Application of nanotechnology in lithium ion battery

Lithium ion battery, as high-efficiency energy storage components, have been widely used in the field of consumer electronics. Lithium-ion batteries have been used in mobile phones and laptops. Lithium-ion batteries have achieved such brilliant results thanks to their ultra-high energy storage density. And good safety performance. With the continuous development of technology, the energy density and power density of lithium-ion batteries have also been continuously improved, among which nanotechnology has made an indelible contribution. Because LiFePO4 has poor conductivity, in order to improve its conductivity, people have prepared it into nanoparticles, which greatly improves the electrochemical performance of LiFePO4. In addition, the silicon negative electrode is also a beneficiary of nanotechnology. Nano-silicon particles can well suppress the volume expansion of Si during lithium intercalation and improve the cycle performance of Si materials.

Cathode material

1.LiFePO4 material
LiFePO4 material has good thermal stability and low cost. Due to the unique covalent bond structure inside the LiFePO4 material, the electronic conductivity of the LFP material is very low, which limits its high rate charge and discharge performance. To this end, LFP materials are made into nanoparticles and coated with materials such as conductive materials, conductive polymers, and metals. In addition, by incorporating a non-stoichiometric solid solution doping method into the nano-LFP particles, the electronic conductivity of the LFP nano-particles can be increased by 108, so that the LFP material can be charged and discharged within 3 minutes. This is particularly important for electric vehicles.

2.Inhibit LiMn2O4 material decomposition
LMO materials have three-dimensional Li + diffusion channels and therefore have a high ion diffusion coefficient. However, Mn3 + is formed in a low SoC state. Due to the existence of the Jonh-Teller effect, the LMO structure is unstable. Part of the Mn element is dissolved into the electrolyte and finally deposited on the surface of the negative electrode, which destroys the structure of the SEI film. Some low-cost main group metal ions can be added in the LMO to replace part of Mn, thereby increasing the valence state of the Mn element and reducing Mn3 + in a low SoC. The surface of the LMO material particles can also be coated with a layer of oxides and fluorides with a thickness of 10-20 nm.

3. Inhibit NMC chemical activity
The specific capacity of NMC materials, especially high-nickel NMC materials, can be as high as 200mAh / g or more, and they have very good cycle performance. However, the NMC material is extremely susceptible to oxidation of the electrolyte in the charged state. In order to suppress the reactivity of the high nickel NMC material and the electrolyte, the material is coated with nanoparticles to avoid direct contact between the material particles and the electrolyte. Greatly improved the cycle life of the material. In addition, nanoparticles with core-shell structure are also an effective method to reduce the reactivity. The high Mn shell has good stability, but the capacity is low, and the high nickel core capacity is high, but the reactivity is large.

Anode material

1.Graphite material protection
Graphite material has low lithium insertion voltage, which is very suitable as a negative electrode material for lithium ion batteries. The lithium-doped graphite has a strong reactivity and will react with organic electrolytes, causing the graphite sheet to fall off and the electrolyte to decompose. Although the SEI film can suppress the decomposition of the electrolyte, the SEI film is not 100% resistant to the graphite negative electrode. Form protection. Common graphite surface protection methods include surface oxidation and nano-coating technology.

Nano-coating technologies include three categories: amorphous carbon, metals and metal oxides. Among them, amorphous carbon is mainly obtained by a vacuum chemical deposition CVD method, which is low cost and suitable for large-scale production. Metal and metal oxide nano-coatings are mainly obtained by wet chemical methods, which can well protect graphite and prevent electrolyte decomposition.

2.Improve the rate performance of lithium titanate LTO and TiO2 materials
The LTO material has high safety, no stress will be generated during Li intercalation and deintercalation, and the lithium intercalation potential is high, which will not cause decomposition of the electrolyte. It is a very excellent anode material. However, LTO materials have low specific capacity and low electronic and ionic conductivity. At present, nanotechnology mainly uses particle nanotechnology, nanocoating technology, and LTO nanomaterials and conductive materials composite applications on LTO. LTO material nano-ization can effectively reduce the diffusion distance of Li +, increase the contact area with the electrolyte, strengthen the charge exchange, and improve the rate performance.

3. Increase the energy density of the silicon anode
The theoretical specific capacity of Si material reaches 3572mAh / g, which is much higher than that of graphite material. However, Si has a volume expansion of 300% during the process of lithium intercalation and delithiation, resulting in particle breakage and active material shedding. The Si material is made into nanoparticles in order to relieve the mechanical stress caused by the expansion of the Si particles.

Li-S batteries have high energy density and low cost, and are very promising next-generation energy storage batteries. However, the main problems Li-S batteries currently face are the low conductivity of S and the problem of dissolution of lithium intercalation products. By compounding S with porous hollow carbon or metal oxide oxide nanoparticles, the stability of S can be significantly improved and the cycling performance of the electrode can be improved. In addition, the compounding of S and graphene materials can also significantly improve the cycling performance of S negative electrodes.

