🏭 Powering the Future, Built in Our Factory

At BSLBATT, we don’t just sell batteries—we engineer and manufacture them! 🔋✨

Proudly showcasing our in-house production line, where every forklift lithium battery and energy storage system is crafted with precision, quality, and innovation. From raw materials to finished products, we control every step to ensure reliability and performance you can trust.

🔹 Forklift Lithium Batteries – Longer lifespan, faster charging, no maintenance.

🔹 Energy Storage Solutions – Scalable, efficient, and built for endurance.

When you choose BSLBATT, you choose direct-from-factory quality with cutting-edge technology. Let’s drive your business forward!

The Future of Lithium-Ion Batteries: Innovations Ahead

Lithium-ion batteries have revolutionized the way we power our devices, from smartphones to electric vehicles. But what does the future hold for this incredible technology?

Exciting innovations are on the horizon! Researchers are exploring solid-state lithium-ion batteries, which promise greater safety and higher energy density. Additionally, advancements in fast-charging capabilities could reduce charging times significantly, making EVs even more practical.

Another breakthrough is the development of lithium-sulfur batteries, which could store up to five times more energy than traditional lithium-ion cells. These innovations could reshape industries, creating a more sustainable and efficient energy future.

Speaking of batteries, if you're looking for smaller cells, like a reliable SR626SW battery, don't forget to explore options that meet your needs. Keep an eye on these tech advancements—they’re set to power tomorrow!

What do you think about the future of lithium-ion technology? Let’s chat! 🚀🔋

Discover the key differences between lithium and lead-acid batteries for material handling. Explore how each option impacts efficiency, costs, and sustainability, helping you choose between long-term savings and short-term gains. 

As China's top lithium battery supplier for scissor lifts, we know that improving equipment performance and reducing costs are key goals for every business. We recently completed a battery upgrade for our scissor lifts, switching from traditional lead-acid batteries to BSLBATT lithium batteries, and the benefits are significant!

Why choose BSLBATT lithium batteries?

🔋 Longer life: BSLBATT lithium batteries have a lifespan of up to 10 years, significantly reducing costs. 5-year/10,000-hour warranty

⚡ Higher energy efficiency: Lithium batteries have a higher energy density and higher charging and discharging efficiency, allowing our equipment to run longer and be more adaptable to 2-shift systems.

🛠 Lower maintenance requirements: Lithium batteries require almost no maintenance, eliminating the trouble of frequent watering and equalization of lead-acid batteries.

🌱 Environmentally friendly choice: Lithium batteries are lighter, reducing the overall weight of the equipment and improving transportation efficiency, while also contributing to sustainable development.

Technical Support: We have branches in North America, the Netherlands, Tokyo, Mexico, and 118 dealers worldwide. We are always here to provide you with the best support.

As technology advances, we look forward to exploring more innovative solutions in future projects to improve our operational efficiency and customer satisfaction.

🔗 To learn more about joining the BSLBATT Lithium Battery Ambassador, please visit our website. https://www.lithium-battery-factory.com/aerial-work-platform-lithium-batteries/

The History of Lithium-ion Battery Manufacturer

Lithium-ion batteries, an energy storage device that is now ubiquitous in our lives, have experienced a magnificent development process in manufacturing technology.

In the 1970s, under the shadow of the oil crisis that enveloped the world, people began to actively look for alternative energy storage solutions. At this time, the research on lithium-ion batteries quietly emerged. The early lithium-ion battery manufacturing technology faced many challenges, and issues such as material stability, battery safety, and cost all needed to be solved urgently.

In terms of materials, researchers are constantly exploring suitable positive and negative electrode materials and electrolytes. The initial positive electrode material for lithium-ion batteries was mainly lithium cobalt oxide, which has a relatively high energy density but high cost and certain safety hazards. With the development of technology, positive electrode materials such as lithium manganese oxide and lithium iron phosphate have emerged one after another. Lithium manganese oxide has a lower cost but its cycle performance needs to be improved; lithium iron phosphate has good safety and a long cycle life. Negative electrode materials have also gradually developed from the initial graphite to new materials such as silicon-based anodes to further improve the energy density of batteries.

