Views: 224 Author: Site Editor Publish Time: 2025-06-27 Origin: Site
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● Why do we need "intelligent" bridges?
>> The "hidden cost" of traditional bridges:
● Our Intelligent Solutions: Four Core Technology Modules
“Traditional bridge construction has a long cycle and high operation and maintenance costs? Extreme weather is frequent, and the traditional structure's ability to resist disasters is insufficient?
Our intelligent steel structure movable bridge makes bridges "think, adapt, and evolve"!”
Industry pain points are directly addressed.
concrete bridges:
long construction period (average 6-12 months), high maintenance cost (annual maintenance cost exceeds 5% of the initial construction cost);
relying on manual inspection (lag in fault response), lack of dynamic safety warning.
The rigid demand of the new infrastructure era: emergency projects (rescue and disaster relief, event support) require "72-hour rapid deployment";
Smart cities need the deep integration of bridges and the Internet of Things and digital twins (such as vehicle-road coordination and real-time load monitoring).
Policy and market opportunities
National policy: The Ministry of Housing and Urban-Rural Development's "Outline for the Development of Intelligent Construction" clearly requires that "the intelligent rate of new bridges will exceed 30% by 2025";
ustomer demand: In the bidding documents of a certain provincial transportation department, the intelligent monitoring system has become a mandatory option (attached screenshot data).
Technology module core technology customer value industry comparative advantage
1. Intelligent monitoring system - 300 + node sensor network (strain, displacement, vibration, temperature and humidity)
Real-time analysis of AI algorithms (millisecond-level early warning) - Prevent fatigue fracture: early warning of structural damage 6 months in advance
Reduce operation and maintenance costs: reduce the frequency of manual inspection by 70%. Traditional bridges: only manual inspection + quarterly inspection (high latency)
2.Adaptive structure design - modular assembly (standard unit size ≤3m, hoisting error <2mm)
Dynamic load allocation algorithm (supports real-time traffic control) - Quick setup in 72 hours.
-Enhanced disaster resistance: 8-level earthquake resistance, 12-level typhoon resistance Concrete bridge: Curing period ≥3 months, cannot be dynamically adjusted
3. Digital twin platform - BIM + GIS 3D modeling
Construction progress simulation (error rate <5%)
Data accumulation throughout the entire lifecycle - Improved return on investment.
Fault tracing efficiency improvement: from 3 days to 2 hours Traditional management: paper records + experience-based decision-making (inefficient)
4.Green intelligent operation and maintenance - photovoltaic integrated bridge deck (power generation ≥5kW/m)
Recycled steel ratio ≥ 30% (carbon emissions reduced by 45%) - Lifecycle carbon footprint reduction: meets EU "Green Bridge" certification standards
Reduced operation and maintenance energy consumption: Intelligent lighting system saves 60% of electricity Traditional bridges: Rely on fossil energy, no design for active emission reduction.
