Schneider Electric South Africa introduces TeSys Deca Advanced to improve motor efficiency and industrial reliability. (Image source: Schneider Electric)

Schneider Electric South Africa has introduced the TeSys Deca Advanced, a next-generation contactor designed to elevate motor management through increased efficiency, reliability, simplicity, and sustainability

As a key player in digital transformation for energy management and automation, Schneider Electric’s latest innovation addresses evolving industrial needs with cutting-edge technology.

A standout feature of the TeSys Deca Advanced is its wide-band coil technology, capable of handling input voltages from 24V to 500V AC/DC. This allows the contactor to adapt seamlessly to voltage fluctuations while reducing energy consumption, resulting in lower CO₂ emissions and cost savings.

According to Thapelo Manthata, Offer Manager Power Products (PPCTR) at Schneider Electric South Africa, the solution is tailored for a wide array of industrial uses. “By combining digital capabilities, reduced energy consumption and more simplified installation, the unit is engineered to help optimise motor management while supporting sustainability and operational resilience.”

“The ideal applications for the TeSys Deca Advanced are robust, high industrial environments. As a contractor, it can be used for hoisting, pumps, HVAC systems, elevators and packaging applications. Additionally, it is suitable for mining and wastewater environments, among others,” says Manthata.

Engineered with ease-of-use in mind, the contactor features a user-friendly three-layer structure that improves wiring visibility and access. This streamlines setup and maintenance, reducing the need for highly specialised installation skills.

“So, it was designed for diverse industrial applications and simplifies installation and maintenance processes. Its ergonomic three-layer setup organises wiring for optimal visibility and accessibility, streamlining operations and minimising the need for specialised skills in the workforce,” added 

The TeSys Deca Advanced also incorporates one-click connection technology that cuts installation time by up to 75%, making it ideal for time-sensitive deployments. It supports direct PLC control, reducing both complexity and the need for extensive inventory by 80%.

Reliability meets predictive maintenance

“TeSys Deca Advanced is built for reliability, having gone through comprehensive testing to guarantee peak performance. It supports predictive maintenance by offering real-time diagnostics, allowing users to foresee and address potential problems before they cause any downtime,” concluded Manthata.

By focusing on key industries such as manufacturing, HVAC, and broader industrial operations, Schneider Electric ensures that the TeSys Deca Advanced contributes to greater uptime and streamlined performance.

“The TeSys Deca Advanced unit is designed to improve operational efficiency in various sectors, including manufacturing, HVAC, and industrial facilities. By integrating advanced technology with a strong emphasis on sustainability, we remain committed to maximising uptime and providing exceptional value.”

Solar Photovoltaic systems have a role to play in increasing South Africa’s power generation capacity

Solar Photovoltaic (PV) systems have a significant role to play in increasing South Africa’s power generation capacity, explainsShaniel Lakhoo, a senior electronic engineer for WSP in Africa

However, the PV power generation profile used in recent long-term planning simulations does not accurately represent the current and expected future PV power generation in the country.

South Africa is at a critical juncture in its energy transition.

With Eskom predicting that solar PV’s contribution to generation capacity will grow to 19% by 2030, it is clear that solar energy will play a pivotal role.

Understanding the power production profile for PV plants is critical in ensuring the right decisions are made on the generation technology mix to best meet the nation’s electricity demand.

Deploying the right mix is also critical to provide a stable lowest-cost electricity solution for the country.

A key decision when it comes to utility-scale PV plant centres on how the modules are set up on the site and whether the modules are fixed in place and angled to compensate for the latitude (fixed-tilt) or track the sun during the day on a single horizonal axis (single-axis tracking).

The choice has significant implications for cost-effectiveness, energy output and ultimately influences when and how much power may be injected into the grid.

The importance of accurate PV power generation profiles

The accuracy of PV power generation profiles is crucial for long-term power generation capacity expansion planning. These profiles inform the broader energy mix and capacity planning for the future.

The country’s studies, included in the Integrated Resource Plan (IRP) 2019, show the predominant use of fixed-tilt systems, with the IRP 2023 not providing sufficient information to conclude the profile used. This is despite the growing use of single-axis trackers in real-world projects.

Single-axis trackers, which follow the sun’s path throughout the day, generally outperform fixed-tilt systems in terms of energy production.

