For more information, please visit the product page. date 08/15/2016 page 1 of 5 SERIES: CFM-92 │ DESCRIPTION: DC AXIAL FAN FEATURES • • • • 92 x 92 mm frame high fan speed for greater air flow two ball bearing construction auto restart protection standard on all models MODEL input voltage input current input power rated speed airflow1 static pressure2 noise rated (Vdc) range (Vdc) typ (A) max (A) max (W) typ (RPM) (CFM) (mm H2O) max (dBA) CFM-9225-13 12 6~13.8 0.40 0.5 6 4,200 96.06 9.38 49.8 CFM-9225-23 24 16~26.4 0.24 0.32 6.72 4,200 96.06 9.38 49.8 Notes: 1. At 0 mm H20 static pressure. 2. At 0 CFM airflow. PART NUMBER KEY CFM-9225 - X 3 - XX - CXX Base Number Input Voltage 1 = 12 Vdc 2 = 24 Vdc cui.com Reserved for Custom Configurations Fan Protection 10 = auto restart protection 11 = auto restart protection / rotation detector 20 = auto restart protection / tachometer signal 22 = auto restart protection / tachometer signal / PWM control signal For more information, please visit the product page. CUI Inc │ SERIES: CFM-92 │ DESCRIPTION: DC AXIAL FAN date 08/15/2016 │ page 2 of 5 INPUT parameter conditions/description operating input voltage 12 Vdc input models 24 Vdc input models min typ max units 6 16 12 24 13.8 26.4 Vdc Vdc current 12 Vdc input models 24 Vdc input models 0.40 0.24 0.5 0.32 A A power 12 Vdc input models 24 Vdc input models 4.80 5.76 6 6.72 W W starting voltage at 25°C 12 Vdc input models 24 Vdc input models 6 16 Vdc Vdc PERFORMANCE parameter conditions/description min typ max units rated speed at 25°C, after 10 minutes 3,780 4,200 4,620 RPM air flow at 0 mm H2O, see performance curves static pressure at 0 CFM, see performance curves 9.38 noise at 1 m 48.5 49.8 dBA min typ max units min typ max units 96.06 CFM mm H2O PROTECTIONS / SIGNALS1 parameter conditions/description auto restart protection available on all models rotation detector available on “11” models tachometer signal available on “20” and “22” models PWM control signal available on “22” models Notes: 1. See application notes for details. SAFETY & COMPLIANCE parameter conditions/description insulation resistance of frame at 500 Vdc between frame and positive terminal dielectric strength at 500 Vac, 60 Hz, 1 minute between frame and positive terminal safety approvals UL/cUL 507, TUV (EN 60950-1) EMI/EMC EN 55022:2010+AC:2011 Class B, EN 61000-32:2014, EN 61000-3-3:2013, EN 55024:2010 life expectancy at 45°C, 15~65% RH RoHS 2011/65/EU 10 MΩ 5 70,000 mA hours ENVIRONMENTAL parameter max units operating temperature conditions/description min -10 typ 70 °C storage temperature -40 70 °C operating humidity non-condensing 5 90 % storage humidity non-condensing 5 95 % cui.com For more information, please visit the product page. CUI Inc │ SERIES: CFM-92 │ DESCRIPTION: DC AXIAL FAN date 08/15/2016 │ page 3 of 5 0.39 (mm H2O) (Inch H2O) PERFORMANCE CURVES 10.00 9.00 0.32 8.00 7.00 0.24 6.00 5.00 0.16 4.00 3.00 0.08 2.00 1.00 0.00 0.00 0.00 20.00 40.00 60.00 80.00 100.00 120.00 (CFM) (CMM) 0.00 0.68 1.36 2.04 2.72 3.40 MECHANICAL parameter conditions/description min motor 4 pole DC brushless bearing system ball bearing direction of rotation counter-clockwise viewed from front of fan blade dimensions 92 x 92 x 25.4 material PBT (UL94V-0) weight 12 Vdc input models 24 Vdc input models 96.3 97.0 units: mm [inch] wire: UL 1007, 24 AWG WIRE CONNECTIONS Function Red +Vin Black -Vin Yellow FG Signal White RD Signal Blue PWM max units mm MECHANICAL DRAWING Wire Color typ ōŢţŦŭ cui.com g g For more information, please visit the product page. CUI Inc │ SERIES: CFM-92 │ DESCRIPTION: DC AXIAL FAN date 08/15/2016 │ page 4 of 5 APPLICATION NOTES Auto Restart Protection/Current Limit Protection When the fan motor is locked, the device will cut off the drive current within two to six seconds and restart automatically after a few seconds. If the lock situation is continued, the device will work on a repeated cycle of cut-off and restart until the lock is released. (See Figure 1 below). Figure 1 Current Limit Protection Lock Sensor/Rotation Detector Lock Sensor is used to detect if the fan motor is operating or stopped. Alarm High: the output will be logical low when fan is operating and be logical high when fan motor is locked. (See Figures 2~3 below). Figure 3 RD Signal Output Circuit: Open Collector Figure 2 Alarm High Output Waveform Ic=5mA max Pulse Sensor/Tachometer Signal/FG Pulse Sensor is for detecting the rotational speed of the fan motor. At locked rotor condition, the signal stops cycling and the output is fixed at VoH or VoL (See Figures 4~5 below). Figure 4 Output Waveform Figure 5 FG Signal Output Circuit: Open Collector Ic=10mA max PMW Control Signal A speed control lead can be provided that will accept a PWM signal from the customer circuit to vary the speed of the fan. The change in speed is linear by changing the Duty-Cycle of the PWM. Open collector type and pull-up voltage is changed by maximum operating voltage and sink current by consuming current. (See Figure 6 below). Figure 6 Duty Cycle Vs=4~5 V cui.com For more information, please visit the product page. CUI Inc │ SERIES: CFM-92 │ DESCRIPTION: DC AXIAL FAN date 08/15/2016 │ page 5 of 5 REVISION HISTORY rev. 1.0 description date initial release 08/15/2016 The revision history provided is for informational purposes only and is believed to be accurate. Headquarters 20050 SW 112th Ave. Tualatin, OR 97062 800.275.4899 Fax 503.612.2383 cui.com [email protected] CUI offers a one (1) year limited warranty. Complete warranty information is listed on our website. CUI reserves the right to make changes to the product at any time without notice. Information provided by CUI is believed to be accurate and reliable. However, no responsibility is assumed by CUI for its use, nor for any infringements of patents or other rights of third parties which may result from its use. CUI products are not authorized or warranted for use as critical components in equipment that requires an extremely high level of reliability. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness.