21 October 2020

Qatar Environment and Energy Research Institute and Eternalsun Spire Collaborate to Enhance Solar Power Research

Qatar Environment and Energy Research Institute (QEERI), part of Hamad Bin Khalifa University, aims to achieve the lowest temperature coefficient measurement uncertainties with Eternalsun Spire long pulse xenon flasher. The temperature-controlled laboratory flasher is a critical piece of equipment used by QEERI to provide key data and performance control to the 800MW Al Kharsaah solar park, ensuring optimization and long-term quality control of the solar plant

Engineers of eternalsun spire and researchers of qeeri in front of the tempearature conrolled lab flasher

QEERI’s goal as a national research institute is to lead Qatar in the fields of environment and energy and become the science and technology reference at a national and international level. Like all Sunbelt countries, Qatar experiences high temperature and high solar irradiation that far exceed the Standard Test Conditions (STC) of 1000 W/m2 and 25°C. Therefore, it is important to understand module performance at different temperature and irradiance levels, simulating real desert conditions. To gain this knowledge, QEERI has recently added the high-end Temperature Controlled Lab Flasher (TCLF) from Eternalsun Spire to its state-of-the-arts Photovoltaic (PV) reliability laboratory.

The TCLF allows QEERI to measure the performance of modules at non-standard test conditions with the lowest measurement uncertainty proving of value to QEERI and its clients across multiple areas:

  • It improves the accuracy of energy yield predictions, which reduces the safety margin added when tendering or designing a PV plant, such as the 800 MW Al Kharsaah solar park.
  • It adds certainty to their module selection process by knowing which modules perform best under site specific irradiance and temperature conditions.
  • Long-term quality control of modules can be tested, research and assured, ensuring that the performance degradation of modules meets the 20 to 30-year warranted value.
  • A range of research topics can be investigated, particularly relating to performance and degradation of modules at non-standard test conditions.

A concrete example of the immediate value that low measurement uncertainty can have when performing measurements at non-standard test conditions, are temperature coefficients. In industry, typical measurement uncertainties of temperature coefficients have been around 10%. A 10% difference in temperature coefficient equates to an approximate 1.2% difference in energy yield for Sunbelt regions. This 1.2% difference has a financial impact estimated at 1.8M for a 100MW plant over a 20-year lifespan.

Why QEERI chose Eternalsun Spire

QEERI has chosen the Eternalsun Spire TCLF as it achieves an overall measurement uncertainty of less than 5% for temperature coefficient measurements. This is important for energy yield prediction of solar plants installed in desert climates. The lowest measurement uncertainty is accomplished using a combination of extremely accurate simulated sunlight qualities: >200 ms long and stable pulse, wide 300-1200 nm spectrum with >99% Spectral Coverage, and extreme high resolution uniformity and repeatability (>99,85%); with an integrated built-in temperature chamber with extremely stable temperature control from 10-85 °C, a low temperature non-uniformity of ±1 °C, and automatic temperature coefficient and energy rating recipe software.

The long pulse enables accurate and fast measurements of PV modules without the need for software corrections. The wide spectrum 300-1200 nm with >99% Spectral Coverage (SPC), according to the latest IEC 60904-9 Ed3 (published September 25, 2020), allows for the measurement of the additional efficiency gains achieved in PV technologies such as PERC, HJT and TOPCon. These technologies increase their efficiency through increased spectral response particularly in the 300-400 nm and 1100-1200 nm ranges.

Mr. Amir A. Abdallah, scientific researcher at QEERI, stated “After carefully investigating our options in the market, we chose the TCLF system from Eternalsun Spire to bring our laboratory to the forefront of high quality testing of different PV module technologies at non-standard test conditions.”

Mr. Alex Goscomb, sales manager of Eternalsun Spire, commented: “We are proud of our collaboration with QEERI, and we look forward assisting them to achieve their goal of becoming a leading solar research institute and progressing the implementation of solar.”


Qatar Environment & Energy Research Institute (QEERI), part of Hamad Bin Khalifa University (HBKU), is a national research institute tasked with supporting Qatar in addressing its grand challenges related to energy, water, and environment. QEERI – with its experienced scientists, engineers, and technicians supported by its focused management and operations teams, working within its world-class indoor and outdoor facilities – aims to make a lasting positive impact on Qatar and the region. The institute’s work is in line with the goals set forth by Qatar National Vision 2030, and is supported by Qatar Foundation Research, Development and Innovation (QF RDI).

About Eternalsun Spire

Eternalsun Spire is a leading manufacturer of solar simulators and integrated climate chambers for measuring the performance and reliability of PV modules. It serves a global customer base of PV module manufacturers, research institutes and test laboratories. Its mission is to contribute to the development and growth of the solar industry by enabling the highest degree of measurement control and certainty by providing high-end solar testing knowledge, technology and services. Eternalsun Spire simulators have renowned capabilities regarding repeatability, reproducibility, spectrum, uniformity, and stability.