In my research, I found energy gains of 12.9% to 20.1% could be achieved annually by using single-axis tracking systems as opposed to fixed-tilt systems. By analysing the Levelised Cost of Energy (LCOE) — a measure of the average net present cost of electricity generation for a plant over its lifetime — my research aimed to determine which configuration would offer the lowest LCOE.

Across all scenarios and locations, single-axis trackers consistently emerged as the most cost-effective solution. Despite the higher upfront costs, the energy gains from using trackers more than offset these expenses. This resulted in a lower LCOE compared to fixed-tilt systems.

Part of this research included a sensitivity analysis to understand the most significant factors impacting LCOE. The analysis revealed that the Balance Of System (BOS) costs and the Ground Coverage Ratio (GCR) are the most critical variables.

Interestingly, the cost of land had only a minor influence on LCOE. This was true even with the upper band equivalent to more than four times the profits that could be expected from using the land for agricultural purposes.

Bifacial modules were explored in my analysis as these become more prevalent in the market and are being deployed in new projects. However, my simulations found the additional energy produced by bifacial modules does not justify the 6% premium over single axis trackers. For fixed tilt systems, the added energy was sufficient to make this the lower LCOE solution.

These insights are crucial for decision-makers. The analysis showed that even in scenarios with lower GHI (Global Horizontal Irradiance), single-axis trackers with mono-facial modules remained the most cost-effective choice. Additionally, the plant design can be optimised based on GCR, knowing the cost of land is not a significant factor, thereby improving the overall feasibility of solar projects.

Creating a representative power profile

One of the valuable outcomes of the research was the development of a representative PV power generation profile for South Africa. This was achieved by weighting the contributions from the 11 Renewable Energy Development Zones (REDZ) across the country, against the expected deployment of PV according to the Integrated Resource Plan (IRP) 2019. The resultant profile blends these contributions to create a profile reflecting the anticipated future solar generation.

This new profile is based on the most cost-effective solution identified in simulations (single-axis trackers with mono-facial modules) and provides a revised profile that forms a more reliable basis for future energy planning. It is a step towards ensuring our long-term energy forecasts are grounded in the realities of the technologies we’re deploying.

The journey of exploring PV tracking choices has underscored the importance of aligning our energy planning with the latest technological and market advancements. As South Africa moves towards decarbonisation, it is crucial long-term planning reflects realistic predictions, rather than solely historical data or outdated assumptions.

The transition to renewable energy is not just about adopting innovative technologies. It comes down to making informed decisions that will shape the sustainability of our energy systems for decades to come.

In the case of utility-scale PV power plants, that means ensuring representative profiles are used when completing long-term planning simulations.

Shaniel Lakhoo is a senior electronic engineer for WSP in Africa

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James Saruchera, co-founder of Afrik. (Image source: Afrik)

As Africa races to position itself within the Fourth Industrial Revolution, the continent’s energy deficit continues to stall progress.

While AI, cloud infrastructure and smart industry capture headlines, it is energy – reliable, accessible and decentralised – that underpins the viability of every digital innovation.

“Energy is no longer just a utility – it’s the bedrock of sovereignty in a digital world,” said James Saruchera, co-founder of Afrik, a decentralised finance infrastructure built to fund real-economy projects across Africa.

“We cannot talk seriously about AI readiness or smart manufacturing without first addressing the bottlenecks in energy access and financing.”

Saruchera, who recently attended the Global AI Summit on Africa in Rwanda, pointed to a growing consensus among African policymakers and innovators: without a radical rethink of how energy infrastructure is funded, the continent risks falling behind in the very technologies it seeks to lead.

Despite holding one of the world’s richest renewable energy profiles – including vast solar, hydro and geothermal potential – Africa remains hampered by traditional, centralised financing models that often prioritise external interests and short-term returns.

“The capital is out there. The technology is out there. What’s broken is the pathway between the two,” Saruchera said.

“Right now, we’re relying on legacy systems of financing that don’t match the speed or structure of our economies. They’re too slow, too opaque and too extractive.”

Afrik’s response has been to re-engineer the infrastructure around infrastructure.

By building a blockchain-based platform to facilitate secure, transparent investment into vetted energy and digital projects, Afrik enables both institutional and citizen investors to back infrastructure in a way that’s traceable, compliant and locally anchored.

