Fact-checked by Grok 2 weeks ago

Krk Bridge

The Krk Bridge (Croatian: Krčki most) is a reinforced concrete arch bridge in Croatia that connects the island of Krk to the mainland across the Krk Channel in the northern Adriatic Sea. Spanning a total length of 1,430 meters with a main arch of 390 meters—the longest concrete arch span in the world upon completion—it was designed and constructed between 1976 and 1980 by a team from the Institute IGH at the University of Zagreb, including engineers Ilija Stojadinović, Vukan Njagulj, and Bojan Možina.^[1]^[2] Opened on July 19, 1980, and originally named Tito's Bridge (Titov most) in honor of Yugoslav president Josip Broz Tito, the bridge revolutionized access to Krk, Croatia's largest island, by replacing ferry services and enabling year-round connectivity for residents, tourists, and commerce; it now handles over one million vehicles annually and supports essential pipelines for oil, gas, and water.^[1]^[3] Built using high-quality C50 reinforced concrete with a low water-cement ratio of 0.36 to withstand the harsh marine environment, the structure rises 67 meters above the sea and features two main arches (390 meters and 244 meters), along with approach viaducts.^[3] Despite its thin 2.5 cm concrete cover exposing it to corrosion risks, regular maintenance has kept it in excellent condition after more than four decades.^[3] Managed by Hrvatske autoceste (HAC) until 2023 and now by Hrvatske ceste, the toll-free bridge (abolished in June 2020) carries the D102 state road and remains a vital artery for the region's tourism-driven economy.^[4]^[5] Plans for a parallel second bridge, announced in 2024, aim to alleviate growing traffic—up to 30,000 vehicles daily in peak season—while adding rail capacity and modern seismic features, with construction targeted for completion by 2029.^[6]

Background

Location and Geography

The Krk Bridge is situated in the northern Adriatic Sea, spanning the narrow inlet between the mainland town of Kraljevica and the northern tip of Krk Island in Primorje-Gorski Kotar County, Croatia.^[7]^[8] It connects the coastal areas of Črišnjeva Bay on the mainland to the Bay of Sveti Marko on the island, facilitating direct land access across approximately 1,430 meters of tidal waters in the Kvarner Bay.^[7]^[9] The bridge's precise geographic coordinates are 45°14′41″N 14°33′56″E, positioning it as a critical link in the region's coastal infrastructure.^[10] Geographically, the structure crosses open tidal channels known locally as the Silent Channel and the Stormy Channel, with water depths accommodating a maximum clearance of 67 meters below the arches to allow maritime passage.^[9] This span integrates with the Jadranska magistrala, Croatia's primary Adriatic coastal highway (D102 state road), enhancing connectivity from nearby Rijeka to the island's internal road network and Rijeka Airport, located on Krk's western coast near Omišalj.^[11] The bridge's placement in the Kvarner Bay, a semi-enclosed gulf, underscores its role in bridging the mainland's industrial hinterland with the island's expansive 405 square kilometer terrain.^[8] The environmental context of the Krk Bridge includes exposure to a seismically active zone along Croatia's Adriatic coast, where design considerations account for potential earthquake forces as per regional engineering standards.^[12] Additionally, its marine setting subjects the structure to saline conditions from sea spray, exacerbated by strong bura winds that can carry saltwater across the deck, contributing to long-term corrosion challenges in the aggressive coastal atmosphere.^[13]^[14] The bridge lies proximate to Rijeka's major industrial port facilities while providing gateway access to Krk Island's prominent tourism zones, including beaches and historical sites around towns like Krk and Baška.^[8]

