Allicdata Part #: | T86C105M050EBSL-ND |
Manufacturer Part#: |
T86C105M050EBSL |
Price: | $ 0.00 |
Product Category: | Capacitors |
Manufacturer: | Vishay Sprague |
Short Description: | CAP TANT 1UF 50V 20% 2312 |
More Detail: | 1µF Molded Tantalum Capacitors 50V 2312 (6032 Metr... |
DataSheet: | T86C105M050EBSL Datasheet/PDF |
Quantity: | 1000 |
Moisture Sensitivity Level (MSL): | 1 (Unlimited) |
Lead Free Status / RoHS Status: | Lead free / RoHS non-compliant |
1 +: | 0.00000 |
Operating Temperature: | -55°C ~ 125°C |
Failure Rate: | -- |
Features: | Fail Safe with Built-in Fuse |
Ratings: | COTS |
Manufacturer Size Code: | C |
Lead Spacing: | -- |
Height - Seated (Max): | 0.110" (2.80mm) |
Size / Dimension: | 0.236" L x 0.126" W (6.00mm x 3.20mm) |
Package / Case: | 2312 (6032 Metric) |
Mounting Type: | Surface Mount |
Lifetime @ Temp.: | -- |
Series: | TANTAMOUNT®, T86 |
ESR (Equivalent Series Resistance): | 2.7 Ohm |
Type: | Molded |
Voltage - Rated: | 50V |
Tolerance: | ±20% |
Capacitance: | 1µF |
Moisture Sensitivity Level (MSL): | -- |
Part Status: | Obsolete |
Lead Free Status / RoHS Status: | -- |
Packaging: | Tape & Reel (TR) |
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Tantalum capacitors are essential elements of all electronic circuits, offering greater power and speed for a given size. T86C105M050EBSL is a hybrid polymeric aluminum electrolytic capacitor mainly used for filtering. This capacitor is able to provide a large capacity at low leakage current, making it ideal for long-term operation of devices.
Application Field
T86C105M050EBSL capacitors are widely used in many applications such as communication systems, industrial electronics systems, consumer electronics, and automotive systems. They are commonly used in high performance applications that require a large capacitance with low cost. Additionally, these capacitors are also used for current limiting, smoothing, and RF decoupling applications.
Working Principle
T86C105M050EBSL capacitors are based on a hybrid polymeric aluminum electrolytic design. This type of capacitor utilizes an electrolyte between two metallic plates to form an electrochemical cell, which produces capacitance. The capacitor is typically made of two aluminum foil electrodes separated by a paper or plastic film dielectric layer. A conductive electrolyte permeates the dielectric layer, allowing for charge transfer between the metal plates. The amount of capacitance generated by the device depends on the thickness of the dielectric layer, as well as the size and shape of the metal plates.
The capacitor works by storing an electrical charge on its two metallic plates. When a voltage is applied across these plates, one plate becomes negatively charged, while the other becomes positively charged. This creates an electrostatic field between the two plates. When a current flows through the capacitor, some of the charge is transferred between the plates, resulting in a decrease in the amount of charge on each plate. This in turn, causes a decrease in the voltage across the capacitor.
On the other hand, when the voltage is removed from the capacitor, the plates return to their original state. As the charges on the plates are discharged, the voltage across the capacitor drops to zero, allowing it to store the electrical energy until the voltage is applied again. This phenomenon is known as capacitive reactance, and is one of the key principles of capacitance.
Conclusion
T86C105M050EBSL is a hybrid polymeric aluminum electrolytic capacitor which is being widely used in various applications. The capacitor is based on an electrolyte-filled dielectric layer between two aluminum plates, and it works by storing an electrical charge on its two plates. When a voltage is applied, one plate is negatively charged and the other is positively charged, which creates an electrostatic field between the two plates. The amount of capacitance generated depends on the size and shape of the plates, and the thickness of the dielectric layer.
The specific data is subject to PDF, and the above content is for reference
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