The Boeing 737-900 is a single-aisle, twin-engine jet airliner developed by Boeing Commercial Airplanes. It is a stretched version of the Boeing 737-800, with a seating capacity of up to 220 passengers. The 737-900 has a range of up to 3,500 nautical miles (6,500 km) and is powered by two CFM International CFM56-7B engines.
The 737-900 was launched in 2005 and entered service in 2007. It is the best-selling variant of the 737 family, with over 5,000 orders placed. The 737-900 is used by a wide range of airlines around the world, including Southwest Airlines, Delta Air Lines, and United Airlines.
The 737-900 is a popular choice for airlines due to its efficiency, reliability, and low operating costs. It is also a relatively quiet aircraft, making it a good choice for use at noise-sensitive airports.
BOEING 737-900 Specs
The Boeing 737-900 is a single-aisle, twin-engine jet airliner developed by Boeing Commercial Airplanes. It is a stretched version of the Boeing 737-800, with a seating capacity of up to 220 passengers. The 737-900 has a range of up to 3,500 nautical miles (6,500 km) and is powered by two CFM International CFM56-7B engines.
- Length: 138.2 ft (42.1 m)
- Wingspan: 117.5 ft (35.8 m)
- Height: 41.1 ft (12.5 m)
- Maximum takeoff weight: 187,700 lb (85,100 kg)
- Range: 3,500 nautical miles (6,500 km)
- Engines: Two CFM International CFM56-7B turbofan engines
- Seating capacity: Up to 220 passengers
These key aspects of the Boeing 737-900’s specifications make it a popular choice for airlines around the world. Its relatively low operating costs, combined with its efficiency and reliability, make it a cost-effective option for short- and medium-haul flights. Additionally, its range of up to 3,500 nautical miles makes it capable of flying between major cities without the need for refueling stops.
Length
The length of the Boeing 737-900 is a key specification that affects various aspects of its performance and operation. A longer fuselage allows for a greater passenger capacity, more cargo space, and improved fuel efficiency. However, it also increases the aircraft’s weight and drag, which can impact its takeoff and landing performance.
- Passenger capacity: The Boeing 737-900 can accommodate up to 220 passengers in a single-class configuration. Its longer fuselage provides more space for seating, allowing airlines to increase their passenger capacity on short- and medium-haul routes.
- Cargo capacity: The 737-900 has a cargo capacity of up to 5,000 cubic feet (140 cubic meters). Its longer fuselage provides more space for cargo, making it suitable for carrying a variety of goods, including luggage, mail, and freight.
- Fuel efficiency: The 737-900’s longer fuselage helps to improve its fuel efficiency. By increasing the aircraft’s surface area, the longer fuselage reduces drag and allows the aircraft to fly more efficiently, reducing fuel consumption and operating costs.
- Takeoff and landing performance: The 737-900’s longer fuselage increases its weight and drag, which can impact its takeoff and landing performance. The aircraft requires a longer runway for takeoff and landing, and its climb rate may be slightly reduced compared to shorter variants of the 737 family.
Overall, the length of the Boeing 737-900 is a key specification that affects its passenger capacity, cargo capacity, fuel efficiency, and takeoff and landing performance. Airlines carefully consider these factors when selecting the right aircraft for their operations.
Wingspan
The wingspan of an aircraft is a key specification that affects its performance and efficiency. The wingspan of the Boeing 737-900 is 117.5 ft (35.8 m), which is wider than the wingspans of previous 737 variants. This wider wingspan provides several advantages:
- Increased lift: The wider wingspan of the 737-900 generates more lift, which is essential for takeoff and landing. This allows the aircraft to carry more weight and fly more efficiently.
- Reduced drag: The wider wingspan also helps to reduce drag, which is the resistance that an aircraft experiences when flying through the air. This reduction in drag improves the aircraft’s fuel efficiency and range.
- Improved stability: The wider wingspan provides greater stability, which is important for handling and maneuvering the aircraft. This improved stability makes the 737-900 easier to fly, especially in turbulent conditions.
The wingspan of the Boeing 737-900 is a critical component of its overall specifications. It contributes to the aircraft’s performance, efficiency, and stability, making it a safe and reliable choice for airlines around the world.
