How to size photovoltaic systems for Group A?

Updated October 15, 2025

Do you know what precautions you should take when designing photovoltaic systems for Group A consumers? Unlike Group B, sizing for this profile requires attention to variables such as contracted demand, peak and off-peak consumption, as well as specific rules. ANEEL.

In this article, we explain in a practical way how solar system sizing works for Group A, addressing the regulatory, operational, and tariff criteria that directly influence the technical and economic viability of the photovoltaic plant.

Who are Group A consumers?

Group A consumers are those with medium-voltage power supplies (above 2,3 kV). This category includes medium- and large-scale consumers such as industries, shopping malls, universities, supermarkets, and large rural properties, among others.

Group A customers have their bill divided into two parts, as they pay for the energy consumed (variable value depending on consumption) and also pay for the contracted demand (fixed value, depending on the contract).

Energy tariffs and contracted demand may vary according to the period of the day in which consumption or demand occurred, the so-called tariff stations (peak hours and off-peak hours).

To learn more about contracted demand, peak hours and off-peak hours, read the article Reading and Interpreting Energy Invoices.

Many people confuse contracted demand with consumed energy. Therefore, it is important to remember that contracted demand is power (measured in kW).

This power is related to the consumer's installed load, that is, to the quantity and power of the equipment that the consumer has. On the other hand, the energy consumed is measured in kWh. Energy is associated with the consumer's monthly consumption.

The Group A consumer pays for both things, for the right to have a contracted demand (kW), which guarantees that all of their equipment and machines can be turned on, in addition to paying for the energy consumed monthly, which is a variable amount.

What is contracted demand?

An important factor when sizing the photovoltaic system is the contracted demand, since the AC power of the system (sum of the maximum AC power of the inverters) is limited to this factor.

For example, a consumer with a contracted demand of 200 kW can install a solar system with a maximum AC power of 200 kW. If the project's AC power exceeds the contracted demand, the consumer must request an increase in this demand from the energy provider.

This increase request must occur before installing the photovoltaic system. Only after the concessionaire responds to the increase in demand can the consumer be sure whether they will be able to install the desired photovoltaic system.

In some cases, increased demand is denied by the concessionaire for technical reasons. In many cases, the increase in demand is accompanied by the replacement of the transformer and the renovation of the customer's power cabinet, which generates additional costs for the photovoltaic project.

A consumer with a contracted demand of 200 kW, for example, who now plans to connect a photovoltaic system with an AC power of 250 kW, must in this case request an increase in contracted demand to at least 250 kW.

It should be noted that the consumer pays for the demand. Normally the return from the photovoltaic system compensates for the additional cost of the increase in contracted demand.

The increase in contracted demand is conditioned on the physical structure of the concessionaire and also the consumer, especially the power of the transformer(s) connecting to the distribution network.

For example, a consumer who has a 225 kVA transformer cannot claim a contracted demand of 250 kW, as their transformer would not support 250 kW of active power.

He must request the concessionaire for the availability of power for the injection of energy due to the installation of the photovoltaic system.

In this case, as the power request is for energy generation, the generation demand contracting (TUSG) is requested, which according to Law 14.300/2022 will be the difference between the demand already contracted for the load, which is 225kW, and the demand required for generation, which is 250kW, that is, the TUSDg for this case will be 25kW.

Availability of physical space

Another factor that can limit installation capacity is the available area for panel installation. This analysis involves comparing the customer's available area (rooftop or ground) with the area required for panel installation, taking into account the type of mounting structures and the spacing between panel rows, which is necessary to allow for maintenance of the photovoltaic system.

In the case of ground-based installations, the corridor area (space between rows of panels), the area of ​​the streets surrounding the solar plant, and the area occupied by electrical centers and inverters must also be taken into account. Below, we'll look at some examples of SFV sizing for Group A consumers.

Sizing for full energy compensation without increasing contracted demand

We will take into consideration a consumer located in the CPFL Paulista concession area, located in Campinas (SP), with the following energy bill.

We have the following information obtained from the invoice, as shown in the previous figure:

• Tariff type: Green seasonal time [1];
• TE Ponta tariff: R$ 0,530 [2];
• TE Fora Ponta Tariff: R$ 0,337 [3];
• Contracted Demand: 700 kW [4];
• Average Consumption Tip: 4.912 kWh [5];
• Average off-peak consumption: 47.782 kWh [6].

Average irradiance in Campinas, used in sizing the PV system: 4,91 kWh/m² per day (value extracted from the database available at http://www.cresesb.cepel.br/index.php#data).

Using the data above, we can calculate the power required to meet the total consumption of this customer:

DC power of the PV system = Required generation / (Irradiance x (1 – Losses)

In the equation above we have the following definitions:

• DC Power: Power of the PV system at the output of the inverters (kW);
• Required generation: amount of energy that the customer needs to generate monthly (kWh per month). This value is the average of monthly consumption extracted from the customer's electricity bill, with the application of the correction factor that takes into account peak and off-peak times;
• Irradiance: value of available solar energy, obtained from a database or solarimetric map (kWh/m² per day);
• Losses: losses involved in the system, normally around 15% (thermal losses, inverter efficiency losses, etc.).

