DC axial compact fan-3414 NHH
Technical Description
Weight |
0.100 kg |
Dimensions |
92 x 92 x 25 mm |
Impeller material |
Glass-fiber reinforced PA plastic |
Housing material |
Glass-fiber reinforced PBT plastic |
Airflow direction |
Exhaust over struts |
Direction of rotation |
Counterclockwise, viewed toward rotor |
Bearing |
Ball bearing |
Service life L10 at 40 °C |
70000 h |
Service life L10 at maximum temperature |
35000 h |
Cable |
Leads AWG 24, TR 64, stripped and tin-plated. |
Motor protection |
Protection against reverse polarity and blocked rotor. |
Approval |
VDE, CSA, UL |
Option |
Alarm signal |
Nominal data
Type of voltage |
|
DC |
Nominal voltage |
in V |
24 |
Nominal voltage range |
in V |
18 .. 26 |
Speed |
in min-1 |
3250 |
Power input |
in W |
3,1 |
Min. ambient temperature |
in °C |
-20 |
Max. ambient temperature |
in °C |
70 |
Air flow |
in m³/h |
102 |
Sound power level |
in B |
5,1 |
Sound pressure level |
in dB(A) |
39 |
Introducing
Introducing the DC Axial Compact Fan 3414 NHH, a high-performance cooling solution for a variety of industrial and commercial applications. With its innovative design and superior functionality, this fan is designed to provide reliable, efficient cooling of electronic components, machinery, and other heat-sensitive equipment.
The DC axial flow compact fan 3414 NHH is equipped with a powerful motor and optimized blade design, allowing it to deliver high air volume and static pressure while maintaining low noise levels. This makes it ideal for applications where cooling performance and noise reduction are critical. Whether used to cool servers in a data center, optimize airflow in HVAC systems, or maintain optimal operating temperatures in industrial machinery, this fan can meet different cooling requirements.
One of the main features of the DC Axial Compact Fan 3414 NHH is its compact and lightweight design, making it easy to integrate into tight spaces and installations where space in cooling equipment is limited. This fan also features rugged construction and durable materials to ensure long-term reliability and performance in harsh environments.
Additionally, the DC Axial Compact Fan 3414 NHH is equipped with advanced monitoring and control features that allow users to adjust fan speed and performance to meet specific cooling requirements. This level of flexibility and customization ensures the fan can adapt to different thermal conditions and provide optimal cooling performance as needed.
Focusing on energy efficiency and sustainability, the DC Axial Compact Fan 3414 NHH is designed to minimize power consumption while maximizing cooling efficiency. This not only helps reduce operating costs, but also promotes environmental protection by reducing energy consumption and greenhouse gas emissions.
Overall, the DC Axial Compact Fan 3414 NHH provides a reliable, high-performance cooling solution for a variety of applications. Its advanced features, compact design and energy-efficient operation make it a valuable asset for industries looking to optimize cooling performance and preserve equipment longevity.
What’s the maximum voltage you can apply to a blower?
The maximum voltage that can be applied to a fan motor varies from model to model, but is typically 5%-10% above the nominal voltage listed. Consult the factory to determine the maximum voltage for a particular part number, and to learn more about the negative effects that high voltages might have on the motor
What is a fan’s of voltage range?
Ebmpapst EC fans are able to perform equally well across a range of input voltages. These fans will have the maximum and minimum acceptable voltages listed on the label, such as the one below:
Note that in order to reach a desired performance point, the fan may need to draw additional current at low voltages.
Can all 60 Hz blower motors operate on a frequency of 50 Hz?
Not all ebmpapst fans are designed to operate at both 50 and 60 Hz. If a fan is able to accept both 50 Hz and 60 Hz power supplies, it will have a “50/60Hz” mark on its label, such as the one below:
Consult the factory if you intend to use a power supply with a frequency that does not match the recommended frequency of your fan.
When determining fan performance, several factors are taken into consideration. These factors primarily include: airflow, static pressure, operating points, RPM, power & current, and sound performance. Of these factors, ebmpapst presents a performance curve with our products to provide a quick-glance overview of the performance. Performance curves use just three of the aforementioned factors: airflow, static pressure, and operating points.
What is Airflow?
For the air-moving industry, it is important to know how quickly some volume of air is being displaced from one location to another, or, more simply stated, how much air is being moved in a set amount of time.
Ebmpapst typically expresses airflow in Cubic Feet per Minute (CFM) or cubic meters per hour (m3/h).
What is Static Pressure?
Once again the air-moving industry is faced with another challenge, the resistance to flow. Static pressure, sometimes referred to as back pressure or system resistance, is a continuous force on the air (or gas) due to the resistance to flow. These resistances to flow can come from sources such as static air, turbulence and impedances within the system like filters or grills. A higher static pressure will cause a lower airflow, in the same way that a smaller pipe reduces the amount of water that can flow through it.
Ebmpapst typically expresses static pressure in inches water gauge (in. W.G.) or Pascals (Pa).
What is the System Operating Point?
For any fan we can determine how much air it is able to move in a given amount of time (airflow) and how much static pressure it can overcome. For any given system, we can determine the amount of static pressure it will create at any given airflow.
Taking these known values for airflow and static pressure, we can plot them on a two-dimensional chart. The operating point is the point at which the fan performance curve and the system resistance curve intersect. In real terms, it is the amount of airflow a given fan can move through a given system.
How do I read an air performance curve?
To aid in fan selection, ebmpapst provides an air performance graph with its products. The air performance graph consists of a series of curves that chart airflow against static pressure.
Follow along on the chart below. The x-axis is for airflow, while the y-axis is for static pressure. The blue line ‘A’ illustrates the fan’s performance outside of a system. To find the operating point 900CFM @ 2 in.w.g., follow the x-axis to 900, then follow the y-axis up to 2 (Point ‘B’). Since this operating point ‘B’ is below the performance curve, it is a point that the fan can achieve.
Lines ‘C’, ‘D’, and ‘E’ are example system resistance curves – as airflow increases, the static pressure (or resistance to airflow) also increases, making it harder to move air. Typically, any point between the highest and lowest of our example resistance curves is the ideal operating range for the fan to achieve its highest efficiency. Some performance graphs will have multiple airflow curves; this would indicate that the fan is capable of multiple speeds in order to match operating points below its maximum speed, thus saving energy.
Forward Curved Impellers
- There are two types of forward curved impellers, dual and single inlet.
- Used primarily in medium pressure, high flow applications.
- Possible market uses: ventilation, refrigeration etc.
Backward Curved Impellers
- Used primarily in high pressure, high flow applications.
- Possible market uses: data center, general ventilation, agriculture; transportation etc.
Axial Fans
- Used primarily in low pressure, high flow applications.
- Possible market uses: LED, ventilation, agriculture; transportation, etc.