“The premise is simple,” said Saruchera. “Africans should be able to invest in and benefit from the systems that will define their future. We’re not just solving for capital – we’re solving for trust, for ownership, and for longevity.”

Afrik’s model moves away from debt-heavy, donor-led development and towards pooled, participatory finance – where individuals, communities and institutions can collectively fund projects with full visibility over how money is spent and impact is delivered.

Crucially, Saruchera sees this as more than a tech play. It’s a policy tool.

“Afrik is already receiving strong engagement from innovation ministries, regulators and institutional funds that understand the need for alternatives,” he said.

“They know we need mechanisms that are fast, auditable and scalable – especially for midsize and off-grid projects that aren’t attracting enough traditional capital.”

Afrik’s pilot pipeline includes solar mini-grids, community-level battery storage and digital infrastructure – selected not for their PR value, but for their replicability and ability to bridge energy and data needs at the same time.

“We’re focusing on real utility, not vanity,” said Saruchera. “These are the kinds of projects that can support AI labs in Kigali, keep rural clinics online in Malawi, or power last-mile logistics in Lagos.”

Asked about the pace of adoption, Saruchera is pragmatic but optimistic.

“We’re not saying this replaces traditional finance overnight – but it complements it, fills gaps and builds systems of resilience from the ground up,” he said.

“What we’re proving is that Africa doesn’t have to wait for the world to catch up. We can build financing infrastructure that’s modern, agile and fundamentally designed for our own economic architecture.”

In an era where development models are being reimagined across the Global South, Afrik’s emergence reflects a broader shift: from dependency to design, from charity to capital, from exclusion to participation.

“Africa’s energy future will not just be green – it must be governed, funded and owned differently,” said Saruchera. “If we can fix how we finance our future, the rest will follow.”

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Inside of one Phoenix Group's data installations (Image source: Phoenix Group)

UAE-based Phoenix Group has announced that it has added 52 MW of additional electricity capacity in Ethiopia to power its local bitcoin mining operations in the country

The cryptocurrency and blockchain company said the expansion increases its total operational capacity in the East African country to 132 MW.

It also raises its global capacity to over 500 MW across five countries, underlining the group’s position as one of the world’s leading bitcoin miners.

The additional capacity will be hydro power, sourced from the Grand Ethiopian Renaissance Dam, according to a company spokesperson.

In a statement, Phoenix Group said its Ethiopian operations now rank “among the most sustainable in global bitcoin mining,” with 90% of its local energy sourced from renewable hydropower via the Grand Ethiopian Renaissance Dam.

“The opportunities for future growth are immense, and we are committed to aggressively expanding our global footprint in key energy markets,” said Munaf Ali, CEO and co-founder of Phoenix Group.

“Initiatives like our latest expansion in Ethiopia are pivotal steps, not only creating significant value today but also solidifying our position at the forefront of this dynamic global industry for years to come.”

Earlier this year, the company marked its entry into Ethiopia with an 80 MW power purchase agreement (PPA), laying the groundwork for its operations in the region.

It noted that the newly secured 52 MW site will be developed in two phases.

Phase 1 will deliver 20 MW of capacity, activating 5,300 high-efficiency air-cooled mining units with an expected output of 1.2 EH/s.

Phase 2, set for completion by the end of Q2 2025, will add a further 32 MW, using hydro-cooling technology.

Once fully operational, the site’s total hash rate is projected to double to approximately 2.4 EH/s.

“With 132 MW now running on clean hydropower, we’re proud to set a new benchmark for sustainable mining in Africa and deliver large-scale operations in energy-rich regions,” said Reza Nedjatian, CEO of Phoenix Mining, AI & Data Centres.

Phoenix Group is the first crypto and blockchain company in the Middle East listed on the Abu Dhabi Securities Exchange (ADX) and operates the largest mining farm in the Middle East and North Africa region.

As well as Ethiopia, it operates bitcoin mining facilities across the UAE, USA, Canada and Oman.

“Phoenix Group has rapidly become a leading force among the top 10 global bitcoin mining companies,” added Ali, “a testament to our strategic foresight in securing prime locations with abundant, low-cost energy and our operational excellence driven by vertical integration and cutting-edge technology.”

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