8 Inspiration for Flexible Batteries

 

flexible battery

People’s needs and other electronic products such as wearable electronic devices, electronic paper, smart clothing, etc. have urgently needed foldable and retractable flexible batteries. Lithium-ion batteries have become an ideal research object for flexible batteries because of their higher energy density and longer service life. A complete lithium-ion battery contains the main parts of the positive electrode, negative electrode, separator, electrolyte, current collector, and battery packaging materials. During the folding and stretching process of the flexible battery, each part has to undergo certain deformation. Therefore, the materials and structures of all parts of the flexible battery must maintain performance after several times of folding and stretching.

Applications of Bionics

After hundreds of millions of years, the creatures on earth have been constantly evolving to adapt to the changing living environment. We humans also draw inspiration from the changes in nature and create many new things. “Bionics” has been used in various fields. For example, radial and spiral filaments make spider webs have good toughness and elasticity. People have made nanofiber webs based on spider webs. For another example, according to a paper-cut craft in our daily life, flexible supercapacitors with similar structures also get good performance. During the development of flexible batteries, what inspirations have we got from nature? This article will introduce in detail.

Applications of Bionics
Applications of Bionics

1. Buckling structure

The buckling structure, also known as the wave-shaped structure, is a wave-shaped stretchable structure as the name implies. The active material is usually coated on a wave-shaped metal pole piece to make a stretchable electrode. The multi-layer buckling structure based on this wave structure shows better performance. In 2015, Fang and Baughman’s research team jointly published an article on Science. The carbon nanotube layer (NTS) is rolled onto a stretched elastic rubber fiber. When the fiber tension pressure is released, its surface is covered. The carbon nanotubes formed a multilayer buckling structure. This kind of multi-buckling structure carbon nanotubes has a resistance change of less than 5% when the tensile deformation is 1320%, which has good application potential in flexible batteries.

Figure 1. The formation process and SEM picture of multilayer buckling structure
Figure 1. The formation process and SEM picture of multilayer buckling structure

2. Origami

Origami is the art of folding or folding paper. The paper is folded into a specific shape and pattern. Intricate designs can be created only through the skill of folding. By folding, bending, etc., the 2D dimensional paper is folded into various shapes in 3D space. And what kind of spark did the application of origami technology to flat lithium-ion batteries sparked? In 2014, the Jiang research team of Arizona State University assembled the current collector, positive electrode, negative electrode, separator, and packaging material according to two different angles. When stretched or bent, the battery can withstand great stress due to the folding effect. Very good elasticity, and still maintain a good cycle capacity after folding the battery many times.

Figure 2. Assembly diagram of the folded battery
Figure 2. Assembly diagram of the folded battery

3. Paper cut

Paper-cutting is one of the oldest folk art in China. It is used to cut patterns on paper to decorate life or cooperate with some folk activities. Unlike origami, paper cutting involves cutting paper. In 2015, the Song research team of Arizona State University produced a “cut-N-shear” battery assembly structure through cutting and folding. When there is an external force, the notch can be rotated to adjust the structure. The battery assembled by this method can still maintain energy storage performance when stretched by 150%.

Figure 3. "cut-N-shear" battery assembly structure diagram
Figure 3. “cut-N-shear” battery assembly structure diagram

4. Spring

Springs can be seen everywhere in our lives. The spring is widely used because of its good elasticity and restoring force. In the design of flexible batteries, the source of inspiration is also indispensable. The Peng research team of Fudan University winds carbon nanotubes on spring-shaped fibers, and the resulting carbon nanotube electrodes retain their shape and capacity during the stretching process. They also made Li4TiO (LTO) anode material and LiMn2O4 (LMO) cathode material together into a spring structure. The battery capacity of this structure does not change when stretched.

Figure 4. Schematic diagram and SEM photo of battery assembly with spring structure
Figure 4. Schematic diagram and SEM photo of battery assembly with spring structure

5. Porous structure

Porous structures, such as sponges, not only have good water absorption but also have good elasticity. In 2016, Yi Cui of Stanford University filled the electrode material, carbon material, and binder into the sponge-like PDMS to form a 3D porous lithium-ion battery that maintained excellent energy storage performance when stretched by 80%.

Figure 5. Schematic diagram of sponge battery
Figure 5. Schematic diagram of sponge battery

6.2D “Crack”

Sometimes the formation of cracks is not necessarily a bad thing, distance can produce beauty. When thermal electron beam evaporation or electron beam evaporation produces gold thin films, micro-cracks can be formed on the thin films by controlling parameters. When there is an external force, these cracks can act as a buffer. Conductive polymers such as PEDOT: PSS, P3HT, etc. will also use this strategy in the production process to increase the flexibility of the polymer film.

