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Semmering Base Tunnel

The Semmering Base Tunnel is a 27.3 km long twin-tube railway tunnel under construction in , linking Gloggnitz in to Mürzzuschlag in and bypassing the historic, steeply graded Semmering Pass section of the Southern Railway line. The project, initiated to modernize rail infrastructure dating back to the 1850s, consists of two parallel single-track tubes with a maximum of 950 m and cross-passages every 500 m for . Upon completion, it will enable passenger and freight trains to operate at speeds of up to 230 km/h on a largely flat trajectory, reducing the journey time from to to under two hours and enhancing connectivity along the EU's Baltic–Adriatic Corridor. Construction of the tunnel, one of Europe's most technically demanding rail projects due to its challenging geological conditions including fault zones and water ingress, began with groundbreaking in April 2012 and main tunneling drives in 2014 across five sites. Excavation works, involving 14 simultaneous drives using conventional and mechanized methods, reached 98% completion by late 2023 and were fully finalized on , 2024, marking a major after over a decade of effort. The €3.9 billion initiative, funded in part by the , is expected to create around 11,000 jobs during operation and generate economic returns of €5 for every €1 invested, while preserving the UNESCO-listed original for heritage tourism. Full commissioning is anticipated in 2030, following fit-out, track installation, and signaling works.

Project Overview

Route and Specifications

The Semmering Base Tunnel is a 27.3 km long twin-bore railway tunnel that connects Gloggnitz in to Mürzzuschlag in , bypassing the historic line over the pass. The two parallel single-track bores run with a maximum overburden of up to 900 m beneath the Semmering Pass, forming a key segment of Austria's high-performance southern rail corridor. Each bore has an excavated diameter of 10 m, providing a cross-sectional area of approximately 80 m² to accommodate modern rail infrastructure. For safety, the bores are separated by 40 to 70 m and linked by cross-passages at intervals of no more than 500 m, enabling evacuation and ventilation in emergencies. The alignment incorporates an underground emergency station roughly midway through the tunnel, featuring caverns for rescue operations, along with four track crossovers to facilitate overtaking and operational flexibility. The tunnel integrates with approximately 11 km of surface approach tracks, including cut-and-cover sections and viaducts at each portal to ensure seamless connectivity. Geologically, the tunnel traverses a challenging profile dominated by gneiss and mica schist formations, intersected by major fault zones that pose risks of water ingress and ground instability. Overburden reaches maxima of up to 900 m in these zones, requiring specialized stabilization measures. The design supports a maximum speed of 230 km/h, enabling efficient high-speed passenger and freight services while maintaining gradients below 10‰ for optimal performance.

Purpose and Benefits

The Semmering Base Tunnel addresses longstanding capacity constraints on the UNESCO-listed , which currently handles around 180 trains per day but faces limitations due to its steep reaching up to 25‰ along 60% of its length, restricting train weights and speeds. By providing a parallel, modern route with a maximum of 8.5‰, the tunnel will relieve pressure on the historic line, allowing it to preserve its cultural significance while accommodating heritage and regional services. As a key component of the European Union's (TEN-T), the tunnel integrates into the Baltic-Adriatic Corridor, enhancing north-south connectivity across and facilitating faster links between major ports and inland hubs. This will reduce travel times on the Vienna to route by approximately 30 minutes, shortening the overall journey to under two hours and enabling average speeds of up to 230 km/h for passenger services. The upgraded infrastructure will support up to 240 trains per day, doubling capacity from the current line and prioritizing high-speed operations. Economically, the project will boost along the southern route by approximately 50%, allowing heavier loads of up to 1,600 tonnes to be hauled by a single without assistance, thereby improving efficiency and competitiveness for over . This enhancement supports in and by creating jobs during construction and stimulating long-term economic growth through better logistics and tourism access. Environmentally, the tunnel's straighter alignment and reduced inclines will lower for trains compared to the existing route's numerous curves and elevations, contributing to decreased CO₂ emissions overall. By shifting more freight to , which emits around 30 times less CO₂ per than trucks, the project aligns with Austria's goals for and climate neutrality.

Historical Background

Original Semmering Railway

The , constructed between 1848 and 1854 under the direction of Carl Ritter von Ghega, stands as Europe's first , overcoming the challenging terrain between Gloggnitz and Mürzzuschlag in . Ghega, born in in 1802, led a workforce of approximately 20,000 laborers to build this pioneering line, which connected the Viennese basin to and marked a significant advancement in during the mid-19th century. The project was commissioned by the Austrian state to link with , facilitating trade and imperial connectivity across the Habsburg Empire. Construction claimed the lives of around 1,000 workers due to accidents, , and outbreaks. Spanning 41 kilometers and ascending 460 meters in elevation, the railway features 14 tunnels totaling 1,477 meters, 16 major viaducts of equal cumulative length, and over 100 smaller arched stone bridges to navigate the rugged Semmering Pass. Approximately 60% of the route maintains gradients of 20 to 25‰, with numerous curves that restricted operational speeds to between 50 and 70 km/h, even for the specifically designed for this demanding alpine environment. This was the first extensive use of steam-powered trains in such mountainous terrain, requiring innovative locomotive designs to handle the inclines without excessive reliance on cable systems. In 1998, the was inscribed on the World Heritage List under criteria (ii) and (iv), recognizing it as an outstanding example of early innovations that solved major physical challenges in railway construction and influenced subsequent global designs for mountain rail lines. The line's integration of precise surveying, retaining walls, and balanced gradients set precedents for alpine rail development worldwide, demonstrating how railways could transform inaccessible landscapes into viable transport corridors. Despite its engineering triumphs, the Semmering Railway has faced ongoing operational challenges, including vulnerability to harsh Alpine weather such as heavy snow and rockfalls, which disrupt service and demand intensive clearing efforts. The steep gradients and tight curves accelerate track and structure wear, leading to high maintenance costs and frequent interventions to ensure . Additionally, the route's capacity remains limited for contemporary high-speed and heavy freight demands, creating bottlenecks that hinder efficient cross-Alpine traffic flows. These limitations underscore the need for a base tunnel to supplement the historic line while preserving its cultural significance.

Project Initiation and Planning

The Semmering Base Tunnel project was initiated in 2004 as part of the European Union's (TEN-T) priority projects, specifically under Decision 884/2004/EC, which designated it within Priority Project 17 (the Baltic-Adriatic Corridor) to enhance cross-Alpine rail connectivity. This inclusion addressed longstanding capacity limitations of the 19th-century by planning a modern base tunnel to support up to 230 km/h. Feasibility studies conducted from 2005 to 2008 confirmed the project's technical and economic viability, evaluating geological conditions, route options, and integration with the broader southern rail network. Key planning phases included route selection between 2005 and 2007, culminating in the approval of the Pfaffensattel variant in April 2008, which optimized the 27.3 km alignment for minimal environmental disruption while integrating with the Koralm Tunnel to form the Vienna-to-Italy high-speed corridor. The environmental impact assessment process advanced through investigations in 2008-2009, supporting regulatory approvals under Austrian railway and nature protection laws. Political drivers stemmed from the Austrian government's emphasis on infrastructure modernization, with commitments in 2008 to upgrade southern rail lines for economic growth and reduced road freight dependency. Initial cost estimates ranged from €2.9 billion to €3.9 billion, reflecting preliminary designs and contingency for geological challenges, with ÖBB-Infrastruktur AG designated as the lead agency responsible for planning and execution. funding was secured starting in 2009 under TEN-T mechanisms, providing up to 50% co-financing of the initial €3.2 billion budget to align with pan-European transport goals.