A required generation will be equal to the average monthly consumption, taking into account the correction factor (FC) for compensation during peak hours:

FC = TE Tipa / TE Fora Ponta = 0,530 / 0,337 = 1,573

 Thus, we can determine the required generation:

Required generation = Average Off-Tip Consumption + (FC x Average On-Tip Consumption)

In the example considered we have:

Required generation = 47782 + (1,573 x 4912) = 55509 kWh/month

For calculation purposes, we transform the necessary generation, expressed here on a monthly time basis, to a daily time basis, simply dividing this value by the 30 days of a month.

Returning to the initial equation, considering system losses of 15% and substituting the values, we find the necessary power:

PV system DC power = 1850 / [ 4,91 x (1 – 0,15) ] = 443,27 kWp

The DC power value calculated above should be adjusted according to the power of the photovoltaic panels chosen to make up the system. For example, we can use 660 Wp panels, which allows us to use 740 photovoltaic modules, with a total power of 444 kWp.

The power of photovoltaic panels used in the system is also called the DC power of the system (direct current power) or peak power of the PV system.

We also need to define the AC power of the PV system, which is the total power at the outputs of the inverters used in the system. The total power output of the inverter inverters can be calculated using a factor overload 25% (typical value):

PV system AC power = PV system DC power / 1,25

In the example considered we have:

PV system AC power = 355,2 kW

Similarly to the adjustment made to DC power, we make the same adjustment to AC power. Considering a 125kW inverter, for example, we can use three inverters, giving us a power output of 375kW.

As we saw previously, the maximum power of the photovoltaic system is limited by the contracted demand. Therefore, we compare the system's AC power (375 kW) with the contracted demand (700 kW). In this case, we see that the system's AC power is lower than the contracted demand, and installation is possible without any changes in this regard. It is also important to verify whether the client has available land to install the proposed photovoltaic system.

Sizing for full energy compensation with increased contracted demand

Let's now size the system whose energy bill is seen below, from a customer who is also located in the region of Campinas (SP).

We have the following information:

• Tariff type: Green seasonal time;
• TE Ponta tariff: R$ 0,560;
• TE Fora Ponta Tariff: R$ 0,362;
• Contracted Demand: 200 kW;
• Average Consumption Tip: 8.500 kWh;
• Average off-peak consumption: 70.000 kWh.

Once again we have the average irradiance in Campinas equal to 4,91 kWh/m² per day (extracted from the database http://www.cresesb.cepel.br/index.php#data).

With all this information, simply apply the same equations presented in the previous case and we will have the following configuration:

FC = TE tip / TE outside the tip = 0,560 / 0,362 = 1,547

Required generation = 70000 + (1,547 x 8500) = 83150 kWh/month

Let's consider system losses of 15% once again. Just for didactic reasons and to practice in a different way, we will use a monthly time base instead of the daily one that was used in the previous calculation. To do this, simply multiply the daily irradiance by 4,91 kWh/m² by 30, finding 147,3 kWh/m² a month.

PV system DC power = 83150 / [ 147,3 x (1 – 0,15) ] = 664,11 kWp

Once again, we'll use 600 Wp panels and adjust the DC (peak) power of the solar panel according to the number of panels needed. This way, we could use 1.110 photovoltaic modules, with a total power output of 666 kWp.

Now that we know the DC power (peak power value of the solar panels, kWp) let's calculate the AC power of the photovoltaic system (output power of the inverters):

AC power of the PV system = DC power of the PV system / 1,25 = 666 / 1,25 = 533 kWp

We will use the same 125kW inverters used in the previous example, which allows us to use 5 inverters, having a power of 625kW. In this case study, we see that the AC power of the PV system (625kW) is much higher than the contracted demand (200kW).

This installation will only be possible if the contracted generation demand (TUSDg) is requested to be made available for at least 540 kW. In this case, a load increase will likely be necessary.

After sizing the PV system according to the required generation, as we have done so far, it must also be checked whether the client has an area available to install the proposed photovoltaic system.

Sizing according to the limit of contracted demand

When the customer does not receive authorization from the concessionaire to increase demand or when the customer does not want to increase the load (changing the transformer and readjusting the input standard), an alternative is to size the system within the limit of the existing contracted demand.

In this case, we do the calculation in reverse, starting with AC power. The maximum AC power will be equal to 200 kW, for example (current contracted customer demand), and the DC power will be given by:

PV system DC power = PV system AC power x 1,25 = 225 kWp

Obviously, with a lower power, the system will generate less energy, which is calculated as follows:

 Generation = DC power of the PV system x Irradiance x (1 – Losses)

In this example we will have:

Generation = 28171 kWh/month

It is worth remembering that the FC (correction factor) for compensation at peak times depends solely and exclusively on the TE's (peak and off-peak), and not on the full fares (full fares are made up of TE's and TUSD's.

If the TE and TUSD are not clearly listed on the invoice, it is necessary to find the TE values ​​in the tariff processes of the ANEEL clicking here.

Conclusion

Sizing photovoltaic systems for Group A involves much more than simply calculating generation based on consumption. It's necessary to consider contracted demand, peak times, differentiated tariffs, and the technical and regulatory requirements defined by ANEEL.

Successful projects in this segment require in-depth knowledge and detailed planning. Therefore, we recommend that you continue specializing in this subject.

To deepen your knowledge about sizing and optimization strategies for photovoltaic systems, consider investing in solar energy courses and training. These programs provide valuable insights into design and operation best practices, helping you make the most of your system within existing constraints.

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