1. DETERMINE SOLAR POWER NEEDS
The first thing to do in designing a solar PV system is to determine how much power is used in a day. How to calculate the number of watts per household equipment used per day. By knowing how much power is needed, this will help you to determine the number of solar panels needed, how many capacities of inverter installed and how much battery size to buy.
2. DETERMINE SIZE OF SOLAR PANEL
The second thing is to determine the size of the solar PV panel by looking at how many peak watts each panels has. It aims to see if the power generated by the panel is sufficient to operate the equipment. For example, if a house requires 3kW and a panel has power 250W, then it takes about 12 solar panels to power the house.
3. DETERMINE SIZE OF INVERTER
Then determine the size of the inverter. The input value of an inverter should not be less than the total watt of the equipment. At least the size of an inverter should be 25% to 30% greater than the total watt of the equipment. For residential scale usually require 2-4 kW inverters. Make sure the inverter has been tested for safety and proven quality.
4. DETERMINE THE SOLAR BATTERY
Next is specifying the type and capacity of the solar battery. In the present time, there are two types of batteries for PV systems on the market; lithium battery and lead battery. When discharging, lead battery never discharge more than 80% while lithium battery can discharge almost 100%. So that lithium solar battery are believed to be more effective than lead solar battery. When determining the battery also determine the capacity of the power shield and how long it will take to fully charge the battery.
5. DETERMINE THE SOLAR CHARGE CONTROLLER ON THE BATTERY.
There are two types of solar charge controllers: PWM and MPPT. PWM is used if panels and solar battery produce the same voltage. While MPPT can be used if the voltage between the panel and battery is different.
RatedPower is a platform that allows you to optimize your solar PV designs quickly and efficiently. In the last few months, we have implemented some game-changing improvements, which have significantly reduced the simulation time and improved the structure grouping algorithm. These new parameters will help you ensure your site is filled with structures with the most optimal design configuration.
At RatedPower, our aim has always been to simplify the work of solar PV engineers by automating all the tasks they perform on a daily basis. From the start, our goal was for RatedPower's algorithm to focus on specific aspects of the design of a PV plant.
These include the automatic positioning of structures, roads, power stations, cables, and more. Other important aspects are the calculation of cable cross-sections in accordance with different electrical standards, the energy production calculation, the substation engineering, and the generation of all the necessary documents and drawings related to each design.
This algorithm has always been evolving. We hope to shed light on some of the latest developments that the layout algorithm has experienced and guidance on how to optimize your design.
In this article, you will learn how to define some parameters that will help you optimize your PV plant, such as choosing the type of layout, determining the DC/AC ratio, or sizing your equipment.
So, buckle up and enjoy the ride!
How can a solar developer optimize their PV plant projects at the very early stages? Watch our recorded webinar session, Early-stage PV project optimization: a developer POV, to find out!
You have at your disposal numerous layout parameters that you can adjust in real time to see how they affect the final layout result. Here&#;s how to use these layout parameters to get the most out of them:
First, you can select the type of layout you want among the following options:
Regular blocks: This option defines a rectangular block of structures belonging to one power station and repeats it throughout the layout. This configuration is better for large PV plants with regular area definitions.
Adaptive design: With this option, each power station (PS) can have different sizes (power) and different DC/AC ratios, so the design complies with the global parameters set by the user. This allows for power stations with different shapes that better fit the perimeter and irregularities of the site, resulting in more total installed capacity.
The layout design tab allows you to define the DC/AC ratio. This ratio primarily depends on the PV module, the inverter, and the structure you have chosen. Other parameters, such as the number of modules per string, strings per structure, and structures per inverter, will also influence this ratio.
You can also enable the "Install the maximum peak power" checkbox. By activating this option, all possible structures will be installed in the PV plant, reaching the maximum possible peak power by varying the DC/AC ratio within a maximum of +/-0.15.