Design and Engineering

Technical Design Features

The Semmering Base Tunnel employs a twin-bore design consisting of two parallel single-track tubes, each approximately 27.3 km long, separated by 40 to 70 m to enhance and operational during . This configuration includes 56 cross-passages connecting the tubes, with additional connections spaced every 500 m to facilitate and evacuation, alongside one central strategically located along the route, including a central underground station spanning 0.6 miles equipped with caverns and access points. The track system is engineered for high-speed stability, featuring slab track laid on a base to support passenger trains up to 230 km/h and freight trains with minimal gradients below 10‰, integrated with the (ETCS) Level 2 for automated signaling and collision avoidance. Safety systems incorporate longitudinal ventilation using jet fans to manage airflow and smoke extraction, complemented by advanced through linear heat sensors and that identify incidents within 30-60 seconds, while evacuation is supported by shafts every 500 m and cross-passages serving as escape routes with overpressurized fire doors. Geotechnical solutions address the route's challenging , particularly fault zones like Grassberg-Schlagl, through systematic grouting to seal ingress rates up to 300 l/s and stabilize the surrounding rock mass. Continuous monitoring is achieved via distributed fiber-optic sensing embedded in tunnel linings, shafts, and earth structures to detect strains, deformations, and environmental changes in real-time, ensuring structural integrity throughout the tunnel's lifespan. Integration features include robust portal structures at Gloggnitz in the north and Mürzzuschlag in the south, designed to seamlessly connect the tunnel to the existing rail network, with cut-and-cover sections extending the approaches—such as a 0.4-mile segment at the southern portal—to accommodate track transitions and surface infrastructure.

Environmental and Safety Considerations

The Semmering Base Tunnel project underwent a comprehensive (EIA) in accordance with EU Directive 2011/92/EU and the 92/43/EEC, completed in 2010 with permits granted in 2014. This EIA mandated specific measures to mitigate environmental effects in the protected Semmering area, including through barriers and planted earth walls along associated tracks, groundwater protection via sealing and drainage systems to address high-pressure inflows up to 100 liters per second, and minimal surface disruption limited to localized impacts at tunnel portals and shafts. These requirements ensured compliance during the planning approvals process, emphasizing integration with the surrounding protected zones. To address biodiversity impacts, the tunnel route was rerouted to avoid sensitive aquifers and fault zones, preventing significant effects on local flora and fauna in the adjacent area (AT1212A00), as confirmed by assessments showing no adverse influence. Compensatory habitats were established through efforts, including the creation of ponds, swales, forestation, reed beds, and passages to offset any habitat loss and support species such as amphibians and birds in the project's vicinity. Additional mitigations, like sodium vapor lamps to minimize , further protected nocturnal . Safety protocols for the tunnel adhere to EU Technical Specifications for Interoperability (TSI) under Directive 2004/54/EC and the Safety in Railway Tunnels TSI (SRT TSI), incorporating blast-proof doors in cross passages designed to withstand pressure waves up to 180 and thermal loads up to °C, as well as self-rescue equipment including emergency exits every 500 meters with positive pressure to maintain smoke-free escape routes. These features, supported by acoustic incident detection systems responsive within 0.7 seconds and deluge suppression, enable self-evacuation times of 30-54 seconds at velocities up to 2.6 m/s. Sustainability goals emphasize reduced environmental footprint through the use of low-carbon concrete in linings and energy-efficient lighting and ventilation systems, such as longitudinal jet fans and axial ventilators optimized for minimal during operation. These measures, combined with the project's promotion of modal shift, are projected to cut annual CO₂ equivalent emissions by 146,000 tonnes, representing a substantial reduction in operational impacts compared to alternatives. Ongoing monitoring integrates real-time seismic sensors via distributed fiber-optic systems to track structural deformations and fault zone stability, alongside hydrogeological sensors for , including level measurements in wells, spring discharges, and brook runoff to safeguard integrity during and post-construction. These instruments, deployed from the design phase, provide continuous data for in the seismically active and karstic terrain.

