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News from IT House 3 June, SNEC PV+ 19th (2026) International Solar Photovoltaic and Smart Energy (Shanghai) Congress opened today at the Shanghai National Convention and Exhibition Centre.

At the meeting, the PowerMatrix Matrix Reverse was officially released by the Sun PowerMatrix Matrix, and its core matrix reversibility system was launched simultaneously, known as the “no triangulation” to address the costs, efficiency and stability that had plagued the industry for so long.

The matrix's reverse system was described as covering a wide range of applications such as large energy bases, green power companies, microgrids and AIDC. The “matrix” in its name reflects the design concept of “multi-element access, multi-pathway connectivity, multi-unit synergy” and aims to achieve orderly synergy between power, grid, load and storage.

IT House Note: The matrix reverser integrates the four main functions of photovoltaic retroversion, storage transformation, energy routing and network control into the same equipment, different from the structure designed for the photovoltaic retrovert in the traditional programme from the storage transformer.

In terms of performance performance, the matrix reverse system has been optimized from the three dimensions of cost, efficiency and stability.

On the cost side, through equipment integration, engineering simplification, and capacity elastication, the system BOS costs were reduced by more than 10%, and the “deficit – storage – loss –” full-chain efficiency was optimized, resulting in LCOE being reduced by more than 2%. In the case of a typical light storage project for a 1GW photovoltaic machine and 2GWh storage capacity in the Northwest Territories, the matrix reverse system can achieve a CAPEX reduction of $326 million and an IRR increase of over 1.5% compared to the traditional exchange coupling programme.

In terms of efficiency, the system achieved full-chain re-engineering from the side of power generation to the side of load: PV per MW support up to 28-road MPPT independently tracking up to 0.8% PV power generation; storage side up by 8% full life cycle discharge through multi-stage SOC balance; power conversions and transmission links down 2 stage transformations and conversion efficiency up 3% to 5%.

In terms of stability, the system migrates stability to each unit of power generation, with primary support of 260 per cent of the high-composite ratio and 200 per cent of the storage power charged, with an average annual utilization of up to 30000 hours, up to 100 per cent of the conventional photovoltaic power station, close to the normal power source operating level.

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