In terms of manufacturing processes, the early lithium-ion battery production process was relatively simple and crude. As the requirements for battery performance continue to increase, the manufacturing process is becoming increasingly refined. The introduction of automated production equipment has greatly improved production efficiency and the stability of product quality. From the preparation of electrodes to the assembly of batteries, every link undergoes strict quality control. For example, in the electrode coating process, accurately controlling the thickness and uniformity of the coating is crucial for battery performance.

Entering the 21st century, with the rapid popularization of electronic products and the rise of the electric vehicle industry, the demand for lithium-ion batteries has exploded. This has further promoted the rapid development of lithium-ion battery manufacturing technology. Major manufacturers have increased research and development investment one after another, committed to improving battery performance and reducing costs.

In terms of technological innovation, solid-state lithium-ion batteries have become a research hotspot. Compared with traditional liquid electrolyte batteries, solid-state batteries have higher safety and energy density. Researchers are working hard to overcome the technical difficulties of solid-state electrolytes, such as improving ionic conductivity and improving interface compatibility with electrodes.

In addition, the continuous improvement of battery management systems also provides a strong guarantee for the application of lithium-ion batteries. Advanced battery management systems can monitor the state of batteries in real time, such as voltage, current, temperature, etc., to ensure that the batteries operate within a safe range and extend the service life of the batteries.

Looking back on the development history of lithium-ion battery manufacturing technology, we can see that this is a process full of challenges and innovations. From the initial laboratory exploration to today's large-scale industrial production, lithium-ion battery manufacturing technology has continuously advanced, bringing great convenience to our lives. Looking forward to the future, with the continuous progress of technology, it is believed that lithium-ion battery manufacturing technology will continue to reach new heights and contribute more to a sustainable energy future.

Why are lithium AA batteries the go-to choice for trail cameras?

Check out our latest blog to see why these batteries are winning the race with longer life, better performance, and more durability. Find out if lithium is the upgrade your trail camera needs! our website

What are the most potential new lithium battery materials in the future?

1. Silicon-carbon composite anode material

After the large screen and diversified functions of digital terminal products, new requirements are put forward for the battery life. At present, the gram capacity of lithium battery materials is low, which cannot meet the increasing demand for batteries in terminals.

As a kind of anode material in the future, the theoretical gram capacity of silicon-carbon composite materials is about 4200mAh/g, which is more than 372 times higher than the 10mAh/g of graphite anode.

At present, the important problems of silicon-carbon composites are:

During charging and discharging, the volume expansion can reach 300%, which will lead to the pulverization of silicon material particles, resulting in the loss of material capacity. At the same time, the ability to absorb liquid is poor.

Poor cycle life. At present, the above problems are solved by means of silicon powder nano, silicon carbon coating, doping, etc., and some companies have made some progress.

2. Lithium titanate

In recent years, the domestic enthusiasm for the research and development of lithium titanate is high.

The advantages of lithium titanate are:

It has a long cycle life (up to more than 10000,1 times), is a zero-strain material (volume change is less than <>%), and does not generate SEI films in the traditional sense;

High level of security. Its lithium insertion potential is high, no dendrite is formed, and the thermal stability is extremely high when charging and discharging;

Fast charging possible.

At present, the important factor limiting the use of lithium titanate is that the price is too high, higher than that of traditional graphite, and the gram capacity of lithium titanate is very low, about 170mAh/g. Only by improving the production process and reducing the production cost can the advantages of lithium titanate such as long cycle life and fast charging be put into use. Combined with the market and technology, lithium titanate is more suitable for use in buses and energy storage fields that have no space requirements.

3. Graphene

Since graphene won the Nobel Prize in 2010, it has attracted wide attention from all over the world, especially in China. There has been a boom in graphene research and development in China, which has many excellent properties, such as good light transmittance, excellent electrical conductivity, high thermal conductivity and high mechanical strength.