Figure 6. SEM pictures of the gold film (with microcracks) on PDMS substrate before and after stretching
Figure 6. SEM pictures of the gold film (with microcracks) on PDMS substrate before and after stretching

7. Mesh structure

The web-like structures in nature such as spider webs have excellent mechanical properties, are very soft and tough, and some web-like structures, such as leaf veins and rivers, can be effectively transported by cross-linked webs. All these structures are used to make flexible electrodes. The simplest method of making mesh electrodes is to randomly coat the active material on the surface of the elastic substrate or inject it into the inside. When pressure is applied from the outside, the active material will be compressed and connected together. This method will not destroy the original structure of the active material, and at the same time can produce good conductivity. The silver nanowires produced by the Lee and Ko research groups of the Korean Academy of Science and Technology form a net-like circuit network when stretched, and have good conductivity when used as electrodes.

Figure 7. Reticulated silver nanowire electrode
Figure 7. Reticulated silver nanowire electrode

8. Self-repair function

Although many different methods are envisaged to make flexible materials, the actual situation is often more complicated. When a flexible instrument containing both flexible and rigid materials receives an external force, the internal structure of the instrument will inevitably undergo structural changes and even damage. Inspired by the self-healing mechanism of natural organisms and plants, flexible batteries have a similar design. In 2012, Zhenan Bao’s research team at Stanford University filled nickel nanoparticles into self-healing polymers at temperatures below room temperature. At 31% nickel content, the composite can be used as an electrode, and at 15% nickel content, the composite can be used as a mechanical sensor. When the two ends of the composite are placed at room temperature, it can self-repair external force damage and restore electrical conductivity.

Figure 8. Nickel composite electrode structure with self-healing function
Figure 8. Nickel composite electrode structure with self-healing function

Functionalization has always been the ultimate goal of people developing new materials. And just like us humans, many complex behaviors do not rely on a single organ and require coordination of various parts. The same is true for flexible batteries, which require all parts of the battery to cope with changes in external forces. Nature provides us with space and food for our survival. It also gave us a lot of inspiration. The development of flexible batteries draws on many examples from nature. At the same time, we believe that more scientific researchers will apply “bionics” to flexible batteries to promote the development of flexible batteries.

What is a Flexible Battery?

  

GREPOW Curved Lithium Polymer Battery

Flexible batteries refer to batteries that can be folded and twisted at will, including primary and secondary batteries. Unlike traditional rigid batteries, their design is conformal and flexible. They can maintain their characteristic shape even when continuously bent or twisted. It is to turn the traditional liquid electrolyte into a solid-state, and “print” the internal structure of the traditional lithium-ion battery on the flexible substrate so that the battery will not be “powered off” even if it is bent or folded, thereby ensuring the battery It can work normally even after bending or folding.

Demand for flexible batteries

We are used to thinking of batteries as bulky tools that can store energy and power electronic devices. For a long time, disposable carbon-zinc batteries, rechargeable lead-acid batteries, and nickel-cadmium batteries have been dominant.

flexible batteries Market descriptions by territory
Figure 1: Market descriptions by territory      Source: IDTechEx

With the emergence of portable devices such as netbooks, ultrabooks, and other handheld devices, the battery market has seen explosive growth of various types, among which the most popular is lithium-ion rechargeable batteries. However, as electronic products become thinner and more flexible, batteries must now get rid of their rigid form and adapt to their bending. Therefore, the thin-film flexible battery market has also followed.

Market observer IDTechEx predicts in their new report that by 2026, the current small thin-film battery market will reach US$470 million. According to He Xiaoxi, a technical analyst at IDTechEx, this is the reason why companies such as TDK, STMicroelectronics, LG, Samsung, and Apple are increasingly involved. Considering the Internet of Things, the deployment of wearable devices and other environmental sensors is getting faster and faster, and it is imperative to replace traditional battery technology. New dimensions and designs are urgently needed. For example, Samsung has a curved battery in the Gear Fit wristband.

Flexible battery manufacturers

The GREPOW battery manufacturer has more than 20 years of battery manufacturing experience. Special-shaped battery technology is mature. The advantages of the special-shaped battery are their adaptability, lightweight and portability, which makes them easy to be used in products such as small and wearable electronic devices. achieve. Therefore, GREPOW is working hard to manufacture different shaped batteries, including rechargeable batteries with high energy density and good shape, and is in a leading position in the industry. Here are two types of batteries related to flexible batteries: curved batteries, Thickness: 1.6 mm ~ 4.5 mm; Width: 6.0 mm ~ 50 mm; Inner arc length: 20 mm ~ 55 mm; Inner arc radius: ≥8.5 mm.

GREPOW curved battery
Figure 2: curved battery      Source: GREPOW battery

Another GREPOW special-shaped battery: ultra-thin battery, Charge the battery to 3.83v and fix the battery to the surface of the white PVC card. Fix the cell pole card to the bending and torsion tester, 15 degrees forward and backward, and 30 degrees total distortion, for bending and torsion test. After the bending and torsion test of the 0.45mm ultra-thin cell for 9000 times, the surface of the cell was folded and the internal pole sheet had creases. The internal resistance increased by about 45%. The voltage before and after the bending and torsion basically remained unchanged.

ultra thin battery
Figure 3: ultra-thin battery      Source: GREPOW battery

STMicroelectronics (ST) is producing thin-film solid-state lithium batteries in small quantities. The report said that two other companies are producing printed batteries. Therefore, there are now various flexible batteries on the market competing for power to power several devices.

Other companies are also trying other strategies. For example, TDK is developing battery-less energy harvesters. The idea is because IoT nodes and wearable devices require extremely low power to operate, so they can be operated by energy harvesters instead of batteries. Other companies such as Oakridge Global Energy Solutions Inc. plan to increase production capacity at their Brevard County, Florida plant. They will manufacture electrodes and batteries for thin-film solid-state lithium batteries. They acquired this technology from Oak Ridge Micro-Energy Inc. in 2002 and plan to start mass production in early 2017.

Types and applications of flexible batteries

Various flexible batteries will soon be on the market. These will include thin-film batteries, printed batteries, layered lithium polymer batteries, micro-batteries, advanced lithium-ion batteries, thin flexible supercapacitors, and stretchable batteries.

Understandably, they will have multiple uses. For example, wearable devices are expected to become the greatest potential for flexible batteries. Printed batteries in the form of skin patches have been used in the healthcare industry, and the market is growing steadily. At present, although the high cost of printed zinc batteries hinders its widespread application, this application has the greatest potential. According to the IDTechEx report, the market for micro-power batteries that power disposable medical devices will expand rapidly.

flexible batteries Applications
Figure 4: Applications of batteries with new form and structural factors     Source: IDTechEx

There are other requirements for batteries that power various types of power sources, displays, and flexible sensors. The U.S. Department of Defense has invested $75 million to create the Flexible Hybrid Electronics Manufacturing Institute in San Jose.

The promotion of flexible batteries and flexible electronics is of great significance. Based on the demand for electronic equipment for batteries, the promotion of flexible battery technology and the cooperation of flexible display, biosensor, and flexible circuit technologies will help to develop more flexible electronic devices for medical health monitoring, smart textiles, smartphones, and global It is applied in multiple scenarios such as positioning system tracking, Internet of Things, and human-computer interaction.

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What is a Good-quality Rechargeable Button-cell Battery?

 

Rechargeable Button-Cell Battery

Rechargeable button-cell batteries are widely used in various devices, so it’s important to know the characteristics of these batteries.  We will briefly explore some of these attributes in this article.

Safety

Safety is one of the most basic and important manufacturing guidelines for all batteries. To prevent short circuits and leakage in button-cell batteries, manufacturers of rechargeable button- cell batteries choose chemically stable materials.

Stability

The M-shaped bump process allows for better contact with machines, which allows for more durability and elimination of frequent replacements. The performance will not be affected even in bad weather conditions. Disassembly and assembly are also easier and faster, and spare batteries can be replaced at any time. Rechargeable button cell batteries allow the appliance to run steadily for a long time, reducing various potential hazards and ensuring personal safety.

Rechargeable Button-Cell Battery

Good conductivity

The applications of rechargeable button-cell batteries usually require the coexistence of corrosive chemicals or airborne contaminants in a dry environment. Therefore, they must have good electrical conductivity. Only when their electrochemical properties are excellent will the batteries be able to perform their task.

Long life

The long life expectancy of rechargeable button-cell battery products is one of the button cell’s many advantages. Under normal conditions of use, the charge and discharge cycle can be recycled ≥400 weeks, and the capacity ≥80%. 

High-cost performance and very good conductivity

Rechargeable button-cell batteries are highly cost-effective and highly conductive. Adding some beneficial metals not only ensures power performance but also improves their cost-effectiveness, so many battery manufacturers will use this method to produce rechargeable button-cell batteries.

In general, rechargeable button-cell batteries have a significant role in preventing accidental short circuits and leaks. Chemically stable materials usually have a higher safety factor. Batteries are also more durable, and they won’t hinder performance in harsh climates. They will not leak, explode, or spontaneously combust.

All in all, the advantages of rechargeable button-cell batteries are obvious. Since rechargeable button-cell batteries are not soldered to a printed circuit board, there is no need to surround it with other components and housings as their removal is usually very simple and easy.

Contact us for customization needs at info@grepow.com

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