Construction Process

Timeline and Key Milestones

The planning for the Semmering Base Tunnel was initiated in the mid-2000s, with ÖBB-Infrastruktur AG commissioned in March 2005 to oversee detailed development as part of the broader Southern Line upgrades. Construction officially began with the on April 25, 2012, marking the start of site preparation and portal works at multiple locations including Gloggnitz and Fröschnitzgraben. Portal construction and initial access tunnels progressed from 2012 to 2015, laying the groundwork for deeper excavation across the project's three main lots. Tunneling activities ramped up with the launch of the first (TBM) drives in January 2014 at the Fröschnitzgraben section (Lot 2.1), followed by additional starts in July 2015 at Gloggnitz (Lot 1.1) and May 2016 at Grautschenhof (Lot 3.1). A significant came on June 10, 2022, with the first breakthrough connecting the Göstritz and Fröschnitzgraben sites, linking two parallel bores over 4 km in length. Main tunneling continued through challenging geological conditions until the final on September 12, 2024, completing the first tube of Lot 1.1, and culminating in full excavation on November 29, 2024, after 14 separate drives totaling 55 km of bored tunnels in twin tubes. Following excavation, inner shell work began in early 2025, with fit-out and commencing in summer 2025. A €76 million slab track was awarded in April 2025 to a of Rhomberg Sersa Rail and , with planning and production starting in June 2025. Full commissioning is expected in 2030, potentially extending to 2031. The project has faced multiple delays, shifting the original 2026 completion target to 2030 primarily due to complex fault zones encountered during excavation, which required additional stabilization measures, compounded by disruptions from the including supply chain issues and workforce limitations. An earlier postponement from 2024 to 2027 in 2020 was linked to unexpected inflows, further extending timelines. Budget estimates have also evolved, rising from an initial €3.3 billion in 2012 to €3.9 billion by 2022, driven by geological complexities, in materials and costs, and mitigation efforts for risks identified during .

Tunneling Techniques and Challenges

The of the Semmering Base Tunnel employed a of mechanized and conventional excavation methods to address the project's complex geology. For the main bores in the central Fröschnitzgraben section, two single-shield tunnel boring machines (TBMs) with a of 10.17 meters were utilized to excavate approximately 5 miles of twin tunnels. These TBMs were equipped with a 6+0 segmental lining system, consisting of segments at least 12 inches thick, installed immediately behind the cutterhead to provide . In contrast, drill-and-blast techniques, implemented via the sequential excavation method (), were applied for cross-passages and approximately 12 miles of the northern and southern sections, involving reinforced , rockbolts, and forepoling pipes to stabilize the face in variable ground conditions. The tunnel's path through the Northern Calcareous Alps presented significant geological challenges, including intense tectonic imbrication with phyllites, schists, quartzites, carbonates, and mica schist formations, particularly in major fault zones such as the Semmering and Grasberg-Schlagl faults. High water ingress was a primary obstacle, reaching up to 300 liters per second in carbonate rock sections and posing risks of erosion in mica schist zones under pressures up to 25 bar in dolomite areas. These inflows, combined with the Semmering fault's tectonic instability, increased the potential for ground deformation and instability during excavation, with fault zones exhibiting swelling clays, cataclasite, and carbonatic breccia that could lead to flowing ground conditions. Overbreak in weak rock areas was controlled through deformation gaps filled with lattice shell concrete (LSC) elements, accommodating up to 20 inches of radial deformation, supplemented by additional 8-inch shotcrete layers where necessary. Water management relied heavily on systematic pre-excavation grouting to reduce permeability to a target of 5 Lugeon units, using a combination of top-hammer drilling in massive rock and grouting-pipe systems in weak, erosive zones like mica schist faults. Grouting involved hybrid cement-polyurethane mixes to minimize wash-out and enhance sealing under , applied via 76- to 102-mm boreholes up to 30 meters long, with flow rates of 1-5 liters per minute and pressures monitored to ensure q/p values below 0.2 liters per minute per bar. The inner lining, cast in-situ reinforced in fault and residential zones, incorporated membranes, geotextiles, and pipes to handle residual inflows and maintain long-term stability. Excavated material, totaling approximately 4.25 million cubic meters, was managed through conveyor belts and trucks to the Longsgraben , where it underwent recultivation and partial for backfill and aggregates, with about 28% repurposed for production in the project. Innovations in the TBM operations included adaptations for variable , such as tested grouting parameters (e.g., cement-polymer ratios and injection rates) to optimize sealing ahead of the machine, enabling safe advances through heterogeneous faulted ground without major interruptions. The bore diameter of 10.17 meters supported the tunnel's design for , ensuring adequate clearance for tracks and safety systems.