Another option to consider when trying to fill in those remaining portions where the chosen inverter cannot fit in, is to utilize a smaller, secondary inverter. When no more power stations can be placed on the site (size-wise), this option will allow you to try to place smaller power stations using the secondary inverter.
To further personalize and optimize your layout design, RatedPower offers several setback options that you can define between different elements within the PV plant. By selecting and adjusting these setbacks, you can fine-tune the layout to achieve the best possible configuration.
Available Area (AA) to fence
Fence to structure
Power Station (PS) to structure
Power Station (PS) to road
Structure to road
Restricted Area (RA) to fence
Restricted Area (RA) to structure
In addition to these, we have introduced new fence strategies that interact with Restricted Areas (RA), providing more options for optimal layout configuration:
Prevent the Fence from Crossing RA
Keep RA Inside the PV Plant
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Let the Fence Cross RA
By carefully selecting the most appropriate fence strategy and setbacks for your Restricted Areas, you can further optimize the overall design of your PV plant, ensuring maximum efficiency and utilization of space.
Optimize your layout by adjusting the orientation or offset of your structures relative to the parcel&#;s borders. You can choose from the following four options:
Standard: Structures follow their usual axis direction.
Rotated: Structures are rotated in blocks.
Offset: The axis of the block is rotated while keeping the structures aligned.
Turning Angle Axis: Structures are rotated while keeping the block aligned.
For linked-row trackers, the last two options are not available.
When your site is too small or contains a lot of irregularities, you can maximize the layout by using smaller structures. This is achieved by reducing the number of modules per row, which can be adjusted using two parameters in RatedPower: the number of modules per string and the number of strings per structure. For tracker systems, you can also opt for smaller structures with fewer modules per row.
In addition, there is also the option to enable partial structures. This feature can be activated from the Equipment tab under Structure.
By enabling partial structures, if you have a configuration with more than one string per structure, the software will allow the placement of structures with fewer strings, even down to one string per structure.
This enables the filling of any remaining spaces that cannot accommodate the original configuration, optimizing the overall layout of your PV plant by ensuring that no usable space is left empty.
RatedPower allows you to optimize the placement of power stations within your PV plant.
Placing the power station inside the DC field will remove one structure from the block connected to it, but will result in shorter distances between structures, generally leading to more total installed capacity.
There are seven road configuration options in RatedPower:
Based on the needs of your PV plant, you can select one of the above options. The two possibilities without perimeter roads install PV modules all the way till the border of your parcel thus allowing you to install more total capacity.
Only Horizontal Roads: Connects all Power Stations in an East-West direction to the access points.
Horizontal and Perimeter Roads: Combines East-West routes with perimeter roads.
Only Vertical Roads: Connects all Power Stations in a North-South direction to the access points.
Vertical and Perimeter Roads: Combines North-South routes with perimeter roads.
Full perimeter roads: Installs roads around the perimeter of the available area, ensuring all Power Stations are connected and accessible from every direction. This option is only available if there are no more than 5 Power Stations within the available area.
Min. perimeter Roads: Focuses on minimizing the length of the perimeter roads, ensuring connectivity with the least amount of road coverage around the available area. This option is only available if your available area contains no more than 5 Power Stations.
No Roads: No internal roads are created within the available area, optimizing the space for maximum structure placement. This is only an option if the available area contains just one Power Station, which will be placed as close as possible to the AC point within the area.
Here, you can choose between two options:
This parameter lets you choose between linear uniform positioning or adapting structures to the parcel&#;s border. Border adaptation can increase total capacity but may complicate construction. The choice between horizontal or vertical roads will also influence this alignment, with border adaptation taking effect based on the direction of the roads relative to the structures' axes.
As discussed above, several relevant design configurations have been developed which enable you to tweak your design to perfection! Another parameter to consider is the pitch distance, which influences not only the ground coverage ratio but also the shading losses. For even more tips, check out our blog about the tilt angle for fixed structures for higher system efficiency.
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