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Choosing the Right Centrifugal Fan

Choosing the Right Centrifugal Fan

Centrifugal blowers or fans, are among the most efficient and versatile pieces of air moving equipment. The scroll housing in a centrifugal fan accelerates the air and changes the direction of the airflow twice, a full 90°, before leaving the housing. Centrifugal blowers are quiet and reliable and are made to operate in a variety of environments and applications. Here are some basic definitions and guidelines to consider for selecting the right centrifugal blower for your system’s needs.

 

Centrifugal Fan Blade Types

Centrifugal fans come in four basic fan types, each with its own specific purpose.

  • Radial These are high-pressure fans with medium airflow. Radial-bladed fans are best for industrial applications where there is dust, or in environments where there is gas or moisture in the air.
  • Forward Curve These are medium pressure, high airflow fans that can be used in both clean air, ventilating and exhaust applications.
  • Backward Curve These are high-pressure, high flow, high efficiency fans. Power reduces as flow increases over the most efficient area of the system.
  • Airfoil These are the highest efficiency fans, best in clean air applications.

Velocity Requirements

To choose the appropriate blower, you’ll need to know how much pressure is required to reach the desired airflow to move air through the ducting and any filters, dampers or other obstructions in your ventilation system. If you have a lengthy, complicated duct system, you’ll of course need a lot more power. Consider the impact of filters on the airflow too as this will also impact the pressure and power needed.

  • Direct Drive is more typical on smaller blowers and generally offers lower cost, fewer components to assemble, greater efficiency (no drive losses), reduced maintenance (no separate bearings or belts) and greater reliability.
  • Belt Drive offers greater flexibility in matching airflow requirements when equipped with a variable pitch motor pulley and is typical of larger blowers.

When equipped with a variable frequency drive (three-phase blowers), direct drive blowers can offer the flexibility of belt drive blowers.

PRESSURE (U.S. SYSTEM)
psi "WG "Hg
1 27.736 2.036
0.03605 1 0.07341
0.49116 13.623 1
0.000145 0.00403 0.000295
0.00142 0.03937 0.00289
0.01934 0.53632 0.03937
14.696 407.61 29.92

 

PRESSURE (METRIC)
N/m2* mmWG mmHg atm
6894.7 704.49 51.714 0.06805
248.36 25.4 1.8628 0.00245
3386.4 346.02 25.4 0.03342
1 0.10219 0.0075 0.0000098
9.7863 1 0.07341 0.00009661
133.32 13.623 1 0.001316
101325 10353 760 1

 

VOLUME FLOW
U.S. SYSTEM METRIC
cfm m3/sec m3/min m3/hr
1 0.000472 0.02832 1.699
2118.9 1 60 3600
35.314 0.01667 1 60
0.58858 0.0002887 0.01667 1

 

VELOCITY POWER TEMPERATURE
U.S. SYSTEM METRIC U.S. SYSTEM METRIC  
fpm m/sec hp W kW  
1 0.00508 1 745.70 .7457  
196.85 1 0.00134 1 0.001 °F = (9/5°C +32°)
°C = 5/9 (°F -32°)
    1.341 1000 1
 
SYMBOL DEFINITION
atm atmospheres
°C degrees Celsius
cfm cubic feet per minute
°F degrees Fahrenheit
fpm feet per minute
Hg mercury
hp horsepower
hr hours
kW kilowatts
SYMBOL DEFINITION
m meters
mm millimeters
min minutes
N newtons
psi pounds per square inch
sec seconds
W watts
WG water gauge
   
 

Environment

The environment in which the system operates must also be considered to choose the right blower-motor combination.

  • Outdoors Consider a Totally Enclosed Fan Cooled (TEFC) electric motor on direct drive units, or a belt drive unit with an included weather cover.
  • Dirty or Dusty Environment A TEFC motor is best for longer life and optimal efficiency.
  • Corrosive Environment In wet, humid environments, a stainless steel blower is recommended, preferably with a stainless wash-duty motor.
  • Hazardous Environment Consider a non-sparking blower, such as a radial or high-pressure blower, with an explosion-proof motor.

Air Quality

Clean Air Consider a forward curve, backward incline or airfoil blower for increased efficiency.

Lightly Dusty Air Consider a radial or high-pressure blower. For very light, non-abrasive dusts, a backward inclined blower is acceptable.

Heavier, More Abrasive Dust, Filings and Shavings For this environment, you’ll probably want an industrial material handing blower.

Corrosive In wet, humid, corrosive environments, you should opt for a stainless steel blower, preferably with a stainless wash-duty motor.

