photovoltaic panels – Voltmax Energy Solutions in Luxembourg

Overpaneling and inverter sizing – how much DC oversizing is smart?

Voltmax — Wed, 10 Dec 2025 11:39:25 +0000

When planning a PV installation and trying to match the power of your solar panels to the inverter, you quickly discover that inverter sizing and PV system design have a major impact on long-term solar energy production. One of the most important concepts in modern solar engineering is over-paneling, also known as DC oversizing. In today’s PV systems, the DC/AC ratio directly influences performance, return on investment and how effectively the solar system works in real-world conditions.

This guide explains when over-paneling is worth applying, how an oversized PV array can increase annual energy yield, what solar designers should consider when choosing the DC/AC ratio, and which limitations signal that adding more panels no longer provides meaningful benefits.

What is overpaneling in a solar PV system?

DC-to-AC ratio explained in simple terms

Overpaneling refers to installing a photovoltaic array with a higher DC power capacity than the nominal AC power output of the inverter. In other words, the solar panels are intentionally oversized in comparison to the inverter’s rating. The key parameter here is the DC-to-AC ratio, which tells us how much total panel power (DC) is connected to how much inverter power (AC). For example, if a 7 kW DC array is connected to a 5 kW AC inverter, the DC-to-AC ratio is 1.4. Increasing this ratio allows the system to produce more usable power during most daylight hours, especially in the morning, late afternoon, or during cloudy conditions. As a result, the inverter spends more time operating close to its peak efficiency rather than underloaded.

What is inverter clipping and why it happens

Because the solar panels can generate more DC power than the inverter is able to convert to AC at any given moment, there are short periods—typically around midday on very sunny days—when the inverter reaches its maximum output and cannot convert the surplus energy. This limitation is known as inverter clipping. The excess power is simply not used, so the system’s production curve gets “flattened” at the top. While clipping may sound like a drawback, the additional energy produced during the rest of the day usually outweighs the small amount of energy lost during peak production hours. This is why overpaneling is considered both economically and technically beneficial in many installations, especially in regions with variable climate or limited roof space.

Why overpaneling works in real-world PV performance

In theory, solar panels should deliver their full nameplate power output — but this happens only under Standard Test Conditions (STC), which almost never occur on an actual rooftop. Real-world weather, temperature, dirt, shading, and seasonal angles reduce the effective production of every PV array. Overpaneling compensates for these natural performance losses by connecting more DC power (solar panels) to the inverter than the inverter’s maximum AC rating. As a result, instead of working underloaded most of the time, the inverter delivers high output more consistently throughout the day and throughout the year.

Panels rarely reach their STC nameplate power

The wattage printed on a solar panel label represents output under perfect laboratory conditions: 1,000 W/m² irradiance, 25°C cell temperature, and an ideal light spectrum. On a real roof, these numbers are almost never achieved. High cell temperatures in summer can reduce panel efficiency by 10–20%. Dust, clouds, morning and evening sun angles, and winter conditions bring the output even lower. This means a “10 kW” PV array often spends only a tiny portion of the year operating anywhere near 10 kW. By oversizing the DC side, homeowners make better use of the inverter’s capacity throughout the day instead of leaving energy production unused.

Lower cost per kWh by adding more solar panels

From a financial point of view, overpaneling increases the return on investment. In many markets, solar panel prices have dropped significantly, while inverters remain a relatively expensive component. Instead of buying a substantially larger inverter, it is usually cheaper to add a few more panels to boost annual energy production. Even if a small amount of energy is occasionally clipped at noon on very sunny days, the extra energy harvested in the mornings, afternoons, and in cloudy weather far outweighs those losses. The result is more solar electricity for the same or nearly the same total system cost — and therefore a lower cost per kilowatt-hour over the lifetime of the installation.

Why overpaneling boosts real-world performance

Solar panels reach their nameplate power only under rare laboratory conditions
Overpaneling helps to compensate for temperature, weather, and seasonal losses
The inverter runs closer to its optimal efficiency for a larger portion of the day
Occasional inverter clipping is minimal compared to gains in yearly energy output
Adding extra panels is usually cheaper than upgrading to a larger inverter
More annual production = lower cost per kWh and faster ROI

When does over-paneling stop being beneficial?

Over-paneling remains effective only within a certain range. Industry-standard inverter sizing usually recommends a DC/AC ratio between 1.2 and 1.5. Beyond this level, the benefits flatten out while the disadvantages grow.

One of the first symptoms of excessive DC oversizing is prolonged inverter clipping. Short, midday clipping peaks are normal and have minimal impact on yearly output, but clipping that lasts for hours each day reduces annual production and can undermine the purpose of over-paneling.

Voltage limits also play a critical role. In cold conditions, open-circuit voltage increases, and overly long strings can exceed the inverter’s maximum input voltage. This poses a technical risk and requires the array to be redesigned. Excessive oversizing may also lead to higher thermal stress on the inverter, reducing reliability and lifespan by forcing it to operate near its limits too frequently.

Economic factors matter as well. When using high-end solar panels, adding more modules can become disproportionately expensive compared to selecting a slightly larger inverter. For these reasons over-paneling is best applied within an optimal range where PV system efficiency rises without surpassing electrical or economic limits.

Recommended DC-to-AC ratios for modern PV design

Selecting the right DC-to-AC ratio is one of the most important decisions when sizing a solar PV system. A well-designed system aims to maximize yearly electricity production while keeping hardware costs under control and avoiding excessive clipping. In modern PV engineering, slight oversizing of the DC side is not a flaw — it is now considered a best practice, especially given today’s panel efficiency, temperature behavior, and rapidly falling module prices. The key is not to avoid clipping completely, but to choose a ratio where the inverter runs close to its peak efficiency much of the year while clipping remains minimal and financially insignificant.

Typical design ranges for residential and small commercial

Most PV designers today no longer aim for a 1:1 DC-to-AC match. For residential systems, optimal ratios frequently fall between 1.2 and 1.4 — and even 1.5 can be justified in climates with frequent cloud cover, high temperatures, or east–west roof layouts. For small commercial installations, ratios of 1.3 to 1.6 are common due to higher daytime energy demand and larger roof areas. These ranges allow the inverter to operate closer to its peak power rating more consistently, improving energy yield without requiring a larger, more expensive inverter.

Annual energy gain vs clipping losses

When the DC array is oversized, two things happen:

Annual energy production increases because low and medium irradiation periods are used more effectively.
Short periods of inverter clipping occur around solar noon on very bright days.

However, long-term data shows that the energy gained throughout the year is significantly greater than the energy lost to clipping. Even at a 1.4 ratio, clipping losses might total only 1–3% annually, while total generation may increase by 8–15%. For most homeowners and businesses, the additional production during mornings, afternoons, and cloudy days is what drives the return on investment.

Is inverter clipping really a problem?

In practical terms — not usually. Clipping looks dramatic when viewed on a production graph, because the curve appears “flat-topped” at peak midday hours. But the duration of clipping is short, and the total kilowatt-hours lost are small. Avoiding clipping entirely would require purchasing a larger inverter, leading to higher system costs for very little additional production. Modern PV design philosophy accepts a small amount of clipping as a strategic trade-off for a larger yearly energy yield and lower cost per kWh. The real “problem” is not that clipping exists — it’s when a system is undersized on the DC side, causing the inverter to run below its optimal output for most of the day.

How to decide if overpaneling makes sense for your roof

Overpaneling is not just a technical trend — it is a strategic design choice that can significantly increase your annual solar production when applied in the right conditions. The key is to evaluate your roof, inverter size, space availability and energy goals as one system. You don’t need to eliminate clipping completely — the smartest PV systems accept a small amount of clipping in exchange for much higher total kWh across the year. If your aim is to maximise clean energy from every square metre of roof, overpaneling is often the most cost-effective solution.

Checklist for homeowners and PV designers

Use this list as a quick decision tool — if most points match your situation, overpaneling probably makes sense:

You want to maximise total annual kWh production, not just peak midday output
You have unused roof space where you could add more panels without major extra cost
Your region has variable weather, frequent clouds, high summer temperatures or winter seasons
You have east–west roof orientations or several roof planes rather than a single perfect south pitch
You want to reduce payback time and lower the cost per produced kWh over 25 years
Adding more panels is cheaper than buying a significantly larger inverter
A small amount of inverter clipping is acceptable in exchange for more energy throughout the year
The inverter manufacturer supports oversizing and the design stays within warranty limits
Local grid connection rules allow oversizing of the PV array relative to the inverter

Questions to ask your installer about overpaneling

To ensure a safe and financially optimal design, it’s useful to speak openly with your installer. Recommended questions include:

What DC-to-AC ratio do you recommend for my roof and why?
How much clipping do you expect annually and how will it affect total energy production?
Will oversizing the panels stay within the manufacturer warranty and technical limits of the inverter?
Is a bigger inverter necessary, or is adding more panels a better investment in my case?
How will roof temperature, shading and orientation affect an oversized array?
Can you show projected yearly production for a 1.0 vs 1.3–1.4 DC/AC setup?

