. The machine failed abruptly, causing the $3.2 ...
  32. [32]
    Exploring Innovations in Tunnel Boring Machine - Data Insights Market
    Rating 4.8 (1,980) Oct 18, 2025 · 2023: Herrenknecht unveils a new generation of hybrid TBMs capable of seamlessly transitioning between soft ground and hard rock excavation, ...
  33. [33]
    Twin-bore tunnels - HS2
    Oct 27, 2025 · A twin-bore tunnel is where two parallel tunnels, each containing a single rail track, are constructed using Tunnel Boring Machines (TBMs).
  34. [34]
    Gotthard Tunnel Expansion: Advanced TBM Technology Navigates ...
    Aug 21, 2024 · On July 30, 2024, the engineering team presented a state-of-the-art Tunnel Boring Machine (TBM) designed specifically for the southern section ...
  35. [35]
    Herrenknecht Wins Business Achievement Award
    Dec 4, 2013 · Company founder Martin Herrenknecht launched Herrenknecht GmbH in 1977 after directing a tunneling job in the Swiss Alps.
  36. [36]
    Tunnelling - Herrenknecht AG
    Modern, integrated tunnel systems for metro, road, railway, passenger, supply and disposal tunnels are the result – built on budget and on schedule.AVN Machine · Road · Railway · MetroMissing: components | Show results with:components
  37. [37]
    Main beam TBMs - About Tunnelling - ITA-AITES
    Definition Single shield TBM. Open-faced shields are shields without a system for pressure regulation at the tunnel face in order to contain groundwater.
  38. [38]
    Main Beam TBM - Tunnel Boring Machines - The Robbins Company
    A Main Beam TBM uses a rotating cutterhead with disc cutters, a floating gripper system, and a main beam for quick access and reduced maintenance.<|separator|>
  39. [39]
    Single Shield TBM - Herrenknecht AG
    Single Shield TBMs are the ideal machine type for tunnelling in consolidated rock and other stable, non-water-bearing ground.
  40. [40]
    Single Shield TBM - Tunnel Boring Machines - The Robbins Company
    Robbins designs Single Shield TBMs to meet the criteria of each specific project, including the geologic conditions, tunnel design, construction plan, project ...
  41. [41]
    Double Shield TBM - Herrenknecht AG
    Double Shield TBMs are among the most technically sophisticated tunnel boring machines. They combine the functional principles of Gripper and Single Shield TBMs ...
  42. [42]
    Double Shield - Tunnel Boring Machines - The Robbins Company
    Robbins designs Double Shield TBMs to meet the criteria of each specific project, including the geologic conditions, tunnel design, construction plan, project ...
  43. [43]
    EPB Shield - Herrenknecht AG
    With so-called Earth Pressure Balance Shields (EPB), the loosened and conditioned soil acts as a plastic support medium to support the tunnel face.
  44. [44]
    What is an Earth Pressure Balance (EPB) Tunnel Boring Machine?
    Apr 26, 2022 · Simply put, earth pressure balance machines (EPBs) are shield TBMs specially designed for operation in soft ground conditions.
  45. [45]
    Earth Pressure Balance - The Robbins Company
    Earth Pressure Balance Machines (EPBMs) are shield machines specially designed for operation in soft ground conditions containing water under pressure.
  46. [46]
    AVN Machine - Herrenknecht AG
    Herrenknecht AVN machines (AVN is short for the German for Automatic Tunnelling Machine Wet) are slurry pressure shields, also known as slurry machines.
  47. [47]
    Slurry TBM | UGITEC
    Slurry TBM prevents tunnel face from collapsing by pressurized mud water in the cutter chamber. Excavated soil material is transported in fluid slurry.
  48. [48]
    Theoretical basis of slurry shield excavation management systems
    Slurry shields are nowadays used in a variety of ground conditions which include hard rock and stiff clays primarily to take advantage of their superior ability ...
  49. [49]
    Precast Segmental Lining for Underground Tunnels - NBM&CW
    Oct 9, 2019 · A Tunnel Boring machine is used for boring beneath the ground sequentially, while simultaneously installing the precast segments and forming a ...<|separator|>
  50. [50]
    [PDF] Precast Concrete Segmental Liners for Large Diameter Road Tunnels
    The present document is the first phase of an FHWA research initiative focused on the design of large diameter precast concrete segmental linings. This document ...
  51. [51]
    Segment handling and installation - Tunnels
    Oct 19, 2011 · The purpose of bolts in a segmental lining is only to provide temporary support until the grout annulus hardens. The bolts are required in the ...
  52. [52]
    [PDF] Guidelines for the Design of Segmental Tunnel Linings - ITA Activities
    Construction loads on the segmental lining include the tunnel boring machine (TBM) jacking thrust loads on the circumferential ring joints and the pressures ...
  53. [53]
    And Non-Bolted Joints On Segmental Tunnel Lining Behavior In ...
    Nov 26, 2017 · The use of TBM for excavation and construction of tunnels such as subways, roads, and railroads, etc. in urban areas and access tunnels in ...
  54. [54]
    [PDF] Recommendations and Guidelines for Tunnel Boring Machines ...
    Each report offers up to date technologies of mechanized tunneling for both hard and soft ground and includes, among others, classifications of TBMs, their ...
  55. [55]
    Rock Bolts in Tunnel: Best Method of Tunnel Support - Sinorock
    Nov 10, 2023 · In this comprehensive article, we'll delve into four key methods of tunnel support: shotcrete support, rock bolts support, metal mesh support, and steel arch ...
  56. [56]
    Products for Fast Excavation with Microtunneling - Sika Group
    Micro TBMs have diameters ranging from a few centimeters up to four meters across. They are typically used for excavation of many vital utility facilities such ...
  57. [57]
    Micro TBM: The Future of Tunnel Construction
    Apr 8, 2025 · A Micro TBM, or Micro Tunnel Boring Machine, is a compact machine used in tunneling projects with diameters typically less than 1.5 meters. They ...
  58. [58]
    Largest Tunnel Boring Machines (TBM) in the World - ASME
    Jun 13, 2023 · The $60 million, German Martina TBM is a closed-shield machine with a diameter of 15.62 m (51 ft. 3 in.), a length of 130 m (430 ft.), and a ...Missing: examples | Show results with:examples
  59. [59]
    World's first in-situ diameter-adjustable tunnel boring machine rolled ...
    Oct 1, 2025 · The Variable Diameter No 1 tunnel boring machine will first be used in an intercity rail project at the Guangzhou Railway Station ...
  60. [60]
    Unprecedented In-Tunnel Diameter Conversion of the Largest Hard ...
    Jul 20, 2022 · The 11.6m diameter TBM was converted to 9.9m in-tunnel, 2.8km into the bore, not in a shaft or pre-excavated portal.<|separator|>
  61. [61]
    [PDF] Chapter 11 - The Robbins Company
    The main beam can be moved up, down, or sideways relative to the tunnel axis throughout the full working stroke. This is how the TBM is steered. The function of ...
  62. [62]
    [PDF] Rock Tunneling Machines: Options and Methods for Variable Geology
    Probe drilling and pre-grouting in TBM tunneling is done with customized rock drills mounted as close to the tunnel face as practically possible to avoid ...
  63. [63]
    Back-Up Systems - The Robbins Company
    From simple, short gantry systems to sophisticated, remote-controlled double-track systems, Robbins matches the back-up system to the construction method and ...Missing: grouting | Show results with:grouting
  64. [64]
    Advanced TBM Tunnel Boring Machine Support Systems
    The tunnel boring industry continues to advance with new technologies that improve efficiency, safety, and environmental performance. Automated systems ...Equipment Selection And... · Operational Challenges And... · Advanced Technologies And...
  65. [65]
    [PDF] Brisbane Airport Link Earth Pressure Balance Machine Two ...
    Mar 10, 2011 · Tunnel boring machine (TBM) details. Page 4. 14TH AUSTRALASIAN ... of the backup gantry will typically load the segments and grout from ...
  66. [66]
    Tunnelling Construction Safety Solutions - MineARC Systems
    Our extensive range of TunnelSAFE Refuge Chambers offer a solution for every application and requirement; from Tunnel Boring Machine (TBM) gantry-mounted ...Missing: trailing escape
  67. [67]
    Tunneling/Boring Equipment Fire Suppression - Stat-X
    The Stat-X total flooding fire suppression system is ideal for all of the enclosed critical electrical and machinery spaces on the TBM.Missing: trailing emergency
  68. [68]
    Vibrations induced by tunnel boring machine in urban areas
    Excavation with tunnel boring machine (TBM) can generate vibrations, causing damages to neighbouring buildings and disturbing the residents or the equipment.
