HVZ0E107NF-LT

Series:	HVZ
Packaging:	Bulk
Lead Free Status / RoHS Status:	--
Part Status:	Active
Capacitance:	100F
Tolerance:	±30%
Voltage - Rated:	2.7V
ESR (Equivalent Series Resistance):	30 mOhm @ 1kHz
Lifetime @ Temp.:	--
Termination:	PC Pins
Mounting Type:	Through Hole
Package / Case:	Radial, Can - Snap-In
Lead Spacing:	0.394" (10.00mm)
Size / Dimension:	0.984" Dia (25.00mm)
Height - Seated (Max):	2.047" (52.00mm)
Operating Temperature:	-25°C ~ 60°C

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Introduction

Electric Double Layer Capacitors (EDLC), also known as ‘supercapacitors’, differ from conventional capacitors in several key ways. Different from conventional capacitors, EDLCs have much higher capacitance values, store much larger amounts of energy, and have longer service lives. Moreover, due to their low equivalent series resistance, they have higher power density than traditional capacitors.HVZ0E107NF-LT is a member of EDLC family, which provides a variety of advantages for its application. In this article, the application field and working principle of HVZ0E107NF-LT will be discussed in detail.

Application Field

HVZ0E107NF-LT is capable of holding high charge and high discharge rates with large amount of energy. Its wide operating temperature range (capacitance changes less than -20°C to +80°C), makes it suitable for a broad range of environmental conditions. Furthermore, its excellent rate of response makes it ideal for applications in automotive and industrial settings. In addition, it is used in applications such as buffering energy, regenerative braking sytems, stabilization of voltage output, data protection, and low frequency output current smoothing. The device can also be employed as a back-up energy storage device in smartphones, PDAs, and laptop computers. Due to its energy density, the device supports a wide range of wide operating temperature range and extended storage life, making it suitable for long durable use. In automotive applications, it is often used in smart motors, solar panel storage, and automotive light energy storage systems. Its capability of high charge and discharge rates makes it ideal for providing direct current (DC) power supply for vehicles. Moreover, high capacitance density makes it a perfect choice for regenerative braking energy storage systems.

Working Principle

HVZ0E107NF-LT works on the principle of electric double layer capacitance. In this mechanism, a thin film of positively charged ions adsorb on the surface of an electrically neutral material, forming an electrical double layer. When a voltage is applied to this double layer, a displacement of ions occurs from one layer to the other side, creating an electric field between the two layers. This electric field can then be used to store high amount of energy. The amount of energy stored depends on the thickness of the double layer and its area. As the double-layer gets thicker, more ions are adsorbed at the surface and more energy can be stored in the electric field. The performance of HVZ0E107NF-LT is improved by several factors. First, its high capacitance density makes it suitable for a wide range of applications, as it can store more charge (electrons) than traditional capacitors. Second, its low equivalent series resistance (ESR) gives it higher power density than traditional capacitors. This allows the device to work with high voltage fluctuation. Finally, its wide operating temperature range (capacitance changes less than -20°C to +80°C) makes it ideal for applications in automotive and industrial settings.

Conclusion

HVZ0E107NF-LT is an innovative member of the EDLC family which has a wide variety of advantages for its application fields. Its high capacitance density, low ESR, and wide operating temperature range make it ideal for automotive and industrial applications. Its working principle is based on the electric double layer capacitance, whereby a thin film of positively charged ions adsorb on the surface of an electrically neutral material, forming an electric double layer. When a voltage is applied to this double layer, a displacement of ions occurs from one layer to the other side, creating an electric field between the two layers, which can be used for storing high amount of energy.

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