Height
The height of the Boeing 737-900, measured at 41.1 ft (12.5 m), plays a crucial role in determining various aspects of the aircraft’s performance and operation. It directly impacts factors such as ground clearance, cabin space, and aerodynamic efficiency. Understanding the significance of the height specification is essential for appreciating the overall design and capabilities of the Boeing 737-900.
- Ground Clearance: The height of the Boeing 737-900 influences its ground clearance, which is the vertical distance between the aircraft’s fuselage and the ground when it is on the ground. Adequate ground clearance is necessary for safe takeoff and landing operations, as it prevents the aircraft from scraping or damaging its undercarriage or fuselage on the runway surface. The height specification ensures that the 737-900 maintains a sufficient level of ground clearance during these critical phases of flight.
- Cabin Space: The height of the Boeing 737-900 directly affects the amount of vertical space available within the aircraft’s cabin. A taller aircraft provides more headroom and a sense of spaciousness for passengers, contributing to their comfort and overall travel experience. The 737-900’s height allows airlines to optimize the cabin layout, accommodating more passengers while maintaining a comfortable level of headroom.
- Aerodynamic Efficiency: The height of the Boeing 737-900 also influences its aerodynamic efficiency. A taller aircraft fuselage can potentially increase drag due to the larger surface area exposed to airflow. However, the 737-900’s design incorporates aerodynamic optimizations to mitigate this effect. The aircraft’s engines are mounted on pylons that are attached to the wings, raising them above the fuselage. This configuration helps reduce drag and improve the aircraft’s overall aerodynamic efficiency.
- Cargo Capacity: The height of the Boeing 737-900 indirectly impacts its cargo capacity. A taller fuselage can accommodate a larger cargo hold, allowing airlines to transport more cargo or luggage. This flexibility is particularly advantageous for airlines operating cargo or freight services, as it enables them to maximize their revenue potential.
In conclusion, the height of the Boeing 737-900, at 41.1 ft (12.5 m), is a critical specification that influences the aircraft’s ground clearance, cabin space, aerodynamic efficiency, and cargo capacity. Understanding the significance of this height parameter provides a deeper appreciation of the aircraft’s design, performance, and operational capabilities.
Maximum takeoff weight
The maximum takeoff weight (MTOW) of the Boeing 737-900, at 187,700 lb (85,100 kg), is a crucial specification that directly influences various aspects of the aircraft’s performance and operation. It represents the maximum allowable weight at which the aircraft can safely take off, considering factors such as structural integrity, engine thrust, and aerodynamic limitations.
The MTOW of the 737-900 is determined through rigorous engineering analysis and flight testing. It is a critical parameter that affects the aircraft’s payload capacity, range, and overall efficiency. A higher MTOW allows the aircraft to carry more passengers, cargo, or fuel, increasing its revenue-generating potential.
Understanding the significance of MTOW is essential for airlines and pilots to ensure safe and efficient operation of the Boeing 737-900. It influences decisions related to:
- Payload capacity: The MTOW determines the maximum weight of passengers, cargo, and baggage that the aircraft can carry while adhering to safety regulations and maintaining optimal performance.
- Range and fuel efficiency: A higher MTOW typically reduces the aircraft’s range and fuel efficiency due to the increased weight. Airlines must carefully consider the trade-off between payload capacity and range when determining the optimal MTOW for a specific route or operation.
- Takeoff performance: The MTOW directly affects the aircraft’s takeoff performance. A higher MTOW requires a longer takeoff distance and higher takeoff speed to achieve the necessary lift for safe takeoff.
- Structural integrity: The aircraft’s structure, including the wings, landing gear, and fuselage, must be designed to withstand the loads and stresses experienced during takeoff, which are influenced by the MTOW.
In conclusion, the maximum takeoff weight of 187,700 lb (85,100 kg) is a fundamental specification for the Boeing 737-900. It establishes the operational limits of the aircraft, influencing its payload capacity, range, takeoff performance, and structural integrity. Understanding and adhering to the MTOW is critical for safe and efficient operation of the 737-900, ensuring optimal performance and maximizing its revenue-generating potential while prioritizing safety.
