Solar Pv System Quotes

There is a lot of willful incompetence in solar industry that is in the process of coming to light.

I have been through the OSHA system twice and I can confirm that I did not have the right to a safe workplace or whistle-blower protection on either occasion.

The top easily preventable health problems that I see in western societies are: 1. Eating chemically grown food. 2. Exposure to electronically generated harmonic energy from wind and solar power systems. 3. Exposure to harmonic energy from switched mode power supplies (SMPS) that come with modern electronic products. 4. Exposure to wireless radio frequency radiation (RF). 5. Light deficiency from an indoor lifestyle and Low-E double glazed windows. 6. Sound deficiency from heavily insulated homes that are devoid of natural sounds and are extremely quiet. 7. Pollen deficiency from living in man-made cities that are devoid of natural levels of pollen. 8. Natural radiation deficiency from living in homes that block natural levels of environmental radiation. 9. Open drain sickness that occurs when drain traps dry out and faulty vent valves that allow sewer gas to fill the home. 10. Drinking the wrong type of water.

Much has also been written about a reverse manifestation of exponential change, about the impressively declining cost of solar photovoltaic cells leading to near-miraculous breakthroughs in solar electricity generation. The latter claim has been particularly popular: I encourage you to check those breathless reports of constantly and rapidly falling photovoltaic (PV) cell prices, and you will see how, if they were the only determinant of the actual cost of PV generation, we would soon be arriving at almost the same place where nuclear generation claims began in the mid-1950s, with solar generation being too cheap to meter, indeed, being absolutely a free give-away. In reality, detailed US data for residential PV systems (twenty-two panels) show that the module cost is now only about 15 percent of the total investment. The rest is needed to cover structural and electrical components (panels must be mounted on supports on roofs or on prepared ground), inverters (to change the direct current to alternating current), labor costs, and other soft costs. Obviously, none of these components, from steel and aluminum to transmission lines, permitting, inspection, and sales taxes, is tending to zero, and hence the overall costs of installation (dollars per watt of direct current delivered by the panels) show a distinctly declining rate of improvement: between 2010 and 2015 they fell by 55 percent, between 2015 and 2020 by 20 percent. And these costs do not include the additional outlays that will have to be made with the increasing share of intermittent sources (solar and wind) in overall electricity generation.

Regarding solar power systems, the bigger the system is, the more likely it may go on fire.

One of the biggest lies that is currently being told in the USA workplace is on the legally required OSHA poster: All workers have the right to a safe workplace.

The current generation of solar and wind power systems generally introduce instability into the electrical utility grid system with their intermittent power generation characteristics and electronically generated harmonic energy.

The era of biologically toxic wireless radio frequency (RF) radiation and harmonic electronic power generation from wind and solar systems with their adverse brain modifying effects that can bring on irritable and aggressive behaviors has made it a bad time to be a police officer.

If you are looking for a job that may make you sick, I can recommend working at a high powered solar photovoltaic (PV) utility power plant.

Poorly functioning solar power systems were around when I worked in the field.

A PV system producing 1 kW of electricity prevents an environmental pollution by 850 kg (about 1,875 lbs) carbon dioxide per year!

When I was commissioning a brand new solar photovoltaic utility site, I came across metal tubes installed into the fuseholders that were marked up as 100 amp fuses on the diagram. Needless to say, it had already gone on fire.

210mm Bifacial PV Modules Market Introduction The market for 210 mm bifacial photovoltaic (PV) modules has emerged as a crucial frontier in the solar energy industry. With the larger wafer size enabling higher power outputs, and bifacial modules capturing reflected sunlight from both the front and rear surfaces, this format offers enhanced energy yield and improved economics. The rise of 210 mm bifacial modules is being driven by escalating demand from utility‐scale solar power plants, technological advancements (especially in N‑type cell architectures), and aggressive deployment in regions such as Asia‑Pacific. As module formats evolve and economies of scale grow, companies are investing heavily in manufacturing capacity for 210 mm bifacial modules. From a strategic standpoint, the adoption of the 210 mm format (and associated technologies such as TOPCon, HJT) represents a shift in the PV value chain, one that promises lower levelised cost of electricity (LCOE) and better performance under real‑world conditions. Market Overview The global 210 mm bifacial PV modules market is projected to grow at a strong pace over the coming years. Estimates indicate a compound annual growth rate (CAGR) ranging from about 9 % to 10.5 % for the period 2025–2033, depending on the source. One forecast pegged market size at approximately USD 12.8 billion in 2024, expanding to USD 28.4 billion by 2033. Another report placed a base size near USD 5.2 billion in 2024 and projected USD 12.7 billion by 2033. Clearly, the large‐format (210 mm) and bifacial combination is gaining momentum. The shift to the 210 mm wafer size has been rapid: for example, industry data suggests that about 80 % of Chinese PV producers had 210 mm capability as of mid‑2022, with 210 mm modules taking a growing share of shipments. The advantages of the format include higher power ratings, improved energy yields (including under low‑irradiance conditions), and lower balance‑of‐system costs per watt. Nevertheless, the market also faces challenges: supply chain bottlenecks, raw material inflation (for silicon, wafers, encapsulation materials), and policies/regulations affecting module trade and incentives. Moreover, deployment in smaller applications (like residential rooftops) may lag compared to utility‑scale, due to cost sensitivity and logistics of larger modules. Overall, the trajectory is strongly positive for 210 mm bifacial modules, especially in large scale power plants and commercial/industrial applications. Key Drivers Several factors are fueling the uptake of 210 mm bifacial modules: Higher energy yield: The bifacial module captures light from both front and rear surfaces; when combined with the large 210 mm wafer size, energy yield gains are noticeable. For example, outdoor testing showed that a 210 mm wafer format module achieved up to 1.6 % higher yield compared to a 182 mm format in certain conditions. Cost reduction: The larger wafer size allows more power per module and fewer modules required for the same output, thereby reducing installation labour, wiring and mounting costs. Further, bifacial modules extract more energy per unit area, improving the economics of projects. Manufacturing scale and capacity expansion: Many manufacturers have invested substantially in large‑format production lines. The 210 mm format is becoming mainstream, thereby driving economies of scale. Policy/regulatory support: Incentives and renewable‑energy targets in many regions are pushing solar deployment. Utility‐scale developers favour high‑power modules (often 600 W+), for which 210 mm bifacial formats are suited. Technological synergy: 210 mm modules are often paired with advanced cell technologies such as N‑type or TOPCon, further improving efficiency, lifespan and performance under low light or high temperature.