DZN-2R5D335T

Series:	DZN
Packaging:	Bulk
Lead Free Status / RoHS Status:	--
Part Status:	Active
Capacitance:	3.3F
Tolerance:	-20%, +80%
Voltage - Rated:	2.5V
ESR (Equivalent Series Resistance):	40 mOhm @ 1kHz
Lifetime @ Temp.:	1000 Hrs @ 70°C
Termination:	PC Pins
Mounting Type:	Through Hole
Package / Case:	Radial, Can
Lead Spacing:	0.197" (5.00mm)
Size / Dimension:	0.492" Dia (12.50mm)
Height - Seated (Max):	0.984" (25.00mm)
Operating Temperature:	-25°C ~ 70°C

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Electric Double Layer Capacitors (EDLC), also known as supercapacitors, are an emerging technology that uses two layers of electric charge to store energy. The latest EDLC technology, DZN-2R5D335T, makes use of a very thin dielectric material to separate two electrodes. This allows for a higher energy density than traditional capacitors and can be used in a variety of applications. In broader terms, EDLC supercapacitors can be divided into two categories: Electric Double Layer Capacitors (EDLC) and Supercapacitors. EDLCs store energy by using two layers of electric charge. This is done by having one layer of positive and one layer of negative ions that form a stable electric double layer around an electrolyte. This method is ideal for applications that require ultra-low leakage and fast charging capabilities. Supercapacitors, on the other hand, store energy by combining two electric double layer capacitors in parallel. The DZN-2R5D335T application field and working principle consists of two types of capacitors. The first type is a dual stack type EDLC, which increases the charge storage capacity in a smaller space than other EDLC types. This type of EDLC is typically used in applications that require a very high amount of energy in a short time, such as solar cell arrays or electric cars. The second type is a supercapacitor, which combines the two electric double layers into a single device. One of the main differences between EDLCs and supercapacitors is their charge/discharge rate. EDLCs can quickly store and discharge energy but the amount of energy they can store is limited. Supercapacitors, on the other hand, have much higher charge/discharge rates and can store significantly more energy. However, they are also much more expensive than EDLCs and often take up more space. The DZN-2R5D335T application field and working principle allow for a much higher energy density than is achievable with traditional capacitors. The device makes use of a very thin dielectric material to separate two electrodes, allowing for a very low capacitance value of 2.5mF. This allows for a maximum rated voltage of 2.5V and a maximum rated power of 8W. The charge/discharge rate of the DZN-2R5D335T is also much higher than other EDLCs and supercapacitors, allowing for fast charging and discharging of energy. The DZN-2R5D335T application field and working principle offer a variety of potential applications. They are ideally suited for applications that require high amounts of energy in a short period of time, such as solar cell arrays in renewable energy systems. They are also ideal for applications that need to rapidly charge and discharge energy, such as in electric vehicles. In addition, the device can be used in products that require a low capacitance value, such as cameras and other consumer electronics. The DZN-2R5D335T is also ideal for applications that require reliable and stable power in harsh environments. This includes medical implants, aerospace, and defense systems. Since it can quickly store and discharge large amounts of energy, it can also be used in grid storage applications. It can also be used in consumer electronics as a backup power source in the event of a power outage. The DZN-2R5D335T application field and working principle make it a versatile and reliable energy storage device. It is capable of quickly storing and discharging large amounts of energy, while maintaining a low leakage current and a low capacitance value. In addition, it is cost-effective and can be used in a variety of applications. As such, it is an ideal choice for applications that require reliable, efficient, and fast energy storage.

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