Historical Context and Planning

Prior to the construction of the Krk Bridge, access to the island of Krk, the largest in the Adriatic Sea, was exclusively dependent on ferry services operated by Jadrolinija, the Yugoslav national shipping company.^[15] These ferries included routes such as Crikvenica-Šilo established in 1959, Križnjevo-Voz in 1964, and Senj-Baška-Lopar in 1969, which handled increasing passenger and vehicle volumes amid post-World War II economic recovery.^[15] By the late 1960s, annual passenger traffic on the Križnjevo-Voz line had surged from 167,802 in 1965 to over 1.4 million in 1977, reflecting the strain on these services due to burgeoning tourism and emerging industrial activities on the island, such as resource extraction and manufacturing tied to nearby Rijeka.^[15] The need for a fixed crossing was first proposed in the 1960s during the era of the Socialist Federal Republic of Yugoslavia, as part of broader efforts to enhance Adriatic connectivity and support regional development.^[16] This initiative addressed the limitations of ferry operations, which could not accommodate the projected rise in vehicle traffic driven by tourism—Krk's mild climate and coastal attractions drew growing numbers of visitors—and industrial expansion, including energy and petrochemical projects.^[16] Feasibility studies conducted in the early 1970s evaluated alternatives like tunnels or additional ferries but ultimately favored a bridge to provide reliable, all-weather access, with preliminary designs emphasizing a structure capable of handling thousands of daily vehicles.^[16] The project received formal approval in 1974 from the Yugoslav federal government, positioning it as a key element of national infrastructure investment to integrate island economies with the mainland.^[16] Key stakeholders included federal and republican authorities in Croatia and Serbia, along with engineering firms like Mostogradnja from Belgrade, which contributed to cost estimates projecting expenses in the hundreds of millions of Yugoslav dinars based on traffic forecasts and economic benefits.^[15] These studies highlighted the bridge's potential to replace overburdened ferries, projecting a reduction in transport delays and costs while boosting annual tourism revenue.^[16] Upon completion in 1980, the structure was initially named Tito's Bridge in honor of Josip Broz Tito, the late Yugoslav president whose administration had championed such infrastructural projects.^[16]

Design and Construction

Engineering Design

The engineering design of the Krk Bridge was led by Ilija Stojadinović in cooperation with Vukan Njagulj and Bojan Možina, who developed the structure as a reinforced concrete arch bridge featuring multiple spans to connect the Croatian mainland to the island of Krk across the Adriatic Sea's Krk Channel.^[17] This design incorporated two primary arch spans—a main span of 390 meters and a secondary span of 244 meters—along with approach viaducts, resulting in a total planned length of 1,430 meters.^[2] The arch configuration was selected for its structural efficiency in achieving long spans while providing inherent stability, particularly through a deck-stiffened system that integrated the roadway deck to enhance rigidity and distribute loads effectively.^[17] Key technical choices emphasized durability in the marine environment, with the arch springings positioned via extended struts below the water level to remain dry and minimize corrosion risks from saltwater exposure.^[2] The bridge's roadway was planned with a width of 11.40 meters to accommodate two traffic lanes, flanked by sidewalks, ensuring sufficient capacity for vehicular and pedestrian use without excessive material demands.^[18] Vertical clearance was specified at 67 meters above the water to allow safe passage for maritime traffic in the channel, balancing navigational needs with the arch's rise for optimal load-bearing geometry.^[2] The initial blueprints incorporated provisions for post-construction adjustments to address concrete creep and shrinkage, using hydraulic jacks to elongate the structure by up to 93 millimeters over three years before permanent encasement, thereby maintaining precise alignment and long-term integrity.^[2] This approach, combined with the arch's compressive strength, made the design cost-effective for the era compared to more complex alternatives like cable-stayed systems, leveraging proven concrete technology for a span that set a European record at the time.^[17]

Construction Process

The construction of the Krk Bridge began in March 1976, with official groundbreaking on March 25 of that year, and spanned four years until its completion in 1980.^[15] The project was executed by main contractor Mostogradnja and subcontractor Hidroelektra, utilizing advanced techniques suited to the marine environment.^[2] The bridge opened to traffic on July 19, 1980, marking a major infrastructural achievement for connecting the island of Krk to the mainland.^[19] The primary construction method involved the cantilever erection procedure for the reinforced concrete arches, specifically a cantilevering truss method where the central arch segment was built first to serve as scaffolding for the lateral sections.^[20] Prefabricated concrete segments, comprising over 60% of the Krk I arch and 86% of the Krk II arch, were assembled in situ using cable-cranes with 10-ton capacity and temporary diagonal stays for stability, while hydraulic jacks adjusted the crown alignment.^[20] This approach minimized the need for extensive falsework in the challenging tidal waters of the Adriatic Sea, where foundations for the Krk I arch were elastically fixed to horizontal beams positioned beneath sea level, and the Krk II arch was anchored directly to rock abutments.^[20] Key events included the meticulous foundation work in the tidal marine setting, which required precise engineering to handle submersion and currents, and the incremental erection of the main 390-meter arch span—the longest reinforced concrete arch in the world at the time—achieved through balanced cantilevering to manage vertical deflections and ensure structural integrity.^[20] Logistics were complex due to the remote island site, involving coordinated transport of heavy prefabricated materials across water and land, while weather posed significant hurdles, including sudden bura winds exceeding 200 km/h and large temperature swings that threatened alignment and safety during arch assembly.^[21] These challenges were overcome through temporary cable-stays and steel trusses, which also contributed to cost efficiencies in labor and materials.^[20] The overall effort demanded substantial inputs of labor from engineering teams and on-site workers, along with extensive use of reinforced concrete in three-cell box-type cross-sections.