Current Status and Future Impact

Recent Progress and Updates

The excavation of the Semmering Base Tunnel was fully completed on November 29, 2024, marking the final breakthrough after initial ones in late 2024. This milestone marked the end of a decade-long tunneling phase, allowing the project to transition into subsequent construction stages without reported major delays. As of mid-2025, the primary focus has shifted to the inner shell concreting, scheduled to continue through 2025 and into 2026, providing structural reinforcement along the 27.3 km twin-bore . As of November 2025, inner shell concreting and initial technical installations are progressing as scheduled, with no major delays reported. Concurrently, technical installations, including cabling, ventilation systems, and other equipment, commenced in summer 2025 to prepare the for operational use. In March 2025, ÖBB-Infrastruktur awarded a €76 million to the Rhomberg Sersa Rail Group and Porr Group consortium for the installation of slab track, with planning and production activities starting in June 2025 and full construction set to begin in April 2027 following inner shell completion. Ongoing geotechnical surveys and monitoring have confirmed the tunnel's stability post-breakthrough, with recent hydraulic field testing and instrumentation addressing inflows and fault zone challenges. The project timeline remains on track for a 2030 opening, as reaffirmed in Austria's 2025 rail investment announcements, ensuring continued progress toward enhanced connectivity between and .

Expected Completion and Operational Details

Following the completion of excavation in November 2024, the remaining works for the Semmering Base Tunnel focus on the fit-out phase, including the installation of the inner concrete lining starting in summer 2025. Slab track laying, covering approximately 55 km including the tunnel and approach sections, is scheduled to commence with production of track support slabs in 2026, progressing through 2028 as part of the overall rail infrastructure build-out. Electrification and signaling systems, including the European Train Control System (ETCS), will be integrated during the subsequent phases from 2028 onward, with comprehensive testing leading to full commissioning in 2030. Upon opening, the tunnel will support mixed passenger and freight operations as a key segment of the TEN-T Baltic-Adriatic Corridor, enabling heavy freight trains with a maximum speed of 230 km/h for passengers and automated control via ETCS Level 2 to optimize train spacing and safety. The design facilitates up to 200 trains per day, enhancing reliability for both high-speed passenger services and efficient freight transit across the . At the portals, the tunnel integrates seamlessly with existing rail lines in Gloggnitz and Mürzzuschlag, diverting mainline traffic to bypass the steep historic while preserving the latter—a —for continued tourist excursions and heritage operations. Post-opening maintenance will incorporate long-term structural monitoring systems to assess tunnel lining integrity, drawing from established practices in Austrian rail projects like the adjacent Koralm Tunnel, with regular safety protocols including ventilation checks and emergency response simulations. The tunnel's operation is projected to boost corridor capacity by relieving bottlenecks on the existing route, enabling a 30-minute reduction in Vienna-to-Graz travel time and fostering through improved connectivity and job creation in the region, with benefits accruing over the long term as part of Austria's €19.7 billion investment framework for 2025–2030.