A professional installer like Voltmax provides side-by-side annual yield simulations for different DC/AC ratios, helping homeowners choose the most profitable configuration rather than the biggest inverter. This removes uncertainty and makes the decision purely data-driven.

FAQ — overpaneling, inverter sizing and clipping

Overpaneling refers to connecting a solar panel array (DC power) that is larger than the AC rating of the inverter. The goal is to increase total yearly electricity production — not just maximize output during the brightest hours of the day. A slightly oversized DC array allows the inverter to operate closer to its maximum power for more hours across the day and across the year, especially during mornings, afternoons and cloudy weather. A small amount of inverter clipping becomes acceptable because the net energy gain far outweighs the small losses at midday.

Is it safe to oversize solar panels compared to the inverter?

Yes. Overpaneling is safe when it follows the inverter manufacturer’s specifications. Modern inverters are designed to limit their output safely once they reach their maximum AC power rating — they do not “overheat” or become overloaded. Oversizing does not push additional AC power into the grid; the inverter simply caps the output and discards the unused surplus.

How much can I overpanel my inverter — what DC/AC ratio is best?

For most residential and small commercial systems, a DC/AC ratio between 1.2 and 1.4 provides the best balance of annual production and equipment cost. Ratios up to 1.5 are often viable in climates with high temperatures, frequent cloud cover or mixed roof orientations. The goal is not to eliminate clipping, but to increase total kWh throughout the year and reduce the cost per produced kWh.

Does overpaneling damage the inverter or affect its warranty?

No — as long as oversizing stays within the limits specified by the inverter manufacturer. Overpaneling does not force the inverter to output more power than it is designed for; it simply gives the inverter more available DC power to convert. In practice, warranty conditions often include a maximum allowable DC/AC ratio, and staying under that threshold keeps the warranty fully valid.

What is inverter clipping and should I worry about it?

Inverter clipping occurs when the DC power from the solar panels briefly exceeds what the inverter can convert to AC — usually around midday on very sunny days. The inverter simply caps the output at its maximum and discards the excess. Clipping may look dramatic on a production graph, but the total lost energy is typically very small, while the extra production gained during the rest of the day is much greater. In modern PV design, slight clipping is considered normal and economically beneficial.

We invite you to our stand at the HOME EXPO

Voltmax — Wed, 02 Oct 2024 11:54:51 +0000

We are with our stand at the HOME EXPO fair, we invite you, your friends and family to participate in the fair and visit us in the Hall.

Our Stand 8D74

Join us at the largest construction and interior design fair – Home Expo 2024! Visit the Voltmax stand, where our experts will show you the latest solutions in photovoltaics, energy storage and electric car chargers.

10 to 13 October 2024 @ LUXEXPO THE BOX

Thursday: 10:00 am – 7:00 pm
Friday: 10:00 am – 9:00 pm
Saturday 10:00 am – 7:00 pm
Sunday: 10:00 am – 7:00 pm

✅ Learn how to reduce your electricity bills
✅ Discover the benefits of your own PV installation
✅ Take advantage of our specialists’ advice

Our advisors offer:

Energy consulting
Photovoltaic installation consulting
Heat pump heating installation advice
Consulting on government and municipal subsidies
Electrical Services Consultation

Don’t miss this opportunity – come and see how you can take care of savings and ecology in your home. See you at Home Expo 2024!

Fair website: https://home-expo.lu/

Your free admission: (download free ticket with QR code)

Admission tickets 2024

Home Expo 2024 is the largest construction, renovation and interior design trade fair in Luxembourg. The event will bring together hundreds of exhibitors from the construction, energy and design industries, offering the latest technologies and innovative solutions for homes and apartments.

During the fair, visitors will have the opportunity to:
✅ Learn about modern technologies in the field of construction and energy
✅ Consult with experts in photovoltaics, heating and energy saving
✅ Discover trends in interior design and smart home systems
✅ Take advantage of special offers and discounts available only during the event

The fair is also a great opportunity to talk to industry leaders and gain valuable tips on construction, modernization and energy-saving solutions.

Don’t miss this unique event!

Missed us at last year’s Home Expo? Book a private consultation today and enjoy the same experience — tailored exclusively for you, with the attention of a true luxury client

Recover and reuse: Recycling of photovoltaic panels

Voltmax — Fri, 22 Mar 2024 11:19:48 +0000

Recycling photovoltaic panels is an increasingly common phenomenon.

Recycling of photovoltaic panels in Europe and Luxembourg is gaining increasing importance in the context of the growing demand for sustainable energy solutions. This process, which enables the recovery of valuable materials and reduces environmental impact, becomes not only an answer to ecological needs but also to legal requirements imposed by EU directives.

Across Europe, thanks to stricter regulations on electronic waste and greater ecological awareness, countries such as Germany, Italy, Japan, and China lead in the implementation of advanced recycling technologies. The European Union, through various directives, obligates manufacturers and importers of photovoltaic panels to organize and finance recycling systems, aimed at increasing the efficiency of resource recovery and reducing the negative environmental impact.

Is it possible to recycle photovoltaic panels? If so, which part can be recycled?

In general, all photovoltaic panels are recyclable. Indeed, there are risk-free procedures for silicon-based panels as well as for thin-film panels containing cadmium. Moreover, recycling is regulated by the European Directive 2012/19/EU on waste electrical and electronic equipment, which is transposed into national law by the law of 9 June 2022 on waste electrical and electronic equipment: this framework currently requires at least 80% of the mass of a photovoltaic panel to be prepared for reuse or recycled, and 85% of the mass to be recovered.

The recycling rate of photovoltaic modules is nevertheless close to 100%, considering that the modules are generally composed mainly of glass, aluminium and other metals. Net modules usually contain very limited amounts of synthetic materials, such as silicon or other minerals. However, it is technically possible to recycle these elements, even if the processes for extracting them are not yet cost-effective. Thus, these materials are currently mainly used for thermal recovery.

The photovoltaic panel recycling process, which includes collecting and sorting, dismantling, shredding, thermal treatments, chemical processes, and cleaning, allows for the recovery of key materials such as glass, metals (including silver and aluminum), silicon, and other substances. These actions not only contribute to environmental protection but also support the development of sustainable solar energy, offering a second life to recovered materials. Let’s trace the key stages of this process that enable the transformation of used photovoltaic panels into valuable resources.

Stages of the recycling process

The photovoltaic panel recycling process consists of several stages:

Collecting and sorting: Panels are collected and transported to recycling centers, where they are sorted based on their type and material composition. The initial segregation involves separating elements into major categories: panels, equipment, wiring, heat sources, etc.
Dismantling: The preliminary dismantling involves removing aluminum frames and connectors, which are relatively easy to recover and reuse.
Shredding: Next, the panels are shredded to reduce their size and facilitate the separation of different components.
Thermal treatments: In some methods, panels are subjected to high temperatures to separate glass from other materials.
Chemical processes: At this stage, various chemical methods are used to recover valuable materials, such as silver, lead, or silicon.
Cleaning: The final stage involves cleaning the recovered materials so they are ready for reuse in the production of new photovoltaic panels or other products. Recovered substances and materials

In the process of recycling photovoltaic panels, a range of valuable materials are recovered:

Glass: Makes up about 75% of the panel’s mass and is easily recovered for reuse. The possibility of recovering glass from photovoltaic panels is high, reaching about 90-95%. This glass can be reused in the production of new panels or other products.
Metals, such as silver used in wires, and aluminum from panel frames. The recovery of metals from photovoltaic panels is also efficient, with the recovery of silver reaching up to 95%, and aluminum – up to 100%. These metals can be reused in various industrial sectors.
Silicon: Can be recovered, although its purification for reuse in photovoltaic panels is more complicated. The recovery of silicon is more complex, but recycling technologies continue to develop, aiming to increase recovery efficiency. Currently, about 85% of silicon can be recovered, which after proper cleaning can be reused in the production of new photovoltaic panels.
Other materials, including copper, lead, and plastics, are also recovered, though their percentage share in the panel mass is smaller.

Do photovoltaic panels contain hazardous materials?

With regard to cells made of silicon, which are by far the most widely used on the Luxembourg market, current production techniques do not require the use of any substances that are harmful to the environment.