Combustible If there’s combustible dust or particulate in the air, opt for a non-sparking blower, such as a radial or high-pressure blower with an explosion-proof motor.

Air Temperatures Use belt drive units with steel wheels in higher temperatures. If temperatures climb above 250°F, consider an industrial blower with a heat slinger.

DESIGNATION FOR ROTATION AND DIRECTION OF DISCHARGE

The direction of the rotation is determined from the drive side of the fan. On single inlet fans, the drive side is the side opposite the fan inlet. On double inlet fans with drives on both sides, the drive side should be on the same side as the higher-powered drive unit.

Clockwise Up Blast CW 360 Clockwise Top Angular Up CW 45 Clockwise Top Horizontal CW 90 Clockwise Top Angular Down CW 135
Clockwise Down Blast CW 180 Clockwise Bottom Angular Down CW 225 Clockwise Bottom Horizontal CW 270 Clockwise Bottom Angular Up CW 315
Counterclockwise Up Blast CCW 360 Counterclockwise Top Angular Up CCW 45 Counterclockwise Top Horizontal CCW 90 Counterclockwise Top Angular Down CCW 135
Counterclockwise Down Blast CCW 180 Counterclockwise Bottom Angular Down CCW 225 Counterclockwise Bottom Horizontal CCW 270 Counterclockwise Bottom Angular Up CCW 315
 

Notes:

  1. Direction of rotation and angular reference is determined from the drive side as defined below:
    • On single inlet fans: The drive side is that side opposite the fan inlet.
    • On double inlet fans:
      • With a single driver: That side with the drive is considered the drive side.
      • With multiple drivers: That side with the higher total power is considered the drive side. If the total power on each side is equal, then the side that has the fixed (non-expansion) bearing is considered the drive side.
  2. Direction of discharge is determined in accordance with diagrams. Angle of discharge is referred to the top vertical axis of fan and designated in degrees as measured in the direction of fan rotation. Angle of discharge may be any intermediate angle as required.
  3. A fan inverted for ceiling suspension or rotated for side wall mounting will have its direction of rotation and angle of discharge determined when fan is located as if floor mounted.
  4. This standard is in harmony with ISO 13349. In ISO 13349, CCW fans are referred to as LG, i.e., Left or Gauche, while CW fans are referred to as RD, i.e, Right or Droit-handed rotation.
 

BLOWER ARRANGEMENT

Drive arrangements for Centrifugal Fans AMCA Standard 99-2404-03

SW = Single Width DW = Double Width
SI = Single Inlet DI = Double Inlet

Please note: Arrangements 1, 3, 7, and 8 are also available with bearings mounted on pedestals or base set independent of the fan housing.

APR. 1 SWSI - For belt drive or direct connection. Impeller overhung. Two bearings on base. ARR. 2 SWSI - For belt drive or direct connection. Impeller overhung. Bearings in bracket supported by fan housing.
ARR. 3 SWSI - For belt drive or direct connection. One bearing on each side and supported by fan housing. ARR. 3 DWDI - For belt drive or direct connection. One bearing on each side and supported by fan housing.
ARR. 4 SWSI - For direct drive. Impeller overhung on prime mover base mounted or integrally directly connected. ARR. 7 SWSI - For belt drive or direct connection. Arrangement 3 plus base for prime mover.
ARR. 7 DWDI - For belt drive or direct connection. Arrangement 3 plus base for prime mover. APR. 8 SWSI - For belt drive or direct connection. Arrangement 1 plus extended base for prime mover.
APR. 9 SWSI - For belt drive. Impeller overhung, two bearings, with prime mover outside base. ARR. 10 SWSI - For belt drive. Impeller overhung, two bearings, with prime mover inside base.
 

MOTOR POSITION

The location of the motor is determined by facing the drive side of the fan and designating the motor positions by the letters W, X, Y or Z as needed.

Motor Position

Facility maintenance pros like you have many jobs to do in the course of the day. So if HVAC isn’t your primary field of expertise, we hope these basics provide some of the guidelines you need when it comes time to seek the advice from a trusted HVAC engineer. Choosing the right combination of blowers and motors for the intended workload and environment is critical in making your system the most efficient it can be while helping to keep energy costs down.

The product statements contained herein are intended for informational purposes only. Such product statements do not constitute a product recommendation or representation as to the appropriat ness for a specific application or use. W. W. Grainger, Inc. does not guarantee the result of product operation or assume any liability for personal injury or property damage resulting from the use of such products.