Technical Features

Structural Specifications

The Krk Bridge is a reinforced concrete arch structure spanning the Adriatic Sea channel between the Croatian mainland and the island of Krk via the islet of Sveti Marko. It features two main reinforced concrete arches—the main one with a span of 390 m (1,280 ft) and a smaller one with a span of 244 m—supported by approach viaducts that contribute to the overall configuration. The total length of the bridge measures 1,430 m (4,692 ft), accommodating vehicular traffic across the narrow sea passage.^[3]^[22] Key dimensions include a deck width of 11.40 m (37 ft), providing space for the roadway without additional shoulders or medians beyond basic safety features. The clearance height beneath the main arch reaches 67.02 m (220 ft) above sea level, while the smaller arch offers 54.56 m (179 ft), ensuring navigational passage for maritime vessels. The main arch's effective span extends to 416 m (1,365 ft) when accounting for the underwater foundation portion embedded in the seabed.^[22]^[23]^[24] The bridge's superstructure consists of two main reinforced concrete arches supported by approach viaducts, all utilizing high-strength concrete with compressive strengths around C50 to C60/75. It supports two traffic lanes—one in each direction—for standard highway vehicles, with no dedicated pedestrian walkways or facilities.^[3]^[25] Load-bearing capacities adhere to 1970s Yugoslav engineering standards, equivalent to German DIN 1072 for general design, with seismic resistance modeled per preliminary European norms and wind loading assessed for gusts up to 42.7 m/s in the Adriatic environment. The structure is optimized for heavy vehicular loads typical of regional highways, including trucks up to standard axle limits, while incorporating reinforcements for marine corrosion and dynamic forces.^[26]^[12]

Innovations and Records

The Krk Bridge achieved several engineering records upon its completion in 1980, most notably holding the world record for the longest span of a reinforced concrete arch at 390 meters, one of the longest reinforced concrete arch spans globally and the longest pure reinforced concrete arch span outside China.^[3]^[27] This span, part of the bridge's two-arch configuration (the second measuring 244 meters), represented the largest structure of its type at the time, surpassing previous benchmarks in reinforced concrete arch design.^[3] Key innovations in the bridge's design and construction enabled these records while addressing the challenging marine environment. The arches were erected using a free cantilevering technique with trussed arch cantilevers, allowing construction without extensive temporary supports in the water and facilitating the unprecedented span length.^[27] The design incorporated a buildability criterion that prioritized constructibility alongside structural integrity, optimizing the arch geometry to minimize dead load and enable the record span through iterative analysis of erection stages.^[28] For enhanced durability against the Adriatic's saline conditions, high-strength C50 concrete (achieving 55.6 MPa compressive strength) was formulated with Portland cement blended with 20% slag, reducing permeability and chloride ingress to promote long-term resistance in the aggressive marine setting.^[3] As a milestone, the Krk Bridge marked the first direct fixed road connection between a major Adriatic island and the mainland, eliminating reliance on ferries and transforming access to Krk Island for its residents and tourists.^[1] This pioneering link influenced subsequent global arch bridge designs by demonstrating the feasibility of large-span cantilever methods and durable concrete formulations in seismic, windy, and corrosive coastal zones, inspiring similar projects worldwide.^[28]^[27]

Operation and Impact

Traffic and Usage

The Krk Bridge handles over 1 million vehicles annually, serving as a critical link for both residents and tourists accessing the island of Krk.^[22] In its first two decades of operation from 1980 to 2000, the bridge accommodated 27 million vehicle crossings, more than double the previous ferry traffic volume to and from the island.^[6] This significant increase in capacity has transformed travel patterns, eliminating the need for seasonal ferry dependencies and enabling consistent year-round access. Traffic management on the bridge evolved notably over time. It operated as a toll facility from its opening until June 15, 2020, with passenger cars charged 35 Croatian kuna (HRK) for southbound crossings.^[29] Following the abolition of tolls, responsibility for the bridge transferred to Hrvatske autoceste d.o.o. on January 1, 2021, as part of the merger of national motorway operators; it was then handed over to Hrvatske ceste effective December 31, 2023.^[30]^[4] The structure connects directly to the D102 state road on the mainland and integrates with the island's internal road network, facilitating seamless distribution of traffic toward key destinations. Usage trends reflect the bridge's role in supporting tourism and regional connectivity. Peak volumes occur during summer months due to heightened tourist influx, often resulting in congestion and queues extending several kilometers.^[31] The bridge enhances access to Rijeka Airport on Krk Island, serving as the primary land route for air travelers. Initially designed solely for road traffic with no railway component, it continues to operate without rail integration. The Krk Bridge has significantly boosted tourism on Krk Island by providing reliable road access, leading to an annual increase in guest numbers since its opening in 1980.^[32] This enhanced accessibility has reduced dependency on ferries, saving time and costs for travelers and supporting the island's economy, which relies heavily on tourism.^[33] In its first 20 years, the bridge facilitated over 27 million vehicle crossings, more than double the previous ferry traffic volume, underscoring its role in economic integration.^[32] Additionally, the bridge has supported industrial growth by improving connectivity to the Port of Rijeka, a major hub for maritime trade in the Primorje-Gorski Kotar County.^[32] Socially, the bridge has improved daily life for the island's approximately 19,000 residents by eliminating isolation and enabling seamless links to mainland services, including Rijeka Airport for faster travel. This connectivity has enhanced emergency access, allowing quicker response times for medical and disaster services across the region.^[1] The structure has fostered a cultural shift, transforming Krk from a remote island community reliant on seasonal ferries to an integrated part of Croatia's coastal network, promoting year-round social and economic interactions.^[32] Over the long term, the Krk Bridge has contributed to Croatia's Adriatic infrastructure development by serving as a model for island-mainland connections that drive regional prosperity.^[32] Toll revenues from the bridge funded its maintenance and operations until the tolls were abolished on June 15, 2020, after which state resources took over.^[5]

Maintenance and Preservation

Challenges and Repairs

The Krk Bridge, situated in a highly aggressive maritime environment along the Croatian Adriatic coast, has faced significant challenges from salt-induced corrosion primarily due to strong winds that spray seawater and airborne salts onto the structure. This exposure has led to the degradation of the reinforced concrete, particularly affecting the thin concrete cover over the rebar, accelerating reinforcement corrosion and contributing to structural wear. Additionally, the bridge's location in a seismically active region necessitates ongoing consideration of earthquake risks, with analyses confirming its design accommodates potential ground motions but highlighting vulnerabilities in long-term performance under combined environmental and seismic loads. The increasing traffic volume, exceeding 1 million vehicles annually, has further exacerbated wear on the deck and supports, amplifying fatigue and maintenance demands without resulting in any major structural failures to date.^[25]^[34]^[35] Routine inspections in the 1990s and 2000s revealed cracking in various elements, attributed to environmental factors such as corrosion from salt ingress and biological damage from marine organisms like sea shells on underwater foundations, which compromised concrete integrity and arch stability. Post-construction interventions began in the mid-1980s with initial monitoring and testing to address emerging issues in superstructure supports and arches, including the application of protective coatings and inhibitors following trials of over 20 systems. By the early 1990s, specialized scaffolding facilitated targeted repairs, involving hydrodemolition to remove deteriorated concrete, treatment of exposed rebar, and application of high-strength mortars and polymer coatings to enhance durability and prevent further degradation. These efforts focused on maintaining the 390-meter main arch's stability, which has remained intact despite the challenging conditions.^[3]^[3] A major preservation project in 2019 addressed widespread rebar corrosion by applying Migrating Corrosion Inhibitor (MCI-2020) to concrete surfaces across the bridge, following the removal of contaminated layers to the depth of the reinforcement. This surface-applied treatment, selected after comparative testing of materials from five producers and verified by engineering firm IGH in Zagreb, migrates into the concrete to form a protective layer on steel bars, halting further corrosion and extending service life. The project, part of phased repairs costing approximately 1 million EUR annually, involved cleaning and moistening surfaces before inhibitor application and subsequent repair mortar spraying, ensuring minimal disruption to the high-traffic structure.^[34]^[36]