Potential applications of graphene in lithium-ion batteries are:

as anode material. The gram capacity of graphene is high, and the reversible capacity is about 700mAh/g, which is higher than the capacity of graphite anode. In addition, the good thermal conductivity of graphene ensures its stability in the battery system, and the spacing between graphene sheets is greater than that of graphite, so that lithium ions diffuse smoothly between graphene sheets, which is conducive to improving the power performance of batteries. Due to the immature production process and unstable structure of graphene, there are still some problems in graphene as an anode material, such as low first discharge efficiency, about 65%; Poor cycling performance; The price is higher, which is significantly higher than that of traditional graphite anode.

As a positive and negative electrode additive, it can improve the stability of lithium-ion batteries, extend the cycle life, and add new internal conductivity.

In view of the immaturity, high price and unstable performance of graphene in the current mass production process, graphene will be the first to be used as a positive and negative electrode additive in lithium-ion batteries.

4. Carbon nanotubes

Carbon nanotubes are a kind of carbon material with graphitized structure, which has excellent conductivity, and because of its small depth and short stroke when de-intercalation, it can be used as an anode material for less polarization during large-rate charging and discharging, which can improve the large-rate charge-discharge performance of the battery.

Shortcoming:

When carbon nanotubes are directly used as anode materials for lithium-ion batteries, there are problems such as high irreversible capacity, voltage lag and inconspicuous discharge platform. For example, Ng et al. prepared single-walled carbon nanotubes by simple filtration, and directly used them as anode materials, with a first discharge capacity of 1700mAh/g and a reversible capacity of only 400mAh/g.

Another application of carbon nanotubes in the anode is to combine with other anode materials (graphite, lithium titanate, tin-based, silicon-based, etc.) to improve the electrical properties of other anode materials by using their unique hollow structure, high conductivity and large specific surface area as a carrier.

5. Lithium-rich manganese-based cathode materials

High capacity is one of the development directions of lithium-ion batteries, but the energy density of lithium iron phosphate and lithium nickel-cobalt-manganese oxide is 580Wh/kg and 750Wh/kg in the current cathode materials, both of which are low. The theoretical energy density of lithium-rich manganese base can reach 900Wh/kg, which has become a hot spot for research and development.

The advantages of lithium-rich as a cathode material are:

High energy density and abundant important raw materials

Due to the short development time, there are a number of problems with the lithium-rich manganese base:

The first discharge efficiency is very low, and the material is oxygen in the cycle process, which brings potential safety hazards, poor cycle life, and low rate performance.

At present, the means to solve these problems include coating, acid treatment, doping, pre-cycling, heat treatment, etc. Although lithium-rich manganese base has obvious gram capacity advantages and huge potential, it is limited to slow technological progress, and it will take time for it to be marketed in large quantities.

6. Power nickel-cobalt-lithium manganese oxide material

For a long time, there has been a great controversy about the route of power lithium batteries, so lithium iron phosphate, lithium manganese oxide, ternary materials and other routes have been adopted. The domestic power lithium battery route is dominated by lithium iron phosphate, but with Tesla's popularity around the world, the ternary material route it uses has caused a boom.

Although lithium iron phosphate is safe, its low energy density can not be overcome, and new energy vehicles require longer mileage, so in the long run, materials with higher gram capacity will replace lithium iron phosphate as the next generation of mainstream technology routes.

Lithium nickel-cobalt-manganese oxide ternary materials are most likely to become the mainstream materials for the next generation of power lithium batteries in China. Domestic electric vehicles with ternary routes, such as BAIC E150EV, JAC IEV4, Chery EQ, Weilan, etc., have a great increase in unit weight density compared with lithium-ion iron phosphate batteries.

7. Coat the diaphragm

Separators are critical to the safety of lithium-ion batteries, requiring good electrochemical and thermal stability, as well as high wettability to the electrolyte during repeated charge and discharge.