Range
The range of an aircraft is a crucial specification that determines the distance it can travel without requiring refueling. The Boeing 737-900 has a range of 3,500 nautical miles (6,500 km), which is a significant factor in its popularity among airlines and passengers.
The range of the 737-900 is enabled by several factors, including its fuel capacity, aerodynamic efficiency, and engine performance. The aircraft’s large fuel tanks allow it to carry a substantial amount of fuel, providing the necessary endurance for long-haul flights. Additionally, the 737-900’s advanced wing design and efficient engines contribute to its low fuel consumption, extending its range even further.
The range of 3,500 nautical miles makes the 737-900 a versatile aircraft capable of operating on a wide range of routes. It can connect cities that are relatively far apart, such as transcontinental flights within the United States or long-haul flights across Europe. This range capability allows airlines to offer direct flights between major cities, reducing travel time and providing more convenient options for passengers.
Furthermore, the 737-900’s range is crucial for airlines in terms of operational efficiency. By reducing the need for refueling stops, airlines can save time and fuel costs, leading to increased profitability. The aircraft’s range also provides flexibility in scheduling and route planning, allowing airlines to adjust their operations based on demand and market conditions.
In summary, the range of 3,500 nautical miles (6,500 km) is a key specification of the Boeing 737-900 that directly impacts its operational capabilities and commercial success. It enables the aircraft to connect distant cities, providing convenient and efficient travel options for passengers while offering airlines flexibility and cost savings.
Engines
The engines are a crucial component of any aircraft, and the Boeing 737-900 is no exception. The two CFM International CFM56-7B turbofan engines that power the 737-900 are known for their reliability, efficiency, and power, all of which contribute to the aircraft’s overall performance and capabilities.
- Fuel efficiency: The CFM56-7B engines are designed to be fuel-efficient, which is a key factor in reducing operating costs for airlines. The engines feature advanced technology that optimizes airflow and combustion, resulting in lower fuel consumption.
- Power and performance: The CFM56-7B engines provide excellent power and performance, enabling the 737-900 to take off and climb efficiently. The engines are also designed to provide reliable operation in a variety of conditions, including extreme temperatures and high altitudes.
- Reliability and durability: The CFM56-7B engines are known for their reliability and durability, which is essential for commercial aircraft. The engines undergo rigorous testing and maintenance programs to ensure they meet the highest safety and performance standards.
- Reduced emissions: The CFM56-7B engines are designed to meet strict environmental regulations, producing lower emissions than previous engine models. This helps to reduce the aircraft’s environmental impact and contributes to a more sustainable aviation industry.
Overall, the two CFM International CFM56-7B turbofan engines are a key component of the Boeing 737-900’s specifications. Their efficiency, power, reliability, and reduced emissions contribute to the aircraft’s overall performance, economics, and environmental friendliness.
Seating capacity
The seating capacity of the Boeing 737-900, with its maximum of 220 passengers, is a significant aspect of its specifications, directly influencing the aircraft’s operational capabilities and commercial viability.
- Passenger comfort and experience: The seating capacity directly affects passenger comfort and the overall travel experience. A higher seating capacity may imply a denser cabin layout, potentially reducing legroom and overall comfort for passengers. Airlines must carefully consider the trade-off between seating capacity and passenger comfort when configuring their aircraft.
- Operational efficiency: The seating capacity influences the aircraft’s operational efficiency. A higher seating capacity allows airlines to carry more passengers on each flight, potentially increasing revenue and optimizing aircraft utilization. However, it also affects factors such as boarding and deplaning times, which can impact the aircraft’s turnaround time.
- Market demand and route planning: The seating capacity plays a crucial role in market demand and route planning. Airlines analyze passenger traffic patterns and demand forecasts to determine the optimal seating capacity for specific routes. A higher seating capacity may be suitable for high-traffic routes, while a lower seating capacity may be more appropriate for routes with lower passenger demand.
- Aircraft configuration and cabin layout: The seating capacity of the 737-900 is closely linked to its aircraft configuration and cabin layout. Airlines can choose from various seating configurations, including all-economy, business-economy, and first-class-business-economy layouts. The specific configuration selected will depend on the target market, route characteristics, and the airline’s branding and service strategy.
In summary, the seating capacity of up to 220 passengers is a key specification of the Boeing 737-900 that influences passenger comfort, operational efficiency, market demand, and aircraft configuration. Airlines carefully consider these factors when selecting and operating the 737-900 to optimize their revenue and provide a comfortable and efficient travel experience for their passengers.
FAQs on Boeing 737-900 Specs
This section addresses frequently asked questions regarding the specifications and capabilities of the Boeing 737-900 aircraft.
Question 1: What is the maximum range of the Boeing 737-900?
The Boeing 737-900 has a maximum range of 3,500 nautical miles (6,500 kilometers), allowing it to operate on a wide range of short- to medium-haul routes.
Question 2: How many passengers can the Boeing 737-900 accommodate?
The Boeing 737-900 has a maximum seating capacity of up to 220 passengers in a single-class configuration. Airlines can choose from various seating configurations to optimize passenger comfort and revenue.
Question 3: What type of engines power the Boeing 737-900?
The Boeing 737-900 is powered by two CFM International CFM56-7B turbofan engines. These engines provide excellent fuel efficiency, reliability, and performance.
Question 4: What is the wingspan of the Boeing 737-900?
The Boeing 737-900 has a wingspan of 117.5 feet (35.8 meters), contributing to its aerodynamic efficiency and stability.
Question 5: What is the maximum takeoff weight of the Boeing 737-900?
The Boeing 737-900 has a maximum takeoff weight of 187,700 pounds (85,100 kilograms), determining its payload capacity and takeoff performance.
Question 6: What are the key advantages of the Boeing 737-900?
The Boeing 737-900 offers several advantages, including its fuel efficiency, reliability, range, and passenger capacity. These factors contribute to its popularity among airlines and passengers alike.
This concludes our FAQs on the Boeing 737-900 specifications. For further information, please refer to the aircraft’s technical specifications or consult with aviation experts.
Now, let’s explore the exceptional performance and capabilities of the Boeing 737-900 in more detail.
Tips on Utilizing “BOEING 737-900 Specs”
To effectively utilize the specifications of the Boeing 737-900, consider these valuable tips:
Tip 1: Understand the Significance of Range: The 737-900’s range of 3,500 nautical miles enables efficient operations on short- to medium-haul routes. Analyze flight distances and passenger demand to optimize aircraft utilization.
Tip 2: Maximize Seating Capacity: With a maximum capacity of 220 passengers, the 737-900 offers flexibility in seating configurations. Determine the optimal layout based on market demand, passenger comfort, and revenue targets.
Tip 3: Leverage Fuel Efficiency: The CFM56-7B engines provide exceptional fuel efficiency. Utilize advanced flight planning techniques and optimize payload to minimize operating costs and enhance profitability.
Tip 4: Consider Wingspan Impact: The 737-900’s wingspan of 117.5 feet contributes to stability and aerodynamic efficiency. Understand how wingspan affects takeoff and landing performance.
Tip 5: Optimize Takeoff Weight: The maximum takeoff weight of 187,700 pounds influences payload capacity. Calculate weight distribution and fuel requirements carefully to ensure safe and efficient departures.
Summary: By leveraging these tips, aviation professionals can harness the full potential of the Boeing 737-900’s specifications to enhance operational efficiency, maximize passenger comfort, and optimize revenue generation.
These insights will guide you towards a comprehensive understanding and effective utilization of the Boeing 737-900’s capabilities.
Conclusion
The Boeing 737-900 stands as a testament to engineering excellence, offering exceptional performance, efficiency, and versatility within the single-aisle aircraft category. Its specifications contribute to its widespread adoption by airlines globally, catering to the demands of short- to medium-haul air travel.
From its impressive range and seating capacity to its fuel-efficient engines and aerodynamic design, the 737-900 embodies a harmonious blend of capabilities. Understanding and effectively utilizing these specifications empower aviation professionals to optimize operations, enhance passenger experience, and maximize revenue potential.
As the aviation industry continues to evolve, the Boeing 737-900 remains a cornerstone of commercial fleets, providing a reliable and efficient means of connecting people and destinations worldwide.