Ongoing Maintenance Strategies

The ongoing maintenance of the Krk Bridge is managed by Hrvatske ceste d.o.o.^[4], which conducts annual inspections and corrosion monitoring to ensure structural integrity in its aggressive maritime environment. These protocols include visual assessments of concrete surfaces and reinforcement, supplemented by non-destructive testing (NDT) methods such as half-cell potential measurements and electrical resistivity testing to detect early signs of chloride-induced corrosion without invasive procedures.^[37] This proactive approach allows for timely interventions, addressing the bridge's exposure to high salinity and strong winds that have historically accelerated rebar deterioration.^[36] A key strategy implemented since 2019 is the application of MCI-2020, a migrating corrosion inhibitor developed by Cortec Corporation, as part of a 30-year preservation plan.^[38] MCI-2020 is surface-applied after cleaning and moistening affected concrete areas, allowing it to penetrate and form a protective layer on steel reinforcement bars, thereby halting further corrosion and extending service life.^[39] This treatment is integrated into phased repair projects, where it is followed by spray-on mortar to restore concrete cover, ensuring long-term safeguarding of the rebar in the bridge's arches and supports.^[36] Cathodic protection systems, installed on the substructure of the main 390-meter arch since 2010, represent another critical technology for ongoing upkeep.^[40] These impressed current systems use titanium mesh anodes for atmospheric exposure and disc anodes for submerged sections, with automatic data logging for half-cell potentials to monitor effectiveness and adjust output as needed.^[40] Integrated during repairs, they provide a 20-year design life, reducing corrosion rates by shifting potentials to protective levels (e.g., approaching -720 mV vs. Ag/AgCl).^[40] Maintenance costs average approximately 1 million EUR annually, covering both regular inspections and extraordinary interventions like inhibitor applications and anode maintenance.^[38] Following the removal of tolls in June 2020, these expenses are funded through the national budget, reflecting the bridge's strategic importance as a toll-free vital link.^[5]

Future Developments

Replacement Plans

Plans for a second bridge parallel to the Krk Bridge have been developed to address longstanding infrastructure challenges on the Croatian island of Krk. The new structure is proposed to be located approximately 1.8 km south of the existing bridge, near the Lanterna peninsula, spanning the Mala Vrata channel from the mainland's Črišnjeva bay to the island's Maltempo fortress area. This positioning avoids crossing the smaller St. Marko island and integrates with planned extensions toward the Omišalj port terminal.^[41]^[42]^[43] The design features a two-level configuration, with four lanes for vehicular traffic on the upper deck and a dedicated single-track railway line on the lower level to facilitate freight and passenger transport. The main span is planned to exceed 600 meters, reaching approximately 850 meters over the sea, as part of a total project length surpassing 7 km that includes a 900-meter viaduct and a 740-meter tunnel. Enhanced engineering will incorporate seismic resilience and corrosion-resistant materials to withstand the Adriatic's harsh marine environment, including wind and salt exposure protections. In June 2024, a Croatian-Slovenian consortium won the tender for the design phase.^[41]^[42]^[44]^[45] Key motivations for the new bridge stem from the existing bridge's overcapacity, exacerbated by seasonal traffic surges that frequently cause congestion. Additionally, the project aims to enable rail connectivity to support the expansion of the Omišalj port, integrating island logistics with mainland networks. The current bridge's traffic overload, handling over 4 million vehicles annually, underscores the urgency for this upgrade.^[41]^[42]^[43] As of 2025, the project is in the design and environmental impact assessment phase, expected to span 3-5 years from the 2024 tender launch, with construction to follow and the full project targeted for operational status by 2030. The initiative, valued in preliminary estimates at hundreds of millions of euros, will proceed in phases, with the existing bridge remaining in use during the build.^[43]^[41]^[42]

