Difference between revisions of "Solar integration"

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<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> Physical installation </h2>
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<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> Solar overview </h2>
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*To ensure proper solar integration functionality, it is essential to begin with the correct physical installation. This involves having a smart energy meter installed in the electric circuit that possesses the necessary communication functionality and is included in our [[Smart energy meters|energy meter list]]. The meter plays a crucial role in detecting negative current flow, indicating when energy consumption is lower than solar generation, and feeding it back into the electrical grid. For effective communication, the charger must be interconnected with the meter.
 
  
*When the meter detects surplus energy, it relays this information to the charger. Based on the charger's internal configurations, it will determine whether to initiate the charging process or not. It is important to note that this process depends on the specific configurations set within the charger.
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Solar integration with electric vehicle (EV) charging stations is an innovative and sustainable approach that combines solar power generation with the charging infrastructure for electric vehicles. Couple examples why this integration is important:  <br>
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*Solar-integrated TeltoCharge can be connected to the local electrical grid, allowing it to draw power from the grid when solar energy production is insufficient or when there is a high demand for charging. This ensures uninterrupted charging availability for EV owners. <br>
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*Solar Power Offset: When solar panels produce excess electricity that is not immediately consumed by TeltoCharge, it can be fed back into the electrical grid. This process, known as net metering or feed-in tariff, allows the solar system owner to earn credits or receive compensation for the surplus energy supplied. <br>
  
 
[[File:Solar integration overview.png|frameless|1200x900px]]  
 
[[File:Solar integration overview.png|frameless|1200x900px]]  
<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> Solar configuration </h2>
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<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> Solar integration components </h2>
 
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Once the charger is properly connected to the electrical grid and interconnected with energy meter, the next step is to configure the settings using the Teltonika Energy app. Below, you will find a comprehensive list of the settings that should be adjusted to achieve solar functionality.
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In order to make '''Solar''' functionality work, these components are included: <br>
 
 
=== General meter settings ===
 
[[File:2023-07-03 07 45 16-Window.png|right|frameless|276x276px]]
 
If you want to enable solar functionality, it is important to correctly configure the general meter settings and dynamic load balancing settings
 
 
 
#'''Energy meter type''': You need to select the type of smart meter (1-phase/3-phase). Please note that you can use a 1-phase charger even if the meter is 3-phase.
 
#'''RS-485 baud rate''': This information can be found in the meter settings accessible through the meter display. If the client cannot locate it, it is recommended to refer to the smart meter manual.
 
#'''RS-485 parity/stop bit''': Similarly, this information can also be found in the meter settings. If the client is unable to find it, it is advisable to check the smart meter manual.<br>
 
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=== Dynamic Load Balancing ===
 
[[File:2023-07-03 07 51 37-Window.png|right|frameless|271x271px]]
 
 
 
#'''Measuring device''': The meter should be selected. For UK chargers, it is possible to choose CT clamps.
 
#'''Energy meter address''': This information can be found in the meter settings accessed through the meter display. If the address cannot be located, it is recommended to consult the smart meter manual.
 
#'''Current update interval''': By default, it is set to 3 seconds. However, there may be cases where the user needs to increase this value. For instance, if there are significant distances between the charger and the smart meter.<br>
 
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1. '''Solar Panels''': Photovoltaic (PV) solar panels are the primary component for generating electricity from sunlight. These panels consist of multiple solar cells that convert sunlight into direct current (DC) electricity. <br>
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2. '''Inverter''': The DC electricity produced by the solar panels needs to be converted into alternating current (AC) electricity, which is compatible with the electrical grid and charging equipment. An inverter is used to perform this conversion. <br>
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3. '''Charge Controller''': A charge controller manages the flow of electricity between the solar panels, battery storage (if present), and the TeltoCharge. It regulates the charging process to optimize energy usage, protect the battery (if used), and ensure safe and efficient charging. <br>
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4. ''Battery Storage (Optional). These batteries store excess solar energy during periods of high generation and supply the stored energy during low or no solar production, ensuring a consistent power supply to the EV charging stations.'' <br>
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5. '''TeltoCharge.''' <br>
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6. '''Electrical Distribution System.''' This involves proper wiring, circuit breakers, and distribution boards to ensure the safe and efficient transfer of electricity to the charging stations. <br>
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7. ''Energy Management System. It may include software algorithms, monitoring systems, and control mechanisms to prioritize charging during peak solar production, balance loads, and manage energy flow between the solar panels, battery storage, and charging stations.'' <br>
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8. '''Grid Connection and Metering.''' Proper metering systems, such as net metering or feed-in tariff meters, may be required to measure the solar energy fed back into the grid or the energy drawn from the grid. <br>
 
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These components work together to create an integrated system that harnesses solar energy to power the '''TeltoCharge'''. The specific configuration and components may vary depending on factors such as the scale of the installation, available space, energy requirements, and desired functionalities. <br>
  
=== Solar EV charging ===
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<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> TeltoCharge available solar modes explained </h2>
[[File:Solar_settings.png|right|frameless|271x271px]]
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#'''ECO+ surplus minimum''' - This setting requires the minimum value of surplus solar energy to be reached in order to initiate a charging session. If the minimum value of surplus energy is not achieved, the charger will remain in "On hold" mode, awaiting additional surplus energy. <br>
 
#'''ECO charging minimum''' - This setting specifies the minimum value required to commence the charging process.
 