Coated diaphragm refers to the coating of adhesives such as PVDF or ceramic alumina on the base film. The uses of coated diaphragms are:

1. Improve the heat shrinkage resistance of the diaphragm and prevent the diaphragm from shrinking and causing a large area of short circuit;

2. The thermal conductivity of the coating material is low, which prevents some thermal runaway points in the battery from expanding to form an overall thermal runaway.

8. Ceramic alumina

In the coated separator, the ceramic coated separator is mainly aimed at the power lithium battery system, so its market growth space is larger than that of the glued separator, and the market demand for its core material ceramic alumina will be greatly increased with the rise of ternary power lithium battery.

The purity, particle size and morphology of ceramic alumina used to coat the separator have high requirements, and the products of Japan and South Korea are more mature, but the price is more than twice as expensive as the domestic ones. At present, there are also many companies in China that are developing ceramic alumina, hoping to reduce dependence on imports.

9. High-voltage electrolyte

Increasing the energy density of batteries is one of the trends of lithium-ion batteries, and there are currently two important ways to increase energy density:

One is to increase the charging cut-off voltage of traditional cathode materials, such as increasing the charging voltage of lithium cobalt oxide to 4.35V and 4.4V. However, the method of increasing the charging cut-off voltage is limited, and further increasing the voltage will lead to the collapse of the lithium cobalt oxide structure, which is unstable in nature.

The other is to develop new cathode materials with higher charging and discharging platforms, such as lithium-rich manganese-based, lithium nickel-cobalt oxide, etc.

After the voltage of the cathode material increases, the high-voltage electrolyte to be matched with it, additives play a key role in the high-voltage performance of the electrolyte, which has become the focus of research and development in recent years.

10. Water-based binder

At present, cathode materials mainly use PVDF as a binder, which is dissolved with organic solvents. Organic solvents are also used in the binder system of the negative electrode, such as SBR, CMC, and fluoroolefin polymers. In the process of electrode production, the organic solvent should be dried and volatilized, which not only pollutes the environment, but also endangers the health of employees. The dried and evaporated solvents need to be collected and processed in special freezing equipment, and fluoropolymers and their solvents are expensive, adding to the production cost of lithium-ion batteries.

グリッドスケールバッテリー：リチウムだけではない | Oneechanblog Podcast

31. Mai 2025

Oh no, täglich ans Aufladen denken, wie soll das bloß gehen!

Ab morgen kann man in ganz Großbritannien keine Einweg-Vapes mehr kaufen. Ich erfahre das durch einen ausgedruckten Zettel im Dorfsupermarkt:

So ein Verbot habe ich mir schon öfter gewünscht, weil man hier wirklich viele Single-Use-Vapes auf den Straßen und in der straßennahen Natur findet. Ich habe es nur für unwahrscheinlich gehalten, dass es dazu kommt, weil sich die britische Regierung insgesamt (und nicht erst seit dem Brexit) eher wenig für Umweltschutz interessiert: Abwasser wird in dieser Ecke Schottlands wie an vielen anderen Orten direkt ins Meer gepumpt, der Müll kommt auf eine Müllkippe im Nachbardorf.

Aber jetzt haben sie also tatsächlich Einweg-Vapes verboten, Jahre vor Deutschland, wo das voraussichtlich 2027 passieren wird, und dann nur indirekt als Folge einer EU-Regelung, die von Wegwerfartikeln mit nicht leicht ausbaubaren Batterien handelt. Begründet wird das britische Verbot überraschenderweise unter anderem mit Umwelt- und Müllverarbeitungsproblemen.

