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Specifications
Lifetime:
3000hrs@105℃
Capacitance:
100uF
Height - Seated (Max):
12mm
Voltage Rating:
63V
Pin Spacing:
3.5mm
Diameter:
8mm
Tolerance:
±20%
Mfr. Part #:
ECLF0812101M063P00
Package:
Through Hole,D8xL12mm
Key Attributes
Model Number:
ECLF0812101M063P00
Product Description
Product Overview
This document provides guidelines for the proper use and handling of Aluminum Electrolytic Capacitors to ensure optimal performance and extended lifespan. It covers essential considerations such as polarity, voltage ratings, ripple current, operating temperature, frequency, storage, and soldering.
Product Attributes
- Brand: TOPAZCON
- Origin: China
- Manufacturer: GuangDong TOPAZ Electronic Technology Co., Ltd.
Technical Specifications
| Item | Description | Details |
| Polarity | DC electrolytic capacitors are polarized. Ensure correct polarity to prevent short circuits or damage. Use bipolar capacitors for uncertain polarity. Not for AC applications. | DC electrolytic capacitors are polarized. Use bipolar capacitors when polarity is not determined or unknown. DC electrolytic capacitors cannot be used for AC application. |
| Bipolar Capacitors | Used in pulse and polarity reverse circuits. Not suitable for pure AC or high ripple current. | Used only in pulse circuits as well as polarity reverse circuits. Not applicable in pure AC or high ripple current. |
| Voltage | Do not exceed rated voltage. Recommended working voltage is 70-80% of rated voltage for extended life. | Exceeding rated voltage increases leakage current and may damage the capacitor. Recommended working voltage: 70-80% of rated voltage. |
| Ripple Current | Do not exceed permissible ripple current. Exceeding limits causes heating, capacitance reduction, and damage. Generally, do not exceed 80% of rated current. | Excessive ripple current causes capacitor heating, capacitance reduction, and damage. Ripple current should not exceed allowable level, generally not more than 80% of rated current. |
| Charge/Discharge Circuits | Use specially designed capacitors for circuits with rapid charge/discharge cycles to prevent damage, capacitance decrease, and heat rise. | Capacitors may be damaged in circuits subjected to rapid charge and discharge cycles, leading to shortened life due to capacitance decrease and heat rise. Use special capacitors for these applications. |
| Operating Temperature | Capacitor characteristics vary with temperature. Lower temperatures ensure longer life. | Capacitance and leakage current increase at higher temperatures, while tg decreases. At lower temperatures, capacitance and leakage current decrease, and tg increases. Usage at lower temperatures ensures longer life. |
| Temperature & Life Relationship | Life is related to operating temperature. Reducing temperature by 10 can double the lifespan at rated temperature. | Generally, if the used temperature is reduced by 10, life is prolonged twice at rated temperature. Formula provided for calculation. |
| Operating Frequency | Capacitance is typically measured at 100Hz or 120Hz. Capacitance decreases and tg increases with higher frequencies, leading to increased ambient temperature. | Capacitance decreases and tg increases as applied frequency becomes higher, whereas the ambient temperature becomes higher. |
| Long-Term Storage | Capacitors stored for extended periods may experience increased leakage current and reduced withstand voltage. Treat before use by gradually applying rated DC voltage. | Long periods of storage tend to increase leakage current and decrease withstand voltage. Treat by gradually applying DC voltage to rated voltage before use. |
| Case Insulation | The capacitor case is connected to the cathode terminal via electrolyte. Insulate at the mounting point if case insulation is required. | Capacitor's case and cathode terminal connect through the electrolyte. Insulation must be at the capacitor's mounting point if the case is to be completely insulated. |
| Force on Terminals/Leads | Avoid applying excessive force to terminals and leads to prevent breakage, separation, and internal connection failure. | Excessive force may cause leads to break or terminals to separate, leading to internal contact failure. |
| Bending Leads | When bending leads for horizontal mounting, maintain a 2mm safety distance from the capacitor body to prevent internal structural damage. | Bending feet should maintain a 2mm safe spacing from the capacitor body to prevent internal structural damage. |
| Circuit Board Cleaning | Use recommended solvents (Methanol, Isopropanol, Ethanol, etc.) for cleaning. Avoid halogenated or similar solvents (trichloroethylene, xylene, acetone) to protect the capacitor's sleeve, marking, and sealing materials. | Do not use halogenated or similar solvents (trichloroethylene, xylene, acetone) for cleaning. Recommended cleaning solvents: Methanol, isopropanol, ethanol, isobutanol, petroleum ether, propanol, and/or commercial detergents. |
| Soldering | Maintain distance between soldering iron and plastic sleeve. For solder dipping, keep temperature within 260 and duration under 10 seconds to prevent damage. | Soldering irons should be kept away from vinyl insulated sleeves. Recommended solder bath temperature: within 260 for no more than 10 seconds. |
| Hole Layout on PCB | Ensure mounting hole spacing equals lead spacing to avoid stress on leads, short circuits, and damage. Consider hole layout to prevent solder splashing onto the sleeve. | Space position holes equally to the space between lead wires. Incorrect spacing can cause stress on leads, short circuits, and damage. Consider hole layout to prevent solder splashing onto the vinyl sleeve. |
2304140030_Guangdong-TOPAZ-Elec-Tech-ECLF0812101M063P00_C156587.pdf
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