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- Wirelessly connects nets on schematic. Used to organize schematics and separate functional blocks. To wirelessly connect net portals, give them same designator. #portaljharwinbarrozo43.0M
- Wirelessly connects power nets on schematic. Identical to the net portal, but with a power symbol. Used to organize schematics and separate functional blocks. To wirelessly connect power net portals, give them the same designator. #portal #powerjharwinbarrozo11.4M
- A generic fixed resistor for rapid developing circuit topology. Save precious design time by seamlessly add more information to this part (value, footprint, etc.) as it becomes available. Standard resistor values: 1.0Ω 10Ω 100Ω 1.0kΩ 10kΩ 100kΩ 1.0MΩ 1.1Ω 11Ω 110Ω 1.1kΩ 11kΩ 110kΩ 1.1MΩ 1.2Ω 12Ω 120Ω 1.2kΩ 12kΩ 120kΩ 1.2MΩ 1.3Ω 13Ω 130Ω 1.3kΩ 13kΩ 130kΩ 1.3MΩ 1.5Ω 15Ω 150Ω 1.5kΩ 15kΩ 150kΩ 1.5MΩ 1.6Ω 16Ω 160Ω 1.6kΩ 16kΩ 160kΩ 1.6MΩ 1.8Ω 18Ω 180Ω 1.8KΩ 18kΩ 180kΩ 1.8MΩ 2.0Ω 20Ω 200Ω 2.0kΩ 20kΩ 200kΩ 2.0MΩ 2.2Ω 22Ω 220Ω 2.2kΩ 22kΩ 220kΩ 2.2MΩ 2.4Ω 24Ω 240Ω 2.4kΩ 24kΩ 240kΩ 2.4MΩ 2.7Ω 27Ω 270Ω 2.7kΩ 27kΩ 270kΩ 2.7MΩ 3.0Ω 30Ω 300Ω 3.0KΩ 30KΩ 300KΩ 3.0MΩ 3.3Ω 33Ω 330Ω 3.3kΩ 33kΩ 330kΩ 3.3MΩ 3.6Ω 36Ω 360Ω 3.6kΩ 36kΩ 360kΩ 3.6MΩ 3.9Ω 39Ω 390Ω 3.9kΩ 39kΩ 390kΩ 3.9MΩ 4.3Ω 43Ω 430Ω 4.3kΩ 43KΩ 430KΩ 4.3MΩ 4.7Ω 47Ω 470Ω 4.7kΩ 47kΩ 470kΩ 4.7MΩ 5.1Ω 51Ω 510Ω 5.1kΩ 51kΩ 510kΩ 5.1MΩ 5.6Ω 56Ω 560Ω 5.6kΩ 56kΩ 560kΩ 5.6MΩ 6.2Ω 62Ω 620Ω 6.2kΩ 62KΩ 620KΩ 6.2MΩ 6.8Ω 68Ω 680Ω 6.8kΩ 68kΩ 680kΩ 6.8MΩ 7.5Ω 75Ω 750Ω 7.5kΩ 75kΩ 750kΩ 7.5MΩ 8.2Ω 82Ω 820Ω 8.2kΩ 82kΩ 820kΩ 8.2MΩ 9.1Ω 91Ω 910Ω 9.1kΩ 91kΩ 910kΩ 9.1MΩ #generics #CommonPartsLibraryjharwinbarrozo1.5M
- A generic fixed capacitor ideal for rapid circuit topology development. You can choose between polarized and non-polarized types, its symbol and the footprint will automatically adapt based on your selection. Supported options include standard SMD sizes for ceramic capacitors (e.g., 0402, 0603, 0805), SMD sizes for aluminum electrolytic capacitors, and through-hole footprints for polarized capacitors. Save precious design time by seamlessly add more information to this part (value, footprint, etc.) as it becomes available. Standard capacitor values: 1.0pF 10pF 100pF 1000pF 0.01uF 0.1uF 1.0uF 10uF 100uF 1000uF 10,000uF 1.1pF 11pF 110pF 1100pF 1.2pF 12pF 120pF 1200pF 1.3pF 13pF 130pF 1300pF 1.5pF 15pF 150pF 1500pF 0.015uF 0.15uF 1.5uF 15uF 150uF 1500uF 1.6pF 16pF 160pF 1600pF 1.8pF 18pF 180pF 1800pF 2.0pF 20pF 200pF 2000pF 2.2pF 22pF 20pF 2200pF 0.022uF 0.22uF 2.2uF 22uF 220uF 2200uF 2.4pF 24pF 240pF 2400pF 2.7pF 27pF 270pF 2700pF 3.0pF 30pF 300pF 3000pF 3.3pF 33pF 330pF 3300pF 0.033uF 0.33uF 3.3uF 33uF 330uF 3300uF 3.6pF 36pF 360pF 3600pF 3.9pF 39pF 390pF 3900pF 4.3pF 43pF 430pF 4300pF 4.7pF 47pF 470pF 4700pF 0.047uF 0.47uF 4.7uF 47uF 470uF 4700uF 5.1pF 51pF 510pF 5100pF 5.6pF 56pF 560pF 5600pF 6.2pF 62pF 620pF 6200pF 6.8pF 68pF 680pF 6800pF 0.068uF 0.68uF 6.8uF 68uF 680uF 6800uF 7.5pF 75pF 750pF 7500pF 8.2pF 82pF 820pF 8200pF 9.1pF 91pF 910pF 9100pF #generics #CommonPartsLibraryjharwinbarrozo1.5M
- A generic fixed inductor for rapid developing circuit topology. *You can now change the footprint and 3D model at the top level anytime you want. This is the power of #genericsjharwinbarrozo15.5k
- An electrical connector acting as reusable interface to a conductor and creating a point where external circuits can be connected.Terminal
- 47 kOhms ±5% 0.125W, 1/8W Chip Resistor 0805 (2012 Metric) Automotive AEC-Q200 Thick Film #forLedBlinkjharwinbarrozo1.2M
- 10uF Capacitor Aluminum Polymer 20% 16V SMD 5x5.3mm #forLedBlink #commonpartslibrary #capacitor #aluminumpolymer #radialcanjharwinbarrozo1.2M
- Yellow 595nm LED Indication - Discrete 1.7V 1206 (3216 Metric) #forLedBlinkjharwinbarrozo1.1M
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adithyaps
copilot
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Solar Panels: As you've mentioned, you're using two solar panels with the following specifications:
- Maximum Power: 50Wp each
- Maximum Power Voltage: 20V
- Maximum Power Current: 2.5A
- Connecting the solar panels in parallel will theoretically double the current output to 5A while maintaining the same voltage.