Thin-film cells use elements such as cadmium or tellurium. The quantities used for the production of related modules are, however, minimal, especially for cells composed of cadmium telluride, known as CdTe. CdTe has low toxicity and the environmental consequences are considered negligible compared to the impact that could be caused by other means of electricity generation.

What is the environmental impact of photovoltaic panels?

The environmental impact is taken into account over the entire life cycle. Thus, environmental effects (such as the impact on climate change, the extraction of minerals, toxicity for human beings, etc.) are taken into consideration during the production and operation of the photovoltaic installation, including the savings made due to the energy produced during its life cycle.

Even if we consider that the production of certain photovoltaic panels requires scarce resources and hazardous materials, the environmental impact throughout their life cycle is less than that caused by the national or European electricity mix. This overall impact can be further reduced by recycling end-of-life panels or by refurbishing used panels for reuse in a second life.

Recycling law of photovoltaic panels in Luxembourg

In Luxembourg according to the law of 9 June 2022 on waste electrical and electronic equipment, the producer is responsible for the collection and processing of photovoltaic panels.

Producer means any natural person or legal entity who manufactures photovoltaic panels in Luxembourg or initially imports them onto the Luxembourg market. Any person established in another Member State or in a third country who, on a professional basis, supplies photovoltaic panels directly to a user in Luxembourg is considered a producer. In practice, in the majority of cases, this is the installer of the photovoltaic plant in Luxembourg.

Possibilities for owners to dispose of their old photovoltaic panels

For photovoltaic panels put on the market before 13/08/2005 :

in case of replacement of the photovoltaic panels, the take back of the old panel is free of charge and must be ensured by the company supplying the new equipment
in case of dismantling of the photovoltaic panel (non-replacement of the panel), the removal by a professional collector is done against payment by the user

For photovoltaic panels placed on the market after 13/08/2005 :

free take-back by the producer who bears the costs of collection and recovery of the photovoltaic panels.

In summary

In summary, the development of photovoltaic panel recycling technologies in Europe and Luxembourg is a key element of the sustainable development strategy, allowing for the recovery of valuable materials, waste reduction, and decreasing the negative environmental impact. Thanks to engagement at the national and EU levels, prospects for the efficient recycling of photovoltaic panels appear promising, significantly impacting the future of solar energy.

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Differences Between Photovoltaic Panels and Solar Collectors

Voltmax — Thu, 07 Apr 2022 17:20:00 +0000

Differences Between Photovoltaic Panels and Solar Collectors – What to Choose?

Solar energy is becoming an increasingly popular power source, leading to growing interest in both photovoltaic panels and solar collectors. Both systems harness solar radiation, but they operate in entirely different ways and serve different purposes. Before making an investment, it’s essential to understand the key differences between these two technologies.

Photovoltaic Panels – How Do They Work and What Are They For?

Photovoltaic panels (PV) are used to generate electricity. This process is based on the photovoltaic effect, which allows the conversion of solar radiation into electrical energy. When sunlight hits photovoltaic cells made of silicon (mono-, polycrystalline, or multicrystalline), photons cause electrons to move, generating an electric current.

Photovoltaic panels are ideal for those who want to reduce their reliance on traditional energy sources. The energy produced by the panels can power household electrical devices, and any surplus energy can be stored in batteries or sold back to the grid.

Key Advantages of Photovoltaic Panels:

Generation of electricity from a free source – the sun.
Ability to power the entire household and electrical devices.
Savings on electricity bills.
Potential to sell excess energy.

Solar Collectors – How Do They Work and What Are They For?

Solar collectors, also known as “solars,” are primarily used for heating domestic water. They work by converting solar radiation into heat, which is absorbed by a liquid (usually a glycol mixture) circulating within the system. This liquid absorbs heat from the absorber – a special plate made of aluminum or copper coated with a layer that absorbs solar radiation (e.g., black chrome, titanium, or silicon oxides). The heated fluid is then transported to a storage tank, where it heats the domestic water.

Solar collectors are perfect for households with a high demand for hot water, such as for daily hygiene needs or heating pool water.

Key Advantages of Solar Collectors:

Efficient heating of domestic water, especially in summer.
Reduced water heating costs.
Simple and proven technology.

Photovoltaic Panels vs Solar Collectors – Differences

Although both photovoltaic panels and solar collectors harness solar energy, they have significant differences.

Feature	Photovoltaic Panels (PV)	Solar Collectors (Solars)
Function	Generation of electricity	Heating domestic water
Technology	Photovoltaic effect (silicon cells)	Conversion of radiation into heat (absorber)
Energy Use	Powering electrical devices	Heating domestic water
Efficiency	Year-round (requires daylight)	Best in sunny months
Energy Storage	Can store energy in batteries	No storage – heats water on the spot
Initial Costs	Higher but potential for energy resale	Lower than PV
Application	Powering the home, charging devices	Heating domestic water

What to Choose – Photovoltaic or Solar Collectors?

The choice between photovoltaic panels and solar collectors largely depends on your needs.

If your primary goal is to generate electricity to power your home, lighting, or charging devices, photovoltaics will be more suitable. Photovoltaic panels can work all year round, even during winter, although efficiency may drop with reduced sunlight.

On the other hand, if your priority is efficient heating of domestic water, especially during the warmer months, solar collectors may be a better option. They are ideal for families with high hot water needs and those looking to reduce water heating costs without requiring large amounts of electricity.

Alternative: Photovoltaics with a Water Heater

More and more people are opting for photovoltaic panels combined with an electric water heater. This configuration allows for the generation of electricity to power the home as well as heating water using an electric boiler. This versatile solution may prove more efficient and flexible than standalone solar collectors, providing greater energy independence.

Conclusion

Both technologies – photovoltaic panels and solar collectors – have their advantages and drawbacks. The choice depends on whether your priority is generating electricity or heating water. It’s also worth considering the combination of photovoltaics with an electric water heater, which allows maximum use of solar energy for various purposes.

Remember, both photovoltaics and solar collectors are investments that can bring long-term savings and contribute to environmental protection by using renewable energy.

Contact us to learn more about our offer. Leave your contact details or use the information in the “Contact” tab.

Still unsure which solar solution is right for you? Contact us today and we’ll help you choose between photovoltaic panels and solar collectors based on your needs

Most common mistakes in photovoltaic installations

Voltmax — Thu, 07 Apr 2022 17:04:10 +0000

What should we pay attention to?

Are you planning to invest in photovoltaics, but you’re not sure which offer to choose? Do you want your installation to be safe and efficient, while also aiming for the lowest possible price? Photovoltaics must be of high quality – otherwise, it won’t be cost-effective or safe. The Luxembourg is characterized by very high levels of sunshine, which is why we have so many orchards and agriculture here. Favorable weather, fertile soil, and abundant sunshine are very good conditions for agriculture, but also for photovoltaic installations. The more sunlight, the faster the return on investment. Before you decide to install photovoltaics, get to know the most common mistakes related to the selection and installation of photovoltaic panels.

Most common mistakes in photovoltaic installations

Photovoltaics in Luxembourg are becoming increasingly popular. There are more and more micro-installations of photovoltaics, which may seem like an ideal situation, but in reality, many systems are poorly executed, and the responsibility for this lies primarily with the “professionals” in the photovoltaic industry, but also partly with the customers seeking excessive savings. So, how can you avoid costly mistakes?

Below, we present the most common mistakes in photovoltaic installations in Luxembourg, which may occur during the design and installation of selected solutions.

Shaded installation location

It is worth knowing that photovoltaics in the city of Luxembourg and surrounding suburban areas are very cost-effective due to the high sunshine levels in our region, and we should wisely use the possibilities provided by the location.

The placement of photovoltaic panels should enable maximum utilization of solar energy. Therefore, the photovoltaic installation is mounted on the southern sides of roofs or on ground structures facing south, where the panels can “collect” the most sunlight and produce more energy. There is no point in installing photovoltaics in poorly sunlit areas, as such an installation will not be efficient and will extend the payback period – reducing the quality and efficiency of the installation overall.

The most common mistakes concern the wrong choice of installation location. Avoid mounting on:

roofs shaded by other buildings or trees
cells can also be shaded by other PV installation elements or building parts, e.g., facades or bay windows.

Remember that shading just 3% of the PV panel’s surface can reduce the efficiency of the photovoltaic installation by up to 25%. However, there is a solution to this issue – choose the appropriate technology that uses power optimizers. This is the only way to effectively combat shading, says an expert from VOLTMAX, a Luxembourg-based company specializing in photovoltaic installations for businesses, individual customers, and agricultural farms.

Choosing a company that uses subcontractors

Choosing a contractor for a PV installation is one of the key issues. The company hired for this task must have experience and a team of qualified employees who constantly improve their skills.

Using an offer from an unknown and untested company may lead to problems later on and could me a mistakes with photovoltaic installation. When assessing the reliability of a contracting company, consider the installation cost estimate and the specification of used components and materials. If the proposed price is lower than the average market prices, there is a suspicion that the company will send subcontractors for the installation, who may not be familiar with the chosen solutions and install them improperly. Another problem is the lack of client awareness among the proposed technological solutions and components. Many representatives may offer components of very poor quality at an inflated price, while praising them. Therefore, the lack of curiosity and involvement of the client in the investment can cause many problems, and as life shows, cost-cutting can be detrimental and lead to long-term costs.

Lack of lightning protection system

A good practice to protect against storms and surge consequences is the installation of lightning protection devices. The need to place them on the roof is considered individually during a meeting with the photovoltaic company’s expert, whose services we decide to use.

Although such situations are very rare, they cannot be excluded. Panels should also be well placed in relation to the lightning protection elements – they must be located in a protected space but with the appropriate insulation gap.

Loose screws

Improper tightening of screws can lead to panels detaching from the roof surface or ground structure and damaging the system.

Any haste in installing photovoltaic installations is very deceptive – even a small oversight can have tragic consequences and cause not only financial losses but also endanger health or life.

Expert VOLTMAX – “From experience, we know situations where errors in photovoltaic installations in Luxembourg due to loose screws could result in a fire because the dislodgement of the screw leads to the failure of originally supported elements, which is not their purpose.”

Incorrectly laid photovoltaic cables

Incorrect cable laying can cause them to wear out; cables laid in a way that rub against each other or other elements can lead to unnecessary malfunctions.

Poorly laid cables can also be exposed to moisture, resulting in a short circuit. The quality of the cables themselves is also very important – the installation must last for many years (25-30 years), and for this to be possible, all even the smallest elements must meet specific requirements. The quality of the cabling used also affects the effectiveness of the generated power, which we will use or pass on to the grid.

Incorrectly connected photovoltaic panels

Next common mistakes is that incorrectly connected photovoltaic panels can result in incorrect operation of the photovoltaic installation or its failure, and in extreme cases, even a fire.

How does it look in VOLTMAX?

Expert VOLTMAX: “You must remember that a condition for the warranty of photovoltaic installations is the correct installation method. So, if the cells are connected incorrectly and get damaged, the complaint may not be accepted. For proper connections, high-quality cables and connectors must be used – relying on cheap substitutes of questionable origin is the shortest path to problems that can be avoided by opting for optimal quality and cost solutions.”

Improper tilt angle of panels

The tilt angle of photovoltaic panels should be chosen according to the specifics of the location where they will be installed. Panels used in photovoltaic installations can be mounted on both steep and flat roofs. In the latter case, a special structure is necessary to lift the cells and enable their proper positioning relative to the incident light.

If the panels have too small or too large a tilt angle, they will not properly utilize solar energy. The greatest power efficiency will be achieved by mounting panels at an angle of 25-36 degrees.

Incorrectly chosen design of the photovoltaic installation

Specialists involved in the creation of the installation design must consider the dimensions and load capacity of the roof, as well as the arrangement of individual installation elements in such a way that the installation is made according to the art and complies with all standards of proper installation while also fitting nicely into the appearance of our building, as the installation should please not only our wallet but also our eyes. A poorly executed project may result in the need for subsequent modifications, which will entail additional costs and delays.

The photovoltaic installation design for a building should be carried out by a person who has construction qualifications for designing electrical and electro-energy devices or a certificate in the field of photovoltaic systems issued by the President of the Office of Technical Inspection.

The installation elements should meet certain technical requirements:

Photovoltaic modules must have efficiency levels of not less than 16%, silicon cells, and mechanical strength of not less than 5,400 Pa.
The inverter should have a transformerless design, be characterized by at least IP65 protection class, and be equipped with convection or fan cooling.

Particularly important is the proper power rating of the installation; too low power will not allow covering the energy demand, and deficiencies will have to be supplemented from the grid, which will result in additional costs and reduced PV installation profitability. Too much power is also a mistake as it will cause unnecessary financial losses associated with the purchase of “stronger” solutions completely unsuited to our needs.

A flawless photovoltaic installation – it’s possible

Can we avoid problems with structural defects in photovoltaic installations? Expert VOLTMAX: “Of course, yes, you just need to meet the following points:” Now you know what is common mistakes in photovoltaic instalations.