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<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> Charging modes </h2>
 
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With TeltoCharger chargers, you can achieve three different solar charging modes, each offering unique benefits for various situations:<br>
 
 
 
*'''Solar only charging profile''' - In this profile, the charging process is initiated solely using green energy. The minimum required value is 6 Amps. If there is less surplus energy available than 6 A, the charger will remain in "On hold" mode.
 
*'''ECO+ charging profile''' - In this profile, the charging process is initiated using a combination of solar energy and grid energy. The user sets the ECO+ surplus minimum value, which determines the minimum surplus energy required to start the charging process. If the set value is less than 6A, the difference in current will be supplemented with grid power.
 
 
 
Example:<br>
 
    ''ECO+ surplus minimum value set to 1 A<br>
 
    0 A (from solar) = charging process is not initiated<br>
 
    1 A (from solar) + 5 A (from grid) = 6 A charging current<br>
 
    5 A (from solar) + 1 A (from grid) = 6 A charging current<br>
 
    10 A (from solar) + 0 A (from grid) = 10 A charging current
 
*'''ECO charging profile''' - In this profile, the charging process is initiated using maximum available solar energy in combination with grid energy. The user sets the ECO charging minimum value, which determines the minimum charging current. This charging current is first covered by the maximum solar energy available and then supplemented with grid energy.
 
 
 
Example:<br>
 
    ''ECO charging minimum value set to 10 A<br>
 
    If 5 A (from solar) + 5 A (from grid) = 10 A charging current<br>
 
    If 9 A (from solar) + 1 A (from grid) = 10 A charging current<br>
 
    If 16 A (from solar) + 0 A (from grid) = 16 A charging current<br>
 
    If 0 A (from solar) + 10 A (from grid) = 10 A charging current
 
 
 
<h2 style="color: #4a4a4a; font-size: 24px; font-weight: bold; margin-bottom: 10px;"> Additional information </h2>
 
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There is additional information that is important to know when using solar integration, specifically regarding timers that dictate the start and stop of the charging process. <br>
 
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If the Solar or ECO+ mode is being utilized and there is a sudden shortage of solar power to charge the electric vehicle, the charger will compensate by drawing charging power from the grid for the following 30 seconds and limiting the maximum current to 6 A until enough solar power is available. If no sufficient solar power is available after 30 seconds, the charger will transition to the "On hold" state and await the availability of additional surplus energy. Once there is sufficient surplus energy, the charger initiates a 2-minute timer during which it verifies the sustained presence of enough solar energy. After the 2-minute interval elapses, the charger proceeds to the charging process. <br>
 
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This mechanism ensures that the charging process is flexible and responsive to variations in solar energy availability. By incorporating timers and checks, the charger optimizes the utilization of solar power while maintaining a reliable and efficient charging experience for electric vehicle owners.
 
 
 
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[[Category: Advanced Topics]]
 

Revision as of 07:58, 6 June 2023

Main Page > TeltoCharge > Advanced Topics > Solar integration

Solar overview

    Solar integration with electric vehicle (EV) charging stations is an innovative and sustainable approach that combines solar power generation with the charging infrastructure for electric vehicles. Couple examples why this integration is important:
    • Solar-integrated TeltoCharge can be connected to the local electrical grid, allowing it to draw power from the grid when solar energy production is insufficient or when there is a high demand for charging. This ensures uninterrupted charging availability for EV owners.
    • Solar Power Offset: When solar panels produce excess electricity that is not immediately consumed by TeltoCharge, it can be fed back into the electrical grid. This process, known as net metering or feed-in tariff, allows the solar system owner to earn credits or receive compensation for the surplus energy supplied.
    Solar integration overview.png

    Solar integration components

      In order to make Solar functionality work, these components are included:

      1. Solar Panels: Photovoltaic (PV) solar panels are the primary component for generating electricity from sunlight. These panels consist of multiple solar cells that convert sunlight into direct current (DC) electricity.
      2. Inverter: The DC electricity produced by the solar panels needs to be converted into alternating current (AC) electricity, which is compatible with the electrical grid and charging equipment. An inverter is used to perform this conversion.
      3. Charge Controller: A charge controller manages the flow of electricity between the solar panels, battery storage (if present), and the TeltoCharge. It regulates the charging process to optimize energy usage, protect the battery (if used), and ensure safe and efficient charging.
      4. Battery Storage (Optional). These batteries store excess solar energy during periods of high generation and supply the stored energy during low or no solar production, ensuring a consistent power supply to the EV charging stations.
      5. TeltoCharge.
      6. Electrical Distribution System. This involves proper wiring, circuit breakers, and distribution boards to ensure the safe and efficient transfer of electricity to the charging stations.
      7. Energy Management System. It may include software algorithms, monitoring systems, and control mechanisms to prioritize charging during peak solar production, balance loads, and manage energy flow between the solar panels, battery storage, and charging stations.
      8. Grid Connection and Metering. Proper metering systems, such as net metering or feed-in tariff meters, may be required to measure the solar energy fed back into the grid or the energy drawn from the grid.

      These components work together to create an integrated system that harnesses solar energy to power the TeltoCharge. The specific configuration and components may vary depending on factors such as the scale of the installation, available space, energy requirements, and desired functionalities.

      TeltoCharge available solar modes explained