Explosion-Proof Firefighting Robots for Oilfields
Product Description
Protecting Lives and Assets: Explosion-Proof Firefighting Robots for Oilfields RXR-MC80BD
Product Overview
RXR-MC80BD
is designed and produced according to GB3836-2010 explosion-proof standard.
It can replace fire and rescue personnel to enter the scene of inflammable, toxic, hypoxia, smoke and other dangerous disasters and accidents for fire fighting, effectively solve the personal safety of fire personnel in the above places. Simple body design, more stable, with high power DC deceleration motor to make obstacles become particularly simple.
Introduction:
Oilfields are complex and high-risk environments where the safety of personnel and assets is of utmost importance. Fire incidents in oilfields can have catastrophic consequences, threatening both human lives and critical infrastructure. To address these challenges and enhance fire safety measures, explosion-proof firefighting robots have emerged as indispensable assets in oilfield operations. This article explores how these advanced robots play a crucial role in protecting lives and safeguarding valuable assets in oilfields.
First Responders in Hazardous Environments: Explosion-proof firefighting robots act as the first line of defense in the event of a fire incident in oilfields. Their ability to operate in hazardous environments, including those with flammable gases and volatile substances, makes them ideal for early fire response before human responders can safely enter the area.
Swift and Proactive Fire Suppression: Time is of the essence in fire emergencies, and the efficiency of fire suppression is crucial. Explosion-proof robots are equipped with state-of-the-art sensors and AI algorithms, allowing them to swiftly identify fire sources and act proactively to suppress fires before they escalate.
Reducing Human Exposure to Risks: Oilfields present numerous risks, and firefighting in such environments can be perilous for human responders. By deploying explosion-proof robots, oilfield operators can significantly reduce the exposure of their personnel to hazardous conditions, ensuring their safety during firefighting operations.
Real-Time Data for Informed Decision-Making: Explosion-proof robots provide real-time data and situational awareness to human operators and incident commanders. This data includes temperature readings, gas concentrations, and the fire's progression, empowering responders to make informed decisions and tailor firefighting strategies for optimal outcomes.
Navigation in Challenging Terrain: Oilfields often feature complex structures, confined spaces, and uneven terrain, making firefighting operations challenging for humans. Explosion-proof robots are designed to maneuver through such environments with precision and agility, accessing areas that might be difficult for human responders to reach.
Collaborative Firefighting Approach: In many cases, explosion-proof robots can work collaboratively with human firefighters. By operating in tandem, they create a more effective and efficient firefighting force, leveraging the strengths of both human intelligence and robotic capabilities.
Conclusion: The deployment of explosion-proof firefighting robots in oilfields has significantly improved fire safety standards, protecting human lives and valuable assets. As first responders in hazardous environments, these robots swiftly and proactively suppress fires, reducing risks to human responders. Their real-time data feedback and ability to navigate challenging terrains make them invaluable assets in oilfield operations. By integrating explosion-proof robots into their fire response strategies, oilfield operators reinforce their commitment to protecting lives and preserving critical infrastructure, ensuring the safety and continuity of their operations even in the face of fire emergencies.
Product Equipments
Thermal Infrared Image Camera
TFT Fire Monitor: 80L/S flow, water/foam dual-purpose, range 80 meters
Gas collection: The collection of six gases around the robot body
Lighting: double LED strong lightAcoustic-optic
Alarm: the robot sends out acoustic-optic alarm under the running state of the robot body
Automatic obstacle avoidance: always detect obstacles in front to avoid collision
Spray cooling: water curtain spray cooling
Application Sites
Product Parameter
| Chassis configuration parameters | |||
| Dimension | 1612*910*1427mm | Weight quality | 726kg |
| Max obstacle height | 》220mm | Climbing ability | >70% |
| Direct run deviation volume | 《5.1% | Speed | >1.5m/s |
| Infrared thermal imager | Yes | Braking distance | <0.15m |
| Anti-collision function | yes | Spray cooling device | yes |
| Lighting | yes | Acoustic-optical alarm function | yes |
| Wading depth | 400mm | Water-proof function | IP67, top IP65 |
| Drag water belt ability | 2pcs80water belt 100M | Working time | 5h |
| Remote distance | 1000m | Speed control way | Wireless control |
| Gas collection | O2/CO2/CO/H2S/CH4/NH3 6kinds of toxic and combustible gases | ||
| Fire water cannon configuration parameters | |||
| Working pressure | 1.0MPA | Flow | 80L/s |
| Fire range | Water>85M, foam>80M | Pitching angle | -18~90 degree |
| Rotary | -45 ~ +45 degree | ||
| Control box configuration parameters | |||
| Dimension | 467*366*188mm | Weight | <10kg |
| Display size | 15inch | Working pressure | 24VDC/12VDC |
| Digital transmission frequency | 902-928MHZ | Format | Portable |
| Camera configuration parameters | |||
| Working temperature | DC12V | Signal system | PAL or webcam |
| Average relative humidity | <95%(+25degree) | Cloud platfrom performance | initial height>1430mm, lift up the rear height>1940mm |
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