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.
Fire safety is a critical concern in oilfields, where the presence of flammable substances and complex infrastructure poses significant risks. The need for swift and precise fire response is essential to prevent potentially catastrophic incidents. Explosion-proof robots equipped with real-time monitoring capabilities have emerged as indispensable tools in enhancing fire safety measures in oilfields. This article explores the vital role of these advanced robots in real-time monitoring and how they contribute to elevating fire safety standards in the challenging environment of oilfields.
Continuous Situational Awareness: Explosion-proof robots are equipped with a range of advanced sensors that continuously monitor the environment for changes in temperature, gas concentrations, and other critical parameters. This real-time data provides firefighters and incident commanders with a comprehensive understanding of the fire's progression, allowing them to assess the situation and make informed decisions.
Early Detection and Prompt Response: Real-time monitoring enables explosion-proof robots to detect fires in their nascent stages. The early detection capability allows these robots to initiate prompt responses before the fire escalates, preventing potential disasters and minimizing damage to oilfield infrastructure.
Remote Surveillance and Data Transmission: Firefighting robots can be operated remotely, allowing operators and incident commanders to control them from a safe distance. This remote capability ensures that human responders can assess the situation without entering hazardous areas, reducing exposure to potential risks.
Data-Driven Decision Making: The data gathered by explosion-proof robots during real-time monitoring provides valuable insights for decision-making. Incident commanders can use this information to develop effective firefighting strategies, allocate resources efficiently, and implement targeted fire suppression measures.
Enhancing Coordination and Communication: Real-time data transmission from the robots enhances coordination and communication among firefighting teams. Incident commanders can receive immediate updates on the fire's progression and adjust their plans accordingly, facilitating a more coordinated and collaborative fire response effort.
Preemptive Measures: Beyond fire response, real-time monitoring by explosion-proof robots can facilitate preemptive measures. Regular monitoring and inspections can identify potential fire hazards and maintenance issues, enabling proactive actions to prevent fire incidents before they occur.
Conclusion: In the ever-evolving landscape of fire safety, explosion-proof robots with real-time monitoring capabilities have emerged as transformative assets in oilfield operations. Their ability to provide continuous situational awareness, detect fires early, and transmit data in real-time empowers firefighting teams with invaluable insights for efficient and targeted fire suppression efforts. As the oil and gas industry continues to prioritize safety, the integration of explosion-proof robots in real-time monitoring will play a pivotal role in ensuring the safety of personnel and safeguarding critical infrastructure in oilfields.
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
1. Application Scenario: Forest Firefighting
Description: The 4WD Track Firefighting Robot is designed to combat and extinguish forest fires efficiently. Equipped with advanced fire suppression systems, this robot can navigate through rugged terrains and reach remote areas that are difficult to access by humans. It utilizes its powerful water cannons and foam dispensers to suppress flames effectively, preventing the fire from spreading further. Additionally, the robot can collect real-time information about the fire, including its size, location, and intensity, providing crucial data to firefighters for strategic decision-making.
2. Application Scenario: Urban Firefighting
Description: In urban areas, the 4WD Track Firefighting Robot plays a vital role in extinguishing fires in high-rise buildings, industrial complexes, and other urban structures. With its robust mobility and agility, this robot can swiftly navigate through narrow corridors, staircases, and debris-filled environments. It utilizes its water cannons, foam dispensers, and thermal imaging cameras to locate and suppress fires effectively. Moreover, the robot can transmit live video feeds to the command center, enabling firefighters to assess the situation remotely and devise appropriate firefighting strategies.
3. Application Scenario: Search and Rescue Operations
Description: The 4WD Track Firefighting Robot serves as a valuable asset in search and rescue operations during natural disasters or emergencies. Equipped with sensors and cameras, this robot can traverse hazardous terrains, such as collapsed buildings or unstable structures, to locate and rescue trapped individuals. It can transmit real-time audio and video feeds to rescue teams, aiding in decision-making and ensuring the safety of both victims and rescuers. Additionally, the robot's ability to withstand extreme temperatures and adverse conditions makes it an ideal tool for locating survivors in challenging environments.
4. Application Scenario: Industrial Hazard Response
Description: The 4WD Track Firefighting Robot finds extensive use in industrial settings where hazardous materials and potentially dangerous situations are prevalent. It can be deployed to handle incidents involving chemical spills, explosions, or other emergencies. The robot's specialized sensors and detectors enable it to identify and assess hazardous substances, ensuring the safety of human responders. With its fire suppression capabilities, the robot can also control and extinguish fires in industrial facilities, minimizing the risk of further damage and protecting valuable assets.
5. Application Scenario: Military and Defense Operations
Description: The 4WD Track Firefighting Robot plays a crucial role in military and defense operations, particularly in combat situations or during hazardous missions. This robot can be deployed to extinguish fires caused by explosions, combat situations, or accidents, reducing the risk of collateral damage. Its ability to collect real-time information about the incident area, including enemy presence or potential threats, provides valuable intelligence to military personnel. Additionally, the robot's rugged construction and advanced mobility allow it to traverse challenging terrains, making it an asset in various military operations.
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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00001. Firefighting robot
00002. Fire robot
00003. Fire rescue robot
00004. Fire suppression robot
00005. Fire response robot
00006. Fire emergency robot
00007. Fire extinguishing robot
00008. Fire safety robot
00009. Fire service robot
00010. Firefighter robot
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.