  69. [69]
    [PDF] Volume 1–Groundwater Control Systems for Urban Tunneling
    This three volume report summarizes best available practices in groundwater control both during and after tunnel construction. This volume describes.<|control11|><|separator|>
  70. [70]
    Noise and Vibration - Crossrail Learning Legacy
    Over 90% of the complaints received throughout the construction of Crossrail to date have been attributed to noise and vibration.
  71. [71]
    [PDF] Mechanized Tunnelling in Urban Areas - Rexresearch1.com
    Nov 5, 2001 · Breakthrough of the Herrenknecht TBM at 'Sao Bento Station', under construction. ... small overburden with respect to the excavation diameter.<|control11|><|separator|>
  72. [72]
    Measuring and monitoring noise levels in tunnel boring - Sigicom
    Jan 25, 2024 · Tunnel boring may cause noise and vibration disturbances. Measuring and monitoring noise levels is one of the challenges of tunnel boring.
  73. [73]
    Tunnelling-induced ground surface settlement - ScienceDirect.com
    Tunnel boring machine (TBM) and liner are regarded as common construction approach of tunnels in urban area. There are many parameters of TBM, such as thrust, ...
  74. [74]
    https://www.rexresearch1.com/TunnellingLibrary/MechanizedTunnellingUrbanAreas.pdf
  75. [75]
    [PDF] Current Underground Construction Technology in Tokyo
    This paper summarizes two topics of the recent case histories of shield TBM tunneling and underground construction technology in the Tokyo metropolitan area, ...
  76. [76]
    Second Avenue Subway - Herrenknecht AG
    The long-awaited "Second Avenue Subway" was built on the eastern coast of Manhattan. The S-434 Gripper TBM bored its way underground for the tunnel from 96th ...Missing: post- | Show results with:post-
  77. [77]
    Why we stopped building cut and cover - Works in Progress Magazine
    Feb 16, 2024 · But for urban subway tunnels, cut and cover has largely been supplanted by the use of tunnel-boring machines (TBMs), which tunnel horizontally ...Missing: expansion | Show results with:expansion
  78. [78]
    Advances in Tunneling Overcome Challenges in Urban Areas
    Jun 10, 2019 · Tunneling in urban areas frequently requires construction with shallow cover, in difficult ground conditions of soft soils and mixed ground, with high ...
  79. [79]
    How Was The Channel Tunnel Built? - Institution of Civil Engineers
    Digging started in 1988, with tunnel boring machines (TBMs) used for all the tunnels. Five TBMs dug from France, six TBMs dug from the UK. The TBMs started work ...Missing: details | Show results with:details
  80. [80]
    Fun Facts About the Channel Tunnel - ThoughtCo
    May 6, 2025 · Each TBM, or tunnel boring machine, used during construction of the Channel Tunnel was 750 feet long and weighed over 15,000 tons. They could ...
  81. [81]
    Gotthard Base Tunnel, Switzerland - Railway Technology
    Sep 17, 2021 · It took nearly 14 years and 2,500 workers to connect the two ends of the tunnel. This final breakthrough in the west tube was completed in March ...
  82. [82]
    Gotthard Base Tunnel - Herrenknecht AG
    The Gotthard Base Tunnel connects Erstfeld and Bodio at a length of 57 kilometers. On June 1, 2016, the longest railway tunnel in the world opened its doors.
  83. [83]
    [PDF] Gotthard Base Tunnel, Switzerland - Sika Group
    The Gotthard Base Tunnel is the world's longest rail tunnel, with two 57km tubes, 152km total, 20 min transit time, and 28.2 million tonnes of rock removed.
  84. [84]
    [PDF] Snowy 2.0 Updated Business Case
    May 24, 2024 · In August 2023, Snowy Hydro announced a revision to the costs and schedule for the Snowy 2.0 Project1. This document provides an update.