Expected Benefits

The new Krk Bridge is anticipated to deliver substantial infrastructure improvements, primarily through doubling the road capacity from the current two lanes to four lanes, thereby accommodating higher volumes of vehicular traffic. Additionally, the inclusion of a dedicated lower-level railway will enable freight transport by rail, diverting heavy goods from roads and significantly reducing congestion on the existing structure, which currently faces overload from port-related expansions and seasonal peaks. This dual-purpose design will provide direct access to the A7 motorway and the new Omišalj container terminal, enhancing overall logistical efficiency in the region.^[44] Economically and socially, the project is expected to boost tourism and trade by improving connectivity to Krk Island, one of Croatia's premier destinations, and supporting the expansion of the Rijeka port system, including the new container terminal that will handle increased cargo volumes. These enhancements are projected to lower operational costs for transport operators over the long term through more reliable infrastructure, while modern features such as wind protection measures will elevate safety standards and contribute to environmental goals by promoting rail over road freight, aligning with sustainable mobility objectives. The alleviation of the current bridge's structural challenges from overuse will further ensure safer passage for the millions of annual visitors and residents.^[43]^[42]^[46] On a regional level, the new bridge will bolster Croatia's integration into the European Union's Trans-European Transport Network (TEN-T) by strengthening links between North Adriatic ports and inland routes, facilitating smoother cross-border trade and mobility. With traffic volumes expected to rise substantially by 2030 due to economic growth and tourism recovery, the project addresses the impending overload on the existing bridge, projected to see at least a 50% increase in demand, thereby sustaining regional development and EU-aligned transport priorities.^[47]^[46]

