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ETS (TerraSAS) Series

 Product Overview

For microgrids, energy storage, and inverter test applications, the TerraSAS™ series photovoltaic (PV) simulators are specifically designed to emulate the dynamic electrical behavior of a terrestrial PV solar array. They offer low output capacitance and high closed loop bandwidth to keep up with the advanced Maximum Power Point Tracking (MPPT) algorithms used in today’s grid-tied inverters.

The ETS Embedded TerraSAS is a high performance solution in a small form factor that combines an agile power supply with an innovative I-V curve generator in a single standalone unit.

• ETS 600 / 1000: For isolated and non-isolated string inverters up to 1000Vdc Voc.
• ETS 60 / 80 / 150: For use with micro-inverters or DC optimizers up to 150Vdc Voc

The ETS series standalone TerraSAS consists of a programmable DC power supply with control software and GUI interface, output isolation, and a unique PV simulation engine that provides the I-V curve. This combination of hardware, software, and firmware allows the TerraSAS to simulate test protocols or combinations of events that a real-world solar installation will be subjected to.

The included software allows modeling of a PV panel without an extensive knowledge of solar array parameters. The only parameters required for a simulation are the open circuit voltage (Voc), short circuit current (Isc), and the peak power parameters Vmp and Imp. Changes to these parameters allow the shape of the I-V curve to be adapted to any fill factor between 0.5 and 0.95.

Once an I-V curve has been generated, changes to the irradiation level or temperature can be modified on the fly to test the behavior of a grid tied inverter under realistic conditions for cloud shadowing and panel temperature rise. Long term weather simulations can be loaded and run to determine the amount of energy harvest delivered in a given situation. Inverter designers use these accuracy and efficiency tests to optimize real MPP search modes.

Application
 Many solar inverters generate AC ripple on their DC input, which is connected to the photovoltaic array. For single phase inverters, the frequency of this ripple is twice the line frequency (120 Hz for US models). The simulator’s power supplies must not suppress this ripple as a function of their regulation loop. An increasing number of inverters (and virtually all micro-inverters) accurately measure amplitude and phase of the ripple voltage and current to quickly track the MPP of the array. This approach allows tracking the MPP at a much higher speed when compared to conventional dithering techniques (also called perturbate-and-observe). Faster tracking of the MPP results in a much higher overall efficiency in cloudy conditions, where the irradiance is constantly changing. It is likely that all solar inverters will use this approach in the near future, since end users are very sensitive to the overall efficiency of their solar energy installations. To satisfy this requirement, the PV simulator must be capable of reproducing the voltage / current behavior of a solar array at the ripple frequency. Most standard switching power supplies employ very large output capacitors and inductors in their output circuits and are unable to deliver the required performance - regardless of the response speed of the I-V curve controller. Elgar’s TerraSAS line of PV simulators are based on high speed versions of our standard products, where output capacitors and other speed-limiting components have been adjusted. This results in a speed improvement of 10 times or better.

Proprietary features built into the PV controller hardware and firmware, combined with our high speed power supplies, deliver the required performance. This technology was extensively tested on micro-inverters and is ready to test the next generation of inverters. The required performance is delivered by high speed switching power supplies and advanced DSP signal processing techniques. In some conditions traditional DC power sources using IGBT technology do not meet MPPT response speed requirements, depending on the MPPT principles. Our power supplies use Power MOSFETs, which typically switch ten times as fast as the most recent IGBTs. Higher switching frequency translates to smaller output capacitors and inductors - which is the key to a successful high speed power supply design

Scalability
 Power supplies are available in 850W, 5kW, 10kW, and 15KW increments. The 80V units are available in two power levels: 1200W for microinverters and 850W for the latest generation microinverters and DC power optimizers. The bandwidth on the 850W version has been improved to 30kHz by adding a linear regulation output stage. 600V units are available in 5kW, 10kW, and 15kW versions depending on Isc requirements. 1000V units are rated 10kW. All versions are easily connected in parallel to scale output power up to handle microinverters, string inverters, and even utility scale inverters. Many models can also be connected in series to handle higher voltage tests. Please refer to the connection diagrams located in the User Manual and follow appropriate wiring codes before connecting ETS PV simulators in series or parallel.

Real time I-V curve display
 The Elgar Real time I-V curve display is updated 20 times per second to illustrate dynamic inverter behavior (operating point and sweep amplitude). Compared to other commercially available solar array simulators with an update rate of only 1Hz, this allows more accurate analysis of the inverter’s actual MPP tracking ability.



Basic I-V Curve simulation
 The Elgar TerraSAS user interface is intuitive, graphically colorful and simple to learn. I-V curves are created by entering simple parametric data or by importing data from the NREL SAM database. It is not necessary to use Java Script or any other Script hosting to create an IV curve and execute it.



Dynamic Irradiance profile display
 The Elgar TerraSAS profile display of Irradiance and temperature is unique and innovative. It enables inverter designers to easily load and implement standards based cloudy condition scenarios, such as the weighted efficiency measurements called out in EN50530 or California Energy Commission. The ability to model dynamic performance profiles allows complex test validation in any situation in a repeatible, reliable manner. These standard profiles are impossible to simulate with a real array. It can also be controlled to a very fine degree and real profiles can be entered and run from actual speed to 100 times actual speed for accelerated lifecycle tests.





Photovoltaic array modeling
 This feature allows the user to quickly define an array of PV panels connected in series or parallel. Using this array modeling capability, the user can simulate such real world conditions as mismatched panels, which result in multiple hump I-V curves. It is important to verify that the MPPT algorithm finds and settles on the universal MPP, not a local maximum.



 

Features And Benefits

• Low output capacitance


•High bandwidth up to 30kHz


•High resolution I-V curve simulates static and dynamic conditions


• Designed for high speed Maximum Power Point Tracking (MPPT)


• Can be integrated into a multi-channel system for higher power testing


• Energy Harvest built in. *


•Low voltage, high bandwidth version for DC Power Optimizers


• EN50530 support