Greenheck Fan dimensions Pressure Drop Data SMD-301V, Amca Test Figures

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Pressure Drop Data

SMD-301V

This pressure drop testing was conducted in accordance with AMCA Standard 500-D using the three configurations shown. All data has been corrected to represent standard air at a density of .075 lb/ft3(1.2 kg/m3).

Actual pressure drop found in any HVAC system is a combination of many factors. This pressure drop information along with an analysis of other system influences should be used to estimate actual pressure losses for a damper installed in a given HVAC system.

AMCA Test Figures

Figure 5.3 Illustrates a fully ducted damper. This configuration has the lowest pressure drop of the three test configurations because entrance and exit losses are minimized by straight duct runs upstream and downstream of the damper.

Figure 5.2 Illustrates a ducted damper exhausting air into an open area. This configuration has a lower pressure drop than Figure 5.5 because entrance losses are minimized by a straight duct run upstream of the damper.

Figure 5.5 Illustrates a plenum mounted damper. This configuration has the highest pressure drop because of extremely high entrance and exit losses due to the sudden changes of area in the system.

5D

6D

Figure 5.3

5D

D

4 (W) (H)

 

3.14

Figure 5.2

Figure 5.5

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Contents Standard Construction Optional FeaturesApplication Size LimitationsPressure Drop Data SMD-301V Amca Test FiguresIn. wg Amca 5.2 Pressure Drop SMD-301VPressure Drop Amca 5.3 Pressure Drop SMD-301V Amca 5.5 Pressure Drop SMD-301V Fpm In. wgTransitioned Damper Dimensions Specifications

SMD-301V specifications

The Greenheck Fan SMD-301V is a high-performance, energy-efficient fan that is widely recognized in the HVAC industry for its innovative design and advanced features. This model, part of the SMD series, is engineered to deliver superior airflow while ensuring low energy consumption, making it an ideal choice for various applications such as commercial buildings, industrial facilities, and institutional environments.

One of the main features of the SMD-301V is its direct drive motor design. This configuration eliminates the need for belts and pulleys, reducing maintenance requirements and enhancing reliability. The motor is also specifically designed for high efficiency, which helps to lower operating costs. With this direct drive attribute, Greenheck ensures quieter operation and a more compact physical footprint, which is often necessary in tight installation spaces.

The SMD-301V is equipped with a backward-inclined impeller, a design that enhances performance by optimizing airflow and minimizing noise levels. This impeller type is known for its ability to maintain efficiency under varying airflow conditions, making it suitable for both constant and variable air volume applications. The fan is capable of providing a stable airflow even in challenging environments, which is a significant advantage when dealing with fluctuating demand.

Another significant characteristic of the SMD-301V is its robust construction. Built from high-quality materials, including corrosion-resistant coatings, it is designed to withstand harsh environmental conditions and ensure long life. Additionally, the fan features an integrated control system, allowing for precise adjustments and enhanced performance monitoring. This integration offers users the opportunity to optimize their systems for maximum efficiency and ease of operation.

The SMD-301V meets rigorous industry standards for performance and safety, making it a reliable choice for various applications. Its compliance with Energy Star guidelines aligns with sustainability initiatives, further highlighting its appeal to environmentally conscious organizations.

In summary, the Greenheck Fan SMD-301V stands out due to its advanced engineering, energy-efficient operation, and user-friendly features. Its combination of a direct drive motor, backward-inclined impeller design, and robust construction make it a top choice for anyone seeking reliable ventilation solutions. The integration of modern control technologies ensures optimal performance, making it an essential component for efficient HVAC systems.