The condition is to choose a reliable supplier.
Appropriately assess your needs, capabilities, and risks associated with owning a photovoltaic installation in the Luxembourg with our expert.
At home, when considering a photovoltaic installation contractor, I encourage you to make a appoitment with our expert: +352 691 986 312
Check the subsidies and financial aid programmes

Customers opting for photovoltaics should also consider its insurance – the cost of such a policy is not high, and insurance will cover potential costs not included in standard building insurance.

Want to avoid the most common mistakes in solar projects? Get in touch and let our experts design a flawless photovoltaic installation for your home or business

photovoltaic panels – Voltmax Energy Solutions in Luxembourg

Overpaneling and inverter sizing – how much DC oversizing is smart?

What is overpaneling in a solar PV system?

DC-to-AC ratio explained in simple terms

What is inverter clipping and why it happens

Why overpaneling works in real-world PV performance

Panels rarely reach their STC nameplate power

Lower cost per kWh by adding more solar panels

Why overpaneling boosts real-world performance

When does over-paneling stop being beneficial?

Recommended DC-to-AC ratios for modern PV design

Typical design ranges for residential and small commercial

Annual energy gain vs clipping losses

Is inverter clipping really a problem?

How to decide if overpaneling makes sense for your roof

Checklist for homeowners and PV designers

Questions to ask your installer about overpaneling

FAQ — overpaneling, inverter sizing and clipping

Is it safe to oversize solar panels compared to the inverter?

How much can I overpanel my inverter — what DC/AC ratio is best?

Does overpaneling damage the inverter or affect its warranty?

What is inverter clipping and should I worry about it?

We invite you to our stand at the HOME EXPO

We are with our stand at the HOME EXPO fair, we invite you, your friends and family to participate in the fair and visit us in the Hall.

10 to 13 October 2024 @ LUXEXPO THE BOX

Our advisors offer:

Your free admission: (download free ticket with QR code)

Admission tickets 2024

Missed us at last year’s Home Expo? Book a private consultation today and enjoy the same experience — tailored exclusively for you, with the attention of a true luxury client

Recover and reuse: Recycling of photovoltaic panels

Recycling photovoltaic panels is an increasingly common phenomenon.

Is it possible to recycle photovoltaic panels? If so, which part can be recycled?

Stages of the recycling process

The photovoltaic panel recycling process consists of several stages:

In the process of recycling photovoltaic panels, a range of valuable materials are recovered:

Do photovoltaic panels contain hazardous materials?

What is the environmental impact of photovoltaic panels?

Recycling law of photovoltaic panels in Luxembourg

Possibilities for owners to dispose of their old photovoltaic panels

In summary

Take advantage of a free audit and receive a free quote for your photovoltaic installation.Fill out the form below!

Ready to give your solar panels a second life? We’ll collect your old panels and recycle them for free when installing your new photovoltaic installation

Differences Between Photovoltaic Panels and Solar Collectors

Differences Between Photovoltaic Panels and Solar Collectors – What to Choose? ­­ ­­ ­­ ­­ ­­ ­­ ­­ ­­ ­­ ­­

Photovoltaic Panels – How Do They Work and What Are They For?

Key Advantages of Photovoltaic Panels:

Solar Collectors – How Do They Work and What Are They For?

Key Advantages of Solar Collectors:

Photovoltaic Panels vs Solar Collectors – Differences

What to Choose – Photovoltaic or Solar Collectors?

Alternative: Photovoltaics with a Water Heater

Conclusion

Contact us to learn more about our offer. Leave your contact details or use the information in the “Contact” tab.

Still unsure which solar solution is right for you? Contact us today and we’ll help you choose between photovoltaic panels and solar collectors based on your needs

Most common mistakes in photovoltaic installations

What should we pay attention to?

Most common mistakes in photovoltaic installations

Shaded installation location

Choosing a company that uses subcontractors

Lack of lightning protection system

Loose screws

Incorrectly laid photovoltaic cables

Incorrectly connected photovoltaic panels

Improper tilt angle of panels

Incorrectly chosen design of the photovoltaic installation

A flawless photovoltaic installation – it’s possible

Want to avoid the most common mistakes in solar projects? Get in touch and let our experts design a flawless photovoltaic installation for your home or business

Take advantage of a free audit and receive a free quote for your photovoltaic installation.
Fill out the form below!

Differences Between Photovoltaic Panels and Solar Collectors – What to Choose?