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Supercapacitors: You plan to use 9 supercapacitor cells connected in series.
- Individual rating: 500F, 3V
- Series configuration: Results in a total voltage of 27V (3V * 9) and a capacitance value reduced due to series connection. The total capacitance can be calculated using the formula Ctotal=nC where (C) is the capacitance of one supercapacitor and (n) is the number of supercapacitors in series. Therefore, Ctotal=9500F≈55.56F.
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Charge Controller with MPPT (Maximum Power Point Tracking): This is crucial for optimizing the power drawn from the solar panels.
- Specification: Must support input from the solar panels and provide proper charging profiles for both the supercapacitors and the battery.
- Recommendation: A charge controller that can handle at least 20V and 5A from the solar panels is required. Additionally, it should feature MPPT for efficiency and programmable outputs for supercapacitor and battery charging.
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DC-DC Converters:
- Buck-Boost Converter for charging the supercapacitors: Since your supercapacitors are in series for a total of 27V and the solar panel outputs 20V, you'll need a buck-boost converter to step up the voltage when charging the supercapacitors. Ensure that it can handle the input from the solar panels and the required charging voltage for the supercapacitors.
- Buck Converter for charging the battery: To ensure that the 24V battery is charged correctly from the higher voltage of the supercapacitors, a buck converter is required.
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Diodes: These will be used for directional control of current, preventing backflow into the solar panels and between the supercapacitors and the battery.
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Voltage and Current Sensing Circuits: For monitoring the charge states of both the supercapacitors and the battery. These circuits will provide feedback to the control system to switch between charging modes.
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Control System: A microcontroller or dedicated control IC that can monitor solar intensity via voltage and current sensing circuits and manage the charging of supercapacitors or the direct charging of the battery based on predefined conditions.
Ratings & Models (Estimations and Assumptions)- Buck-Boost Converter: Considering your use case, look for a model that can support inputs up to 25V and provide adjustable output up to 30V with a minimum current capacity of 5A. A specific model would depend on the availability from suppliers but consider devices similar to the LM25116 or any suitable integrated buck-boost controller capable of handling the specifications.
- Buck Converter for Battery Charging: Needs to support up to 30V input (due to supercapacitors) and output 24V with current up to 5A. A model such as the LM2596 could be appropriate, given its wide input range and adjustable output voltage.
- Control System (Microcontroller): A model like the Arduino Due or STM32F4 series could be suitable, given their Analog-to-Digital Converter (ADC) capabilities and processing power for real-time adjustments and monitoring.
Additional Components- Fuses and Protection Circuits: Essential for safeguarding against over-current scenarios.
- Heat Sinks: For the DC-DC converters, given the power levels involved.
- Power Resistors: For initial charging circuit calibration and safety tests.
Noteadithyaps
copilot
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Solar Panels: Two 50Wp, 20V solar panels, to be connected in parallel. This configuration doubles the current output while maintaining the same voltage, effectively giving you 100Wp at 20V with a maximum current of 5A.
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Supercapacitors: Ten 500F, 2.7V supercapacitor cells, to be connected in series. This will give you a supercapacitor bank with a total capacity of 50F at 27V, which suits the charging voltage margins for your 24V battery.
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Charge Controller: A solar charge controller optimized for supercapacitor charging. This controller should support variable charging rates and be capable of handling the energy flow from the solar panels to the supercapacitors and the bicycle battery, regulating the process based on the intensity of sunlight.
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DC-DC Converters:
- Buck-Boost Converter for Supercapacitors: To manage the charging of the supercapacitors from the solar panels, accommodating the variance in voltage levels.
- Step-down (Buck) Converter for Battery Charging: To safely step down the voltage from the supercapacitor bank or solar panels directly to the appropriate charging voltage for the 24V battery.
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Switching Circuitry: For controlling whether the charge flows from the solar panels to the battery directly or first to the supercapacitors, based on the intensity of sunlight. This can be managed by smart relays or MOSFETs governed by a microcontroller or a dedicated control unit.
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Protection Circuitry:
- Overcharge and Deep Discharge Protection for Supercapacitors: To prevent damage to the supercapacitors.
- Battery Management System (BMS): For the lithium battery to ensure safe charging, discharging, and overall battery health.
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Sensors: Light intensity sensor to measure the sunlight intensity, which will decide the charging path—either direct to battery or via supercapacitors.
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Microcontroller Unit (MCU): To read sensor inputs and control the switching circuitry based on programmed logic for sunlight intensity, ensuring the optimal charging path is selected.
High-Level Circuit Approach: