TMCS01-SUPER CAPACITOR
This comprehensive product specification outlines the superior performance and precise test methods of our product, serving as the foundation for robust technical validation.
- Backup Power Applications: Ideal for RAM, detonators, car recorders, and smart devices. meters, vacuum switches, digital cameras, and motor drives.
Energy Storage Solutions: Perfect for intelligent metering devices, UPS systems, security equipment, communication tools, flashlights, water meters, gas meters, taillights, and various small appliances.High Current Operations: Suitable for electrified railways, smart grid control, hybrid vehicles, and wireless transmission systems.High-Power Support: An excellent choice for wind power units, locomotive starts, ignition systems, electric cars, and more.
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- (Standard Test Conditions):
The standard test conditions for this specification include a standard atmospheric pressure, a temperature of 25°C, and relative humidity below 60%.
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- (TestBasis):
QC/T 741-2014
QC/T 741-2014: Vehicle Super Capacitor Standards
Q/GDW 11845-2018
Q/GDW 11845-2018: Technical Guidelines for Supercapacitors in Electric Energy Metering Equipment
DL/T 1652-2016
DL/T 1652-2016: Technical Specifications for Supercapacitors in Electric Energy Metering Equipment
IEC62391-1-2006
This product showcases a sleek cylindrical capacitor design. Inside, it features a winding structure where positive and negative electrode sheets are separated by a diaphragm and immersed in electrolyte components. The aluminum shell is securely sealed with a rubber plug, ensuring reliability. The lead-out method places the lead-out pole conveniently on the same side of the product.
Series Super Capacitor
Applications
- Applicable to Cylindrical Super Capacitors
.Standard Test Conditions
- Samples are typically tested under standard atmospheric pressure conditions, with a temperature range of 15 ~ 35 ºC and relative humidity of 25% ~ 75%. Samples should be stabilized for over 1 hour at the testing temperature. This specification's test conditions are standardized at atmospheric pressure, a temperature of 25 ± 1 ºC, and relative humidity of 60-15%.
.Specifications
- Type: TMCS01-5FZ5.5VB
- Capacitance: 5F
- Capacitance Tolerance: -20% ~ +80%
- Rated Working Voltage: 5.5V
- Nominal Resistance: AC Resistance: 40mΩ
DC Resistance: 60mΩ
- Working Temperature: -25 ~ 70 ºC
- Storage Temperature: -40 ~ 85 ºC
- Cycle Life: The product boasts a standard charge and discharge cycle of 100,000 iterations.Performance Metrics: |△C/C|≤30%, ESR ≤ 4 times initial value at 25 ºC.
.Test Methods
- Capacity Test Methods (Constant Exile Electrical Method)
- Switch S is transitioned to the constant current/constant voltage source, allowing a current of 10 mA/F for precise constant current capacitor charging under test conditions.
- Measure the capacitor's rated voltage performance by charging it with a constant voltage, UR, and allowing it to stabilize for 30 minutes under test conditions.
- After a consistent 30-minute charge at constant voltage, initiate the switch to the S constant exile electric device, applying a steady current of 10 mA/F. Refer to figure 2 for guidance. The measurement involves observing the voltage decline from levels U1 to U2 and recording time intervals t1 and t2, dependent on capacitor capacity.
Note: C: Represents capacity measured in farads (F).
I: Discharge current measured in amperes (A). T1: Time taken to discharge to voltage U1, measured in seconds (s).
T2: Duration to discharge down to voltage U2, measured in seconds (s). U1: The starting voltage (V) for measurement.
U2: The voltage mark where measurement concludes (V).
- Method of Testing Internal Resistance
2.1 Method for Calculating DC Impedance
Note: RAC: Represents AC resistance in ohms (Ω). U: The root mean square (rms) value of AC voltage, measured in volts (V r.m.s).
I: The effective rms value of the alternating current, measured in amperes (A r.m.s).
- Measurement of Leakage Current
- Before testing, ensure the super capacitor is fully discharged, typically for a duration exceeding 1 hour, to accurately measure leakage current.
- Apply the rated voltage UR across both capacitor terminals for precise measurements.
- Once charged to the rated voltage UR, measure the super capacitor's performance over intervals at 30 min, 12 h, 24 h, and 72 h, focusing on series UV protection across the resistor voltage.
Derive leakage current through meticulous calculation:
Note: LC: Denotes the leakage current, measured in milliamperes (mA).
UV: Voltage across the series resistance on both terminals, measured in volts (V).
R: Series protective resistance, typically maintained below 1000 ohms (Ω).
- Dimension (Unit :mm)
Note: The diagram provided is purely schematic. The actual product specifications take precedence.
Size
( A×F×B) ±1 |
Pin distance
(p)±0.5 |
Pin diameter
(Φd)±0.1 |
Pin length (C max) |
| 25.5×13×23 |
17.8 |
0.6 |
30 |
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