References

  1. [1]
    Semmering base tunnel - About the project - ÖBB Infra
    Around 27 kilometres in length and 18 years in making under challenging geological conditions: The Semmering Base Tunnel ranks amongst the most complex tunnel ...
  2. [2]
    Koralm Tunnel and New Semmering Base Tunnel: State of ...
    The Koralm Tunnel is 32.9 km long, passing between Styria and Kärnten. The New Semmering Base Tunnel is 27.3 km long, linking Lower Austria with Styria.
  3. [3]
    Semmering Base Tunnel slab track contract awarded
    Mar 25, 2025 · ÖBB-Infrastruktur has awarded a consortium of Rhomberg Sersa Rail Group and Porr Group a €76m contract to install slab track in the 27·3 km twin-bore Semmering ...
  4. [4]
    Semmering base tunnel - ÖBB-Infrastruktur AG
    The Semmering Base Tunnel connects Lower Austria and Styria, enabling travel from Vienna to Graz in under two hours, and is a sustainable investment.
  5. [5]
    The Semmering Base Tunnel: overcoming the Alps - Rail Engineer
    Oct 17, 2024 · The report added that work on the second tube is expected to be completed in the first quarter of 2025, when tunnelling will be completely ...
  6. [6]
    Semmering Base Tunnel excavation completed - Railway PRO
    Dec 4, 2024 · Excavation for Semmering Base Tunnel has been completely finalised on November 29, 2024, ten years after construction began in the Frö ...
  7. [7]
    OEBB SUEDSTRECKE SEMMERING BASISTUNNEL
    The works, located on different sections along the line, include the construction of the 27-km-long Semmering base tunnel, around 20 km of track doubling, ...
  8. [8]
    Semmering Base Tunnel - Railway Technology
    Aug 25, 2014 · The tunnel will enable trains to travel at a speed of 250km/h and is ... data to enhance site navigation, personalize ads and content ...Missing: specifications | Show results with:specifications
  9. [9]
    Semmering Basistunnel SBT Los 2.1 - Implenia
    8.6 km). These two shafts have been constructed by blasting down to a depth of up to 400 metres and have diameters of 11 m and 8.5 m respectively.Missing: design speed
  10. [10]
    New Semmering Base Tunnel: Gloggnitz Preliminary Work finished
    The 27.3 km long New Semmering Base Tunnel (SBTn) is a major element of the new Austrian southern rail route. Its two bores are to be linked every 500 m by ...<|control11|><|separator|>
  11. [11]
    [PDF] SEMMERING BASE TUNNEL - Amberg Engineering
    The Semmering base tunnel is a high-performance rail link with 2 single track tubes, each 27.3km long, designed for a flat trajectory.<|control11|><|separator|>
  12. [12]
    Semmering Base Tunnel: TBM Start in Contract Section 2.1
    The 27.3 km long New Semmering Base Tunnel (SBTn) is a major element of the new Austrian southern rail route. Its two bores are to be linked every 500 m by ...Missing: approach tracks
  13. [13]
    [PDF] Semmering Base Tunnel: 17 Miles of SEM and TBM Tunneling ...
    This consists of two 17 miles of single-track railway tunnels, numerous cross passages and a complex underground emergency station including caverns, passages, ...Missing: speed | Show results with:speed
  14. [14]
    [PDF] Semmering Base Tunnel – Ground characterisation for tendering ...
    Semmering Base Tunnel – simplified geological longitudinal section ... gneiss) (neglecting fault zone GTs). This reduces the large number of 51 GTs ...
  15. [15]
    Squeezing Condition - an overview | ScienceDirect Topics
    The maximum overburden measures approx. 1000 m and the geology mainly consists of mica schist, feldspatic gneiss and phyllite. rb; ssrb + shd; ovx. Karawanken ...
  16. [16]
    [PDF] Semmering Base Tunnel – Large Caverns in Challenging Conditions
    The maximum overburden above the caverns is app. 500 m in difficult geological conditions with large fault zones and extensive water inflow, which require ...Missing: mica | Show results with:mica
  17. [17]
    [PDF] Semmering Base Tunnel - ÖBB Infra
    History is being written in the Semmering region. Construction of the 27.3 km tunnel in the heart of Austria means a modern rail link for future generations.
  18. [18]
    Consortium PORR and Rhomberg Sersa Rail Group: Slab Track in ...
    Mar 20, 2025 · The Semmering Base Tunnel is scheduled to be commissioned in 2030. For this project, RSRG will take over commercial management, while PORR will ...
  19. [19]
    Existing Semmering Line - ÖBB-Infrastruktur AG
    With around 180 trains per day, it is one of the busiest routes in Austria. ... From 2030, a new, modern high-speed section will head south through the Semmering ...
  20. [20]
    Semmering Railway - UNESCO World Heritage Centre
    The Semmering Railway, constructed between 1848 and 1854 over 41 km of high mountains, is one of the greatest feats of civil engineering during the pioneering ...Gallery · Maps · Documents · Videos
  21. [21]
    Baltic Sea - Adriatic Sea corridor - Mobility and Transport
    The Baltic Sea-Adriatic Sea Corridor extends in the North from the Polish Baltic Sea ports of Gdańsk and Gdynia as well as Szczecin and Świnoujście and the ...
  22. [22]
    Semmering rail tunnel, the jewel of Austria - Railway PRO
    May 18, 2017 · Once completed, the double, 27.3-km tunnel will be one of the longest railway tunnels in the world. Construction works were launched in 2014 and ...
  23. [23]
    Full speed ahead for freight transport on the new Koralm Railway
    Nov 4, 2025 · Climate-friendly mobility: 30% more freight capacity on the southern route New line: Shorter transport routes, lower energy consumption ...
  24. [24]
    Semmeringbahn - OKthePK
    Along its track length of 41 kilometres the Semmering railway overcomes an altitude difference of 460 metres while along 60 percent of its length the gradient ...
  25. [25]
    [PDF] TEM and TER revised Master Plan - Final Report - UNECE
    ... rail capacity bottlenecks, and considered a road as congested when the travel speed of heavy goods vehicles (HGVs) decreased below 50 km/h. The road capacity.
  26. [26]
    [PDF] Investigation strategies on the example of the Semmering Base Tunnel
    Apr 1, 2015 · Feasibility, route selection. Approval procedure, design phase. Construction. Preparatory works. Remote sensing data. Desk study. Surface ...
  27. [27]
    Semmering Base Tunnel – Ground characterisation for tendering ...
    Aug 6, 2025 · As result of the two-year route selection process, the southernmost variant Pfaffensattel was chosen in April 2008 as the best variant for the ...
  28. [28]
    New Semmering Base Tunnel – the investigation programme 2008 ...
    Apr 12, 2010 · New Semmering Base Tunnel – the investigation programme 2008 ... environmental impact assessment and also the documents required for the ...
  29. [29]
    The Semmering Base Tunnel: powerful and future-oriented
    Aug 6, 2015 · Tunnel between Gloggnitz (Lower Austria) to Mürzzuschlag (Styria) · 3km-long · 30 minutes time saving · 2026 completion date · Two parallel tunnel ...
  30. [30]
    [PDF] Semmering Base Tunnel - iC consulenten
    The alignment of the tunnel is based on a maximum train velocity of 140 mph with a maximum inclination of. 8.4 ‰. Due to the envisaged completion date and ...
  31. [31]
    [PDF] Tunnel Safety And Ventilation, Graz
    Jun 14, 2018 · The Semmering Base tunnel with a length of 27 km, and the Koralmtunnel with a length of 33 km, are core parts of the Baltic - Adriatic corridor.
  32. [32]
    ETCS Train Control System - ÖBB-Infrastruktur AG
    ÖBB-Infrastructure is building the ETCS network in three implementation phases, expanding 3,700 kilometres with ETCS Level 2: The next step for the ETCS ...
  33. [33]
    Distributed fibre-optic sensing applications at the Semmering Base ...
    At the Semmering Base Tunnel, fibre-optic sensing is used at every construction location to monitor tunnel linings, shafts, reinforced earth structures and ...Missing: ventilation safety slab track
  34. [34]
    [PDF] Environmental and Social Data Sheet
    Jul 21, 2015 · Forecast emissions savings are 146,000 tonnes of CO2 equivalent. Bruck an der Mur, totalling 143 km along the existing infrastructure and 129 ...Missing: benefits | Show results with:benefits
  35. [35]
    Tunnelling in challenging geotechnical and geological conditions in ...
    Aug 6, 2025 · Drilling and Grouting Works for Pressurised Groundwater Conditions of the Semmering Base Tunnel ... sealing grouting. Weak fault rocks ...Missing: protection | Show results with:protection
  36. [36]
    Railway and nature - ÖBB-Infrastruktur AG
    The areas we own alongside the railway are important habitats and retreat areas for many animals and plants. We manage 3,400 hectares of protective forest, look ...
  37. [37]
    Semmering Base Tunnel: project overview and IGMS monitoring ...
    At a value of approximately 1.85×10 5 µε/m, the maximum strain gradient ε′ max and the corresponding maximum bond stress τ max are reached, indicating slippage ...