References

[1]
(PDF) An overview of Krk Bridge repairs - ResearchGate
Krk Bridge is still the biggest reinforced concrete arch bridge with the longest concrete arch span in the world (390 m) and in spite of the designed ...Missing: sources | Show results with:sources
[2]
Krk Bridge – an Engineering Marvel That Transformed the Island of Krk
May 20, 2023 · The construction lasted from 1976 to 1980 and was led by engineers Ilija Stojadinović, Vukan Njagulj, and Bojan Možina. The work was carried out ...Missing: Croatia sources
[3]
[PDF] CROATIA National report on motorways 2023.pdf - Asecap
As on 31st. December 2023, the total length of the motorway network in Croatia is 1,341.10 km. ... the Bridge Krk was handed over for operation to Hrvatske ...Missing: details | Show results with:details
[4]
Abolishment of Krk bridge toll officially marked - Ministarstvo turizma
Jun 15, 2020 · The Krk bridge toll was abolished on Monday, June 15, due to road sector debt and savings from merging road companies. This was important for ...
[5]
Croatia: new Krk bridge coming in 2029 - SeaHelp
Feb 27, 2024 · In order to relieve the old Tito Bridge from 1980, a new, larger bridge is also being built from the mainland to the island of Krk. This ...Missing: engineering history
[6]
Krk Bridge - Visit Kraljevica
The Krk Bridge connects the mainland with Island Krk, linking Črišnjeva and Scott to Omišalj. It has a 390m arch and is free to cross.
[7]
About the island of Krk tourism
The island of Krk, our largest island (of around 410 square kilometers) has, thanks to its desirable geographical and transport position and good natural ...
[8]
Krk Island - Krk Bridge | HR-CRO - Croatia
The length of the Krk bridge with all accesses is 1430 meters, the height is 67 meters and the width of the bridge is 7.5 meters. It consists of two arches, the ...Missing: Kamnik inlet
[9]
File:Krk Bridge.jpg - Wikimedia Commons
Camera location, 45° 14′ 41.28″ N, 14° 33′ 56.3″ E Kartographer map based ... List of bridges in Croatia. Usage on es.wikipedia.org. Anexo:Puentes en arco ...
[10]
How to get to and from Rijeka-Krk Airport in Croatia
Jun 28, 2023 · There is no toll for this bridge. If you are traveling to the islands of Cres or Lošinj, first go to Valbiska on Krk. From Valbiska, there are ...
[11]
https://www.expatincroatia.com/how-to-get-to-and-from-rijeka-krk-airport/
[12]
[PDF] Chlorides ingress as an environmental load on Krk bridge - ABECE
Chloride analysis were per- formed on the Krk bridge (Adriatic coast), which has been exposed to marine environment for 25 years. Surface chloride concentration ...Missing: seismic | Show results with:seismic
[13]
Krk Bridge | Smartec
Jan 31, 2017 · The Krk bridge was exposed to strong wind (called bura) which raised the salt water and spread it all over the bridge substructure.Missing: seismic zone
[14]
[PDF] TRAFFIC SYSTEM ON THE ISLAND OF KRK
Aug 23, 2025 · The construction of the Krk bridge began officially on. March 25, 1976 and the opening was planned for No- vember 29, 1979, but was realised ...
[15]
https://traffic2.fpz.hr/index.php/PROMTT/article/download/1863/740
[16]
[PDF] CONTEMPORARY CONCRETE ARCH BRIDGES
Just five years later, Ilija Stojadinovic, in cooperation with Vukan Njagulj and Bojan Možina, designed the outstanding Krk. Bridges (Fig. 14), in Croatia ...Missing: original | Show results with:original
[17]
Krk Bridges (Krk, 1980) - Structurae
Participants ; Vukan Njagulj (design engineer) ; Bojan Mozina (design engineer) ; Ilija Stojadinovic (designer).Missing: original | Show results with:original
[18]
Krk Bridge - Mare Tours
On the island of Pag, a 301 m-long bridge was built in 1968. · The island of Vir is connected to the mainland by a 378-m-long bridge built in 1976.Missing: history sources
[19]
How to reach us - Otok Krk
The easiest way to get to the island of Krk is by car over the Krk bridge, and by plane in the airport situated close to Omišalj. You can also arrive on the ...
[20]
[PDF] 35316837.pdf - CORE
Construction method drawing of the Krk I bridge. The arches Krk I and Krk II of the bridge were constructed by cantilevering truss method (Fig. 4.43) and ...
[21]
Krk bridge - Sitolor d.o.o.
Sep 13, 2022 · ... height of the bridge itself which is 67 m, all this represented an additional challenge our engineers and construction workers. With our ...Missing: waters | Show results with:waters
[22]
Krk Bridge - Wikipedia
Krk Bridge (Croatian: Krčki most) is a 1,430 m (4,692 ft) long reinforced concrete arch bridge connecting the Croatian island of Krk to the mainland.
[23]
Krk Bridge - Megaconstrucciones.net English Version
A 1430 m long reinforced concrete arch bridge connecting the Croatian island of Krk to the mainland and carrying over a million vehicles per year.Missing: original design length 390 width 11.40 67 cost 50
[24]
Toll obligation for Krk bridge to be abolished from 15 June 2020
May 25, 2020 · The construction of the Krk Bridge, with a total length of 1450 metres (both arches) and a width of 11.40 metres, began in July 1976, and the ...Missing: details | Show results with:details
[25]
Krk Bridge | Information: Croatia
It also connects the city of Rijeka to Rijeka Airport, which is situated on Krk. In the first 20 years of its existence, the bridge was crossed by 27 million ...
[26]