Die BBC zitiert Einweg-Vape-Fans, deren Hauptproblem mit der Umstellung zu sein scheint, dass sie ein Mehrweggerät aufladen müssten:

"With everything else going on in my life, what if I forget to recharge my vape? And then I wake up one morning without a vape, or I run out of charge at work? "I'm used to the ease of being able to buy a disposable one when I need." (Quelle: "'I don't know what we'll do' – Vapers panic-buy ahead of disposables ban")

Ich verstehe das Problem nicht. Dieselben Leute haben doch sicher Handys und müssen da auch mindestens einmal täglich ans Laden denken. Und bei anderen Abhängigkeiten hat man noch ganz andere Probleme. Im Techniktagebuch-Redaktionschat erkennt Oliver Laumann das Problem als eine Spielart der deutschen Reichweitenangst. Felix Neumann schlägt vor, für Notfälle immer ein Kurbelvape parat zu haben.

(Kathrin Passig)

BQ25185 all-in-one Li-Poly board with 3.3V out 🔋🌞⚡

We had a previous version of this 3.3V buck output board with an MCP73831, but now we've replaced it with a BQ25185, which makes it a little more flexible: Vin can be up to 18V, and solar panels will work, too. There's also a power path and 4.5V regulated output. This charger chip can handle LiFePO4, but for that chip, we might swap the buck for a buck-boost or a boost / LDO to get the solid 3.3V output. Coming soon.

🚀 We're at Solar & Storage Live Philippines 2025 – Meet Us at Booth 1-Q11!

The countdown begins! In just 5 days, our team will showcase cutting-edge lithium battery storage solutions at Solar & Storage Live Philippines 2025 (May 19-20).

📍 Booth 1-Q11 | SMX Convention Center, Manila.

EMPOWERING RENEWABLE ENERGY

The Role of Energy Storage Solutions

Renewable energy sources like solar, wind, and hydro-power are making substantial strides in transforming our energy landscape. They offer a cleaner, more sustainable alternative to traditional fossil fuels. However, their intermittent nature and dependency on weather conditions have presented a significant challenge: how to ensure a reliable and consistent supply of electricity. This is where energy storage solutions step in, playing a pivotal role in empowering renewable energy.

In this blog, we will explore the crucial role of energy storage solutions in empowering renewable energy and driving the transition to a cleaner and more sustainable energy future.

The Ascendance of Renewable Energy

Before we dive into the role of energy storage, let's briefly examine the rise of renewable energy sources. Over the past few decades, there has been a growing awareness of the environmental impacts of fossil fuel consumption, including air pollution, climate change, and resource depletion. In response to these concerns, countries and industries worldwide have been shifting their focus towards cleaner and more sustainable energy alternatives. Solar panels and wind turbines have become increasingly common sights, harnessing the power of the sun and the wind to generate electricity. Hydropower, utilizing the energy of flowing water, is another established and widely used renewable energy source. These technologies offer a more sustainable and environmentally friendly way to meet our energy needs.

The Challenge of Intermittency

While renewable energy sources have numerous advantages, they are inherently intermittent. The sun doesn't shine at night, the wind doesn't always blow, and water availability can vary seasonally. These fluctuations in energy production can make it challenging to maintain a stable and reliable electricity supply. Consider solar power, for example. Solar panels produce electricity when exposed to sunlight, but they don't generate power after sunset or during cloudy weather. Wind turbines are similarly dependent on wind conditions. When the wind is too weak or too strong, it may not operate optimally. Hydropower generation can be affected by droughts or heavy rainfall. These intermittent energy sources need a solution to ensure a steady power supply, especially when demand remains constant.

Energy Storage Solutions to the Rescue

Energy storage solutions, primarily in the form of batteries, serve as the linchpin that bridges the gap between renewable energy production and demand. They work by storing excess electricity generated during periods of high renewable energy production and releasing it when needed. Let's delve into the ways in which energy storage empowers renewable energy.

1. Balancing Supply and Demand

Energy storage systems store excess energy when renewable sources are producing more power than needed. This surplus energy is then discharged during periods of high demand or when renewable generation is low. This balance ensures a stable electricity supply and prevents disruptions.

2. Integration of Renewable Resources

Energy storage allows for the smooth integration of renewable resources into the existing energy infrastructure. By storing excess energy, renewable sources can contribute more consistently to the grid, reducing the need for backup fossil-fuel-based power generation.

3. Grid Stability and Reliability

Energy storage systems enhance grid stability by providing a buffer against fluctuations in energy supply. They can store excess energy during times of low demand and release it during peak demand, reducing strain on the grid.

4. Peak Shaving

Peak shaving is a strategy used by energy providers to reduce the overall demand for electricity during periods of high energy consumption. Energy storage can be used to store excess energy during off-peak hours and release it during peak times, reducing costs and relieving pressure on the grid.

5. Increased grid resilience

Energy storage systems enhance grid resilience by providing backup power during outages and disasters. They can keep critical facilities operational and reduce downtime, offering a vital lifeline during emergencies.

6. Supporting Remote and Off-Grid Areas

Energy storage is invaluable in remote or off-grid areas where a consistent power supply is challenging to achieve. These systems enable the reliable delivery of electricity, reducing the need for costly infrastructure expansion.

Energy storage solutions come in various forms, but batteries are the most commonly used and versatile. Lithium batteries, in particular, have gained widespread adoption due to their high energy density, efficiency, and reliability. Other battery technologies, such as solid-state batteries and flow batteries, are also emerging as promising options.

The Future of Energy Storage

The role of energy storage solutions in empowering renewable energy is poised to grow significantly in the coming years. Advances in technology, falling costs, and increased investment are driving innovation and adoption in this sector. Some key trends and developments to watch for include:

1. Improved battery technology

Advancements in battery technology, such as the development of solid-state batteries and the use of alternative materials, are increasing energy density, reducing costs, and extending battery lifetimes.

2. Grid-Scale Energy Storage

The construction of larger grid-scale energy storage facilities is expanding worldwide, enabling more significant integration of renewable energy into the grid.

3. Energy Storage Policy and Regulation

Governments and regulatory bodies are recognizing the importance of energy storage and are implementing policies and incentives to promote its adoption.

4. Circular Economy and Recycling

Efforts are underway to develop recycling programmes for energy storage systems to minimize the environmental impact of these technologies.

The Journey Ahead

The integration of energy storage solutions into the renewable energy landscape is a game-changer. It not only addresses the intermittency of renewable sources but also accelerates the adoption of clean energy by making it more reliable and cost-effective. As technology continues to advance, we can expect energy storage systems to become more efficient, affordable, and widespread.

In conclusion, the role of energy storage solutions in empowering renewable energy cannot be overstated. They are the key to a future where our energy needs are met sustainably and reliably while reducing our dependence on fossil fuels and mitigating the effects of climate change. As technology continues to progress and the benefits of energy storage become more apparent, the partnership between renewables and energy storage will shape the energy landscape for years to come.

⚡ Revolutionizing Material Handling in 2025! ⚡ Discover how lithium batteries are transforming 2-3 shift material handling with: ✅ Improved Efficiency ✅ Reduced Downtime ✅ Enhanced Performance

Say goodbye to operational delays and hello to seamless productivity! 🚀 SBR Batteries delivers cutting-edge solutions for a more powerful and efficient future. 🌟

The Perfect Partnership: Yamaha Golf Carts & BSLBATT 48V 104Ah Battery 🚗🔋 

Excited to see the seamless collaboration between Yamaha golf carts and the powerful BSLBATT 48V 104Ah lithium battery! ⚡

This combination not only delivers outstanding performance but also extends range and reliability on the course. Experience longer-lasting power, reduced maintenance, and enhanced efficiency for a truly unbeatable ride.🌟

Today, We will share the process of making a 12V portable power supply using 18650 ternary lithium batteries, each with a capacity of 2500mAh.#DIYbattery #lithiumbatteries #powersupply

Small size, light weight, fast charging, long life, no leakage, safer. ♻️

With multiple advantages, the MKS series will significantly enhance your riding experience as a partner of your powersports 🚴

Leoch motorcycle lithium batteries are in the spotlight at Automechanika Shanghai 2023! 🏍️