Fire safety is a critical concern in oilfields, where the presence of flammable substances and complex infrastructure poses significant risks. The need for swift and precise fire response is essential to prevent potentially catastrophic incidents. Explosion-proof robots equipped with real-time monitoring capabilities have emerged as indispensable tools in enhancing fire safety measures in oilfields. This article explores the vital role of these advanced robots in real-time monitoring and how they contribute to elevating fire safety standards in the challenging environment of oilfields.
Continuous Situational Awareness: Explosion-proof robots are equipped with a range of advanced sensors that continuously monitor the environment for changes in temperature, gas concentrations, and other critical parameters. This real-time data provides firefighters and incident commanders with a comprehensive understanding of the fire's progression, allowing them to assess the situation and make informed decisions.
Early Detection and Prompt Response: Real-time monitoring enables explosion-proof robots to detect fires in their nascent stages. The early detection capability allows these robots to initiate prompt responses before the fire escalates, preventing potential disasters and minimizing damage to oilfield infrastructure.
Remote Surveillance and Data Transmission: Firefighting robots can be operated remotely, allowing operators and incident commanders to control them from a safe distance. This remote capability ensures that human responders can assess the situation without entering hazardous areas, reducing exposure to potential risks.
Data-Driven Decision Making: The data gathered by explosion-proof robots during real-time monitoring provides valuable insights for decision-making. Incident commanders can use this information to develop effective firefighting strategies, allocate resources efficiently, and implement targeted fire suppression measures.
Enhancing Coordination and Communication: Real-time data transmission from the robots enhances coordination and communication among firefighting teams. Incident commanders can receive immediate updates on the fire's progression and adjust their plans accordingly, facilitating a more coordinated and collaborative fire response effort.
Preemptive Measures: Beyond fire response, real-time monitoring by explosion-proof robots can facilitate preemptive measures. Regular monitoring and inspections can identify potential fire hazards and maintenance issues, enabling proactive actions to prevent fire incidents before they occur.
Conclusion: In the ever-evolving landscape of fire safety, explosion-proof robots with real-time monitoring capabilities have emerged as transformative assets in oilfield operations. Their ability to provide continuous situational awareness, detect fires early, and transmit data in real-time empowers firefighting teams with invaluable insights for efficient and targeted fire suppression efforts. As the oil and gas industry continues to prioritize safety, the integration of explosion-proof robots in real-time monitoring will play a pivotal role in ensuring the safety of personnel and safeguarding critical infrastructure in oilfields.
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
1. Application Scenario: Forest Firefighting
Description: The 4WD Track Firefighting Robot is designed to combat and extinguish forest fires efficiently. Equipped with advanced fire suppression systems, this robot can navigate through rugged terrains and reach remote areas that are difficult to access by humans. It utilizes its powerful water cannons and foam dispensers to suppress flames effectively, preventing the fire from spreading further. Additionally, the robot can collect real-time information about the fire, including its size, location, and intensity, providing crucial data to firefighters for strategic decision-making.
2. Application Scenario: Urban Firefighting
Description: In urban areas, the 4WD Track Firefighting Robot plays a vital role in extinguishing fires in high-rise buildings, industrial complexes, and other urban structures. With its robust mobility and agility, this robot can swiftly navigate through narrow corridors, staircases, and debris-filled environments. It utilizes its water cannons, foam dispensers, and thermal imaging cameras to locate and suppress fires effectively. Moreover, the robot can transmit live video feeds to the command center, enabling firefighters to assess the situation remotely and devise appropriate firefighting strategies.
3. Application Scenario: Search and Rescue Operations
Description: The 4WD Track Firefighting Robot serves as a valuable asset in search and rescue operations during natural disasters or emergencies. Equipped with sensors and cameras, this robot can traverse hazardous terrains, such as collapsed buildings or unstable structures, to locate and rescue trapped individuals. It can transmit real-time audio and video feeds to rescue teams, aiding in decision-making and ensuring the safety of both victims and rescuers. Additionally, the robot's ability to withstand extreme temperatures and adverse conditions makes it an ideal tool for locating survivors in challenging environments.
4. Application Scenario: Industrial Hazard Response
Description: The 4WD Track Firefighting Robot finds extensive use in industrial settings where hazardous materials and potentially dangerous situations are prevalent. It can be deployed to handle incidents involving chemical spills, explosions, or other emergencies. The robot's specialized sensors and detectors enable it to identify and assess hazardous substances, ensuring the safety of human responders. With its fire suppression capabilities, the robot can also control and extinguish fires in industrial facilities, minimizing the risk of further damage and protecting valuable assets.
5. Application Scenario: Military and Defense Operations
Description: The 4WD Track Firefighting Robot plays a crucial role in military and defense operations, particularly in combat situations or during hazardous missions. This robot can be deployed to extinguish fires caused by explosions, combat situations, or accidents, reducing the risk of collateral damage. Its ability to collect real-time information about the incident area, including enemy presence or potential threats, provides valuable intelligence to military personnel. Additionally, the robot's rugged construction and advanced mobility allow it to traverse challenging terrains, making it an asset in various military operations.
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 |
Please don't hesitate to send us message!
Contact us now!!
00001. Firefighting robot
00002. Fire robot
00003. Fire rescue robot
00004. Fire suppression robot
00005. Fire response robot
00006. Fire emergency robot
00007. Fire extinguishing robot
00008. Fire safety robot
00009. Fire service robot
00010. Firefighter robot