  38. [38]
    Semmering Base Tunnel, Hydrogeological Preservation of Evidence
    The Semmering Base Tunnel with a length of 27 km is the centrepiece of the new Southern Railway Line between Vienna and Graz, which is expected to start ...
  39. [39]
    Advantages of tunnel monitoring using distributed fibre optic sensing
    Predictive maintenance and safety assessment during the construction and operational phase are becoming more and more important in modern tunnelling.Missing: seismic | Show results with:seismic
  40. [40]
    First breakthrough achieved in Semmering Base Tunnel
    Jun 13, 2022 · The estimated total cost of the project has also increased by €390m to €3.9bn. Work on the Gloggnitz section has resumed after the ...Missing: 2.9-3.9 billion
  41. [41]
    Semmering Base Tunnel delayed by complex geology
    May 5, 2022 · Work on the 27.3km long railway tunnel has been delayed by several months due to a geological fault zone in the Grasberg area.Missing: gneiss mica schist
  42. [42]
    Opening of Semmering Base Tunnel delayed
    Jan 6, 2020 · Opening is now expected in 2027. Unexpected water began to enter the tunnels during drilling, causing flooding, with the issue taking longer ...Missing: COVID overrun 2026 2030<|control11|><|separator|>
  43. [43]
    Drilling and Grouting Works for Pressurised Groundwater Conditions ...
    Jun 8, 2022 · The Semmering Base Tunnel uses a Standpipe-Packer, cased drilling with grouting inserts, a Grouting-Pipe system, and a combined cement- ...
  44. [44]
    The New Semmering Base Tunnel – project overview / Der ...
    Oct 20, 2025 · The Semmering Base Tunnel with a total length of 27.3 km will realize a high-speed rail connection according to the latest requirements for ...Missing: specifications | Show results with:specifications
  45. [45]
    [PDF] Applicability of excavated rock material: A European technical ...
    Environmental impact assessment concluded on the construction of an island in a protected natural area close to district Essex using about 4 million tons of ...
  46. [46]
    Project News Flash 02/2025 - Amberg Group
    May 23, 2025 · After an incredible 3,374 days, the excavation work on construction lot SBT1.1 was successfully completed on December 11, 2024. With this, we ...Missing: groundbreaking | Show results with:groundbreaking
  47. [47]
    Excavations for Semmering Base Tunnel are officially completed
    Dec 2, 2024 · “The concrete inner shell will now be completed in the next few months and then the technical tunnel equipment can start”, Austrian railway ...
  48. [48]
    Semmering Base Tunnel: Prediction of Groundwater Inflows and ...
    Jul 18, 2025 · Duration of the RW phase approximately 3 hours. 3) Rapid and complete closure of the valve at the discharge borehole to initiate the rate.
  49. [49]
    (Ava-33903) Semmering Base Tunnel New / Sbt 3.1 Geotechnical ...
    Rating 4.8 (12,683) · Free · Business/ProductivityThe tender was released on Aug 27, 2025. Country - Austria. Summary - (Ava-33903) Semmering Base Tunnel New / Sbt 3.1 Geotechnical Measurements. Deadline - ...
  50. [50]
    2025–2030 rail investment plan announced in Austria - Railway PRO
    May 14, 2025 · ÖBB will continue key ongoing projects such as the Koralmbahn, the Semmering Base Tunnel, and the Brenner Base Tunnel, along with essential ...
  51. [51]
    Kirchdorfer Group delivers track slabs for Semmering Base Tunnel
    Sep 29, 2025 · From 2026, MABA Concrete Solutions of Kirchdorfer Group will produce a total of 10,637 track support slabs for the slab track of the ...
  52. [52]
    Stable upswing for Austria's railway infrastructure: framework plan ...
    Oct 25, 2022 · This is also based on the updated planned commissioning of the Brenner Base Tunnel (probably in 2032) and is now planned for 2034. The ...
  53. [53]
    Long‐term monitoring of railway tunnels - Moritz - Wiley Online Library
    Feb 19, 2021 · The paper presents the implementation of long-term monitoring at the projects Koralm Tunnel and Granitztal Tunnel and gives an outlook at the Semmering Base ...Missing: analytics drills
  54. [54]
    EUR 21.1 billion investment for Austrian rail infrastructure
    Nov 9, 2023 · The Austrian rail infrastructure will benefit a EUR 21.1 billion investment under the ÖBB framework plan 2024-2029, which is increased by EUR 2 billion.