  85. [85]
    Snowy Hydro 2.0 flags another cost blowout with $12bn price tag ...
    Oct 3, 2025 · The project aims to link two existing Snowy reservoirs by tunnels up to 27km in length. Once completed, it will be able to generate 2,200 ...
  86. [86]
    The fourth TBM for the Snowy Hydro 2.0 project (Ø 11.86 ... - Facebook
    Aug 6, 2025 · The fourth TBM for the Snowy Hydro 2.0 project (Ø 11.86 m) has successfully passed its Factory Acceptance Test (FAT) at the Herrenknecht ...
  87. [87]
    DEP Announces Major Milestone For Delaware Aqueduct Repair As ...
    Aug 16, 2019 · Its centerpiece is a 2.5-mile-long bypass tunnel that DEP is building 600 feet under the Hudson River from Newburgh to Wappinger.Missing: cost | Show results with:cost
  88. [88]
    Delaware Aqueduct Repair - The Robbins Company
    Single Shield TBM will bore through Difficult Conditions to fix the World's Longest Continuous Tunnel. Project Overview. At 137 km (85 mi) long, ...Missing: cost time
  89. [89]
    Tunnel repair for aging New York aqueduct - TunnelTalk.com
    A 3 mile bypass tunnel is part of a $2.1 billion upgrade of the Delaware Aqueduct, a vital component of New York City's drinking water supply system. The ...
  90. [90]
    HS2 6-monthly report to Parliament: July 2025 - GOV.UK
    Jul 17, 2025 · Over 70% of HS2 's 32 miles of bored and mined tunnels between London and Birmingham have now been completed. Construction is progressing across ...
  91. [91]
    HS2: costs and controversies | Institute for Government
    Oct 5, 2023 · The Gordon Brown Labour government initially estimated that HS2 would cost £37.5bn (in 2009 prices) but the expected cost has since increased dramatically.Missing: TBM details length
  92. [92]
    Prufrock - The Boring Company
    Prufrock is targeting a speed greater than 1 mile per week, which is 6 times faster than The Boring Company's previous-generation TBM (Godot).
  93. [93]
    Musk's new tunnel boring machine works without humans - Inspenet
    Sep 16, 2025 · The Prufrock-4 introduces continuous excavation and remote operation to reduce costs and accelerate tunneling projects throughout the Loop ...
  94. [94]
    What's New in Tunnel Boring Machine Technology?
    Jan 25, 2024 · IoT Connectivity · Automated TBMs · Plasma and Gas Tunneling · Adaptive Tunneling · Continuous Excavation · Sustainable TBM Design · Microtunneling.
  95. [95]
    Powering Tunnel Boring Machines with a Hybrid Power Solution
    Utilities infrastructure company Rob Carr adopted two Battery Energy Storage Systems for a tunnel boring operation for Sydney Water.
  96. [96]
    Greener TBM slurry processing - Victoria's Big Build
    Aug 9, 2024 · By recycling water into the slurry system, the project saved more than 140 Olympic-sized swimming pools of water. Was this page helpful?
  97. [97]
    [PDF] Reducing emissions from non-road mobile machinery
    Non-road mobile machinery (NRMM) relies on fossil fuels, contributing 3.1% of EU emissions. Transition to zero-emission technologies is crucial for reducing ...Missing: tunnel | Show results with:tunnel
  98. [98]
    Multi-mode TBM - Herrenknecht AG
    The basic concept allows switching between slurry support, earth pressure balance support and open mode by means of various conversions within a tunnel section.
  99. [99]
    Robotic replacement for disc cutters in tunnel boring machines
    Aug 7, 2025 · Moreover, Du et al. (2022) designed and tested a teleoperated robot specifically for replacing disc cutters on Tunnel Boring Machines (TBMs).Missing: 2020s | Show results with:2020s
  100. [100]
    Unveiling the World's First Green TBMs: A Leap Forward in ...
    Jan 14, 2025 · CREG's green TBMs are designed to minimize their environmental footprint. While specific eco-friendly features of the machines have not been ...
  101. [101]
    Emerging data-processing technologies for TBM projects — state of ...
    ... tunneling. Rapid technological advances in machine manufacturing allow tunnel boring machines (TBM) to be used in ever more challenging ground conditions.<|separator|>