Ultralife 9V Lithium Battery
₹750.0
| Battery Capacity | 1.2 Ah |
| Voltage | 9V |
| Battery Type | LiMnO2 |
| Country of Origin | Made in India |
| Packaging Type | Box |
| Brand | Ultralife |
| Current | 7 Amp |
| Min. Operating Temperature | -20 DegreeC |
| Max. Operating Temperature | 60 DegreeC |
| Min. Storage Temperature | -40 DegreeC |
| Max. Storage Temperature | 60 DegreeC |
| Shelf Life | 10 Years |
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Ultralife’s Lithium 9-volt battery is a consumer-replaceable battery that lasts up to 5 times longer than ordinary alkaline 9V batteries and 10 times longer than carbon-zinc batteries.
It has the highest energy density, flattest discharge voltage curve, longest shelf life, widest operating temperature range, and lightest weight of any comparable 9-volt battery. A 10-year service / shelf life makes our 9-volt battery the choice for major smoke alarm manufacturers for their premium lines of 10-year ionization-type smoke alarms. As a consumer-replaceable battery, consumers can instantly upgrade any application requiring a 9-volt battery.
Features:
- High energy density, up to 5x more than alkaline, up to 10x more than carbon zinc
- Up to 10 year shelf life
- High running voltage
- Flat discharge voltage curve
- Low impedance, better performance at low temperatures
- Up to 10 year operational life in most ionization-type smoke detectors
- Advanced safety features – over current protection
- Lightweight – 18% less than alkaline
- Wide operating temperature range
- Meets ANSI Alkaline 1604 size specifications
- Low short circuit temperature
Applications:
- Alkaline 9V replacement
- Rugged handheld devices
- Telematics
- Test and Instrumentation
- Smoke alarms / carbon-monoxide detectors
- Beacons and emergency location transmitters
- Security systems / sensors
- Metering systems
- Sonobuoy’s
- Music / audio devices
- Handheld security scanners
- Medical Instruments
- Wearable medical devices
- Surgical lighting
- Patient monitors
- Data recorders
- Remote monitoring systems
| brands | ULTRALIFE |
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Q & A
Electrochemical batteries, such as lithium-ion batteries, are widely used in various applications, including electric vehicles, portable electronics, and renewable energy storage. While they offer many benefits, their sustainability depends on several factors.
Resource Extraction: The production of electrochemical batteries involves the extraction of raw materials, such as lithium, cobalt, nickel, and graphite. The sustainability of batteries depends on responsible mining practices, reducing environmental impacts, and ensuring the rights and well-being of local communities involved in extraction.
Energy Consumption: The manufacturing process of batteries requires energy, and the sustainability of batteries depends on the energy sources used. If the energy comes from fossil fuels, it contributes to greenhouse gas emissions and climate change. However, using renewable energy for battery production significantly improves their sustainability.
End-of-Life Management: Proper disposal or recycling of batteries is crucial for their sustainability. Batteries contain hazardous materials that can harm the environment if not handled correctly. Establishing effective recycling programs to recover valuable materials from spent batteries reduces the need for raw material extraction and minimizes waste.
Lifetime and Performance: The longer a battery lasts and the more energy it can store over its lifetime, the more sustainable it becomes. Improving battery durability, energy density, and cycle life reduces the need for frequent replacements, leading to a lower environmental impact.
Circular Economy: Implementing a circular economy approach can enhance the sustainability of electrochemical batteries. This involves designing batteries for easy disassembly, reuse, and recycling, enabling the recovery of valuable materials and reducing waste.
Significant efforts are being made to improve the sustainability of electrochemical batteries. Researchers are exploring alternative materials, such as solid-state electrolytes, to reduce reliance on scarce resources and increase safety. Additionally, advancements in battery recycling technologies and the development of closed-loop supply chains are being pursued to minimize waste and maximize resource recovery.
It's important to note that while electrochemical batteries have sustainability challenges, they are still considered a valuable technology in the transition towards a low-carbon future. Continued research and innovation, coupled with sustainable practices across the entire battery life cycle, are essential to improve their overall sustainability.
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