Reinforced concrete bridge exposed to extreme maritime ...
Feb 15, 2020 · The paper provides a brief overview of in-service performance of the Krk Bridge on the Croatian Adriatic coast, where combination of aggressive maritime ...
[27]
Abolishment of Krk bridge toll officially marked - Croatia Week
Jun 15, 2020 · Abolishment of Krk bridge toll officially marked · by croatiaweek · June 15, 2020 · in News.Missing: cost | Show results with:cost
[28]
Krk bridge (Krk II and Krk I). - ResearchGate
In the Krk bridge region, the gust speeds domain specifically is from 41m/s (v10 min) to 51 m/s (max) [6] . There are 138 days around the area with wind speeds ...
[29]
[PDF] Eurocode requirements on Adriatic arch bridges
Šibenik, old Pag and Krk bridge, located in the III zone of strong Bora wind, were designed ac- cording old code PTP-5 for the wind pressure of 1.3 kN/m2 on the ...Missing: saline | Show results with:saline
[30]
Not Found | Emerald Publishing
**Summary:**
[31]
Getting to Krk Island, by car, plane, train or bus - Croatia Expert
The length of the Krk bridge is 1430 meters and the toll for cars is 35 kuna ... The toll on relation Zagreb – Ostrovica for cars is 60 kuna. Krk Town. If ...
[32]
Croatian motorway operators ARZ and HAC to merge - Croatia Week
May 21, 2020 · ZAGREB, May 21 (Hina) - The Autocesta Rijeka (ARZ) and Hrvatske Autoceste (HAC) motorway operators will merge, and the Krk Bridge toll will be
[33]
Roads are jammed as Croatia hits peak part of the tourism season
Jul 15, 2023 · Road traffic was very heavy on the Krk Bridge as well, with lines in both directions stretching up to 4 kilometers at one point. The ...
[34]
[PDF] ECONOMIC COMPARISON OF MOTORWAY CONCESSIONARIES ...
For 20 years, 27.2 million vehicles have crossed the bridge, and the number of guests on the island of. Krk is increasing every year in which the Krk Bridge ...
[35]
Second home properties on Krk - why are they in demand?
Oct 30, 2025 · One of the greatest comparative advantages of Krk is its connection to the mainland via the Krk Bridge, which eliminates dependence on ferry ...
[36]
[PDF] Effectiveness of MCI® Surface Protection System in Krk Bridge ...
Mar 28, 2019 · Application of MCI® -2020 will stop further corrosion of reinforcing metals and extend the service life of the bridge. Preservation Project.
[37]
Seismic assessment of a long-span arch bridge considering the ...
The Krk I Bridge, 390 m long concrete arch, built in 1980, was the largest bridge of its kind at the time of its construction. In the last 20 years several ...
[38]
Case Study: Effectiveness of MCI Surface Protection System in Krk ...
Apr 10, 2019 · The Krk Bridge is a reinforced concrete arch bridge that connects ... design was done by IGH, Institute for Civil Engineering in Zagreb.
[39]
[PDF] Assessment of reinforcement corrosion and concrete damage on ...
Oct 10, 2019 · Cracks and concrete damage caused by other mechanical and non-mechanical processes additionally accelerate corrosion processes and cause ...<|control11|><|separator|>
[40]
Cortec provides MCI 2020 protection for Croatia's Krk Bridge
Krk Bridge is a 1.4km reinforced concrete arch bridge ... design was done by IGH, Institute for Civil Engineering, based in the Croatian capital Zagreb.
[41]
[PDF] Effectiveness of MCI® Surface Protection System in Krk Bridge ...
Krk Bridge ... The field investigation of the current status and the preservation project design was done by IGH,. Institute for Civil Engineering in Zagreb.
[42]
(PDF) Cathodic Protection of the Krk Bridge - ResearchGate
Implementation of this procedure into our practice is of great importance, because we considered that cathodic protection (CP) may be required for service life ...Missing: destructive | Show results with:destructive
[43]
Novi krčki most: Imat će dvije etaže, četiri trake za automobile, prugu, zaštitu od buke
### Summary of Proposed New Krk Bridge (Poslovni.hr, 10 Feb 2024)
[44]
New Krk Bridge to Boast Modern Features - Total Croatia News
Feb 11, 2024 · The bridge itself will be span 850 metres over the sea, but the traffic part of the project isn't only the bridge, but also a viaduct over the ...Missing: details | Show results with:details
[45]
Plans for new dual-use Krk Island bridge unveiled | Croatia Week
Jan 3, 2024 · The proposed bridge will feature lanes for road traffic and a corridor for a railway line extending to the island of Krk.
[46]
Croatia to construct a new bridge from the mainland to Krk Island
Mar 7, 2024 · Over recent years, salt exposure has led to concrete degradation and cracking. Furthermore, the current Tito Bridge's capacity has been exceeded ...
[47]
None
Below is a merged summary of the mentions, traffic projections, capacity issues, planned improvements and benefits, and useful URLs related to Krk Bridge and Krk Island in the *Transport Development Strategy of the Republic of Croatia (2017–2030)*. To retain all information in a dense and organized format, I will use a table in CSV format for key details, followed by a concise narrative summary that integrates all segments.
[48]
[PDF] Rijeka Gateway project - World Bank Documents & Reports
The ultimate purpose of the Rijeka Gateway Project is to increase the trade competitivcness of Croatia by improving the international transportation chain ...