Why Should We Use A Data Center Rack Load Bank?


Businesses in today’s modern economy rely heavily on high-density data centers because they provide the efficiency and cost savings essential to survival in today’s business climate. Server racks in a data center provider for the safe and effective consolidation of various types of network hardware. However, many different kinds of data center rack load bank are available; how do you pick the right one?

What is a data center rack load bank?

Resistive Load banks are testing equipment used to commission, maintain, and replicate a typical electrical load/source to evaluate an electrical power source such as a generator, UPS, or battery system. This way, the load bank may simulate and be verified against the real load before it is connected to the power source.

Why should we use a data center rack load bank?

One of the most widespread applications for load banks is testing in data centers. As a result of the complexity of our electrical systems and the necessity of steady and reliable electricity, the data center rack load bank plays a crucial role. Most up-to- data center rack load bank for startup, maintenance, expansion, and component replacement.

Commissioning: Any problematic electrical components or systems will be exposed during load testing during the commissioning phase, allowing for them to be repaired or replaced before going “live.” As many data centers anticipate growth, the real-world load is not always accessible at the early stages of construction. To ensure the quality of the components, load banks are the only realistic approach to simulate real-world load.

Expansion: Data centers are typically larger than necessary to allow for future growth. The expansion calls for accurate simulation of power consumption and cooling adaptability. New technology and components must demonstrate their functionality and efficiency in settings where private or vital data may be held.

Maintenance: In the event of a power outage, most data centers feature diesel generators and uninterruptible power supply units (UPS). Consistent upkeep is essential for minimizing data center downtime, costing upwards of $7,900 per minute in the United States alone. Regarding stress testing and maintenance testing of electrical systems, load banks are far and away the best option.

Substitute Parts: The components of a circuit can be tested and verified with great efficiency using load testing. As parts get older and near the end of their lifespan, the likelihood of failure increases. When testing components under realistic settings, load banks are invaluable. Load testing results determine which parts need to be replaced.

Programmable AC loads

Compared to a resistive load bank, which normally only runs at power factor unity, a programmable AC load offers superior accuracy.

Our devices let you set up complicated load stages and fine-tune sink values in the milliamp range over various input voltages, waveforms, and power factors. Crest factor mode allows for peak current modeling. Some models allow you to set the power factor as either leading or lagging from 1 to 0.

All models in the series have a non-volatile memory accessible from the front panel, wherein the auto-sequencing function and a waveform library are kept. In constant current mode, you can select between sine, square, and DC waveforms and boost signals from an external waveform generator.

An isolated current monitor is included in all of our programmable ac load at Junxy Power Solutions, making it simple to hook up an oscilloscope and observe the load current. If the remote operation is necessary, we provide several interface options, including GPIB, RS-232, USB, and LAN. To reach 180kW, up to 8 ELPA-SINE systems can be set up simultaneously with master-slave functionality. Three-phase equipment testing can be done with either a delta or wye connection. Systems can be combined or divided into multiple parts depending on the situation, as each component functions autonomously. A turbo option for inrush current testing allows for twice the maximum current sink for up to 1 second.