Temperature Test Chambers Requirements for Refrigeration

The refrigerant in temperature test chambers should obviously meet the basic requirements of the temperature environment test, including:

(1) Standard gasification temperature (ts).
The temperature at which a refrigerant evaporates from a liquid to a gaseous state is determined by its working pressure. The temperature at which the refrigerant evaporates from a liquid to a gaseous state at standard atmospheric pressure is called the standard vaporization temperature (ts) of the refrigerant, such as the standard vaporization temperature ts of R22 = -40.8 ° C; standard gasification temperature of R502 is ts = -45.6 ° C. The lower the working pressure of the refrigerant, the lower its vaporization temperature. On the contrary, if the evaporation temperature of a refrigerant is required to reach a certain low temperature value, its working pressure must be adjusted to be lower than a corresponding pressure, and the pressure value is saturated. steam pressure.

In order to avoid the infiltration of air into the refrigeration system and reduce the cooling efficiency, the normal operating pressure of the temperature test box refrigeration system should generally be higher than the local atmospheric environmental pressure. Therefore, the standard vaporization temperature (ts) of the refrigerant is the lowest limit temperature that the temperature test chamber can reach.

(2) The condensation pressure Pk cannot be too high.
The condensing pressure Pk is the working pressure at which the high-temperature and high-pressure steam discharged from the compressor is cooled to a liquid state during condensation. This pressure is restricted by the temperature of the cooling medium and the compressor discharge pressure. The higher the compressor discharge pressure and the lower the temperature of the cooling medium, the more easily the refrigerant vapor condenses. However, increasing the discharge pressure of the compressor will not only increase the power consumption of the compressor, shorten the working life of the compressor, but also easily cause leakage of the working fluid.

On the other hand, the temperature of the cooling medium is not too low due to the limitation of the ambient temperature and the temperature of the cooling water. Generally, the inlet temperature of the cooling medium into the condenser is 24 ° C ~ 29 ° C. The temperature is 40 ° C ~ 50 ° C, and the average temperature of the cooling medium is in the range of 30 ° C ~ 50 ° C.

(3) Oil solubility and water solubility of the refrigerant.
The refrigerant should have a certain degree of oil solubility and water solubility. After the lubricant is dissolved in the refrigerant, it is beneficial to the lubrication of various operating parts in the refrigeration system, especially the liquid refrigerant with oil solubility in the condenser will take away the oil film condensed on the inner wall of the condenser due to condensation effect It can reduce the influence of the oil film on the inner wall of the condenser on the heat exchange efficiency of the condenser.

However, when the liquid refrigerant enters the evaporator with the dissolved oil, as the liquid refrigerant evaporates and gasifies, it will be installed in the evaporator in the actual refrigeration system, and the compressor's exhaust port will be equipped with oil and gas separation. Device to limit the amount of dissolved oil in the refrigerant. At the same time, in the installation of the evaporator, some oil return measures are taken.

The oil absorbed on the inner wall of the evaporator will also return to the oil pool of the compressor under the effect of gravity and the negative pressure of the compressor suction. For shell-and-tube evaporators, the return air pipe must have a certain inclination toward the compressor suction port when installing, so that the remaining oil can be sucked back into the compressor by the suction negative pressure of the compressor depending on the oil collecting effect of gravity

The infiltration of water vapor into the refrigeration system will form "ice plugs" in some parts of the low temperature section, blocking the smooth flow of refrigerant. Therefore, a "drying filter" is installed before the condenser in the refrigeration system to absorb the moisture that may seep into the refrigeration system, and when installing and maintaining the refrigeration system, increase the vacuuming time appropriately to benefit the refrigeration system. Residual moisture is evaporated and removed under vacuum. To ensure the normal operation of the refrigeration system, the use of water-soluble refrigerants can be circulated with a small amount of residual water vapor.

In addition, it is also desirable that the refrigeration unit volume of the refrigerant is large, which can reduce the size of the refrigeration unit; has a high thermal conductivity, which can reduce the heat exchange area of ​​the condenser and evaporator; low viscosity and low density, which can reduce Resistance in pipeline flow reduces pipeline pressure drop; stable chemical and physical properties, non-corrosive, non-toxic, non-combustible, non-explosive, and has certain anti-electrical properties.

In actual engineering, the lowest limit temperature of the temperature environment test chamber is generally: -40 ° C ~ -35 ° C or -75 ° C ~ -70 ° C. Condensation using the ambient temperature of the wind and surface water as the cooling medium The inlet temperature of the device is usually not higher than 30 ° C.

The Use of NQ Wireline Coring Core Barrel

The wireline coring core barrel is a drilling method for drilling the core from the drill pipe without lifting the drill. It has the characteristics of high drilling efficiency, good rock core quality, long bit life and low labor intensity. In actual work, the environment in which the rope drill is used is relatively harsh. Q series wireline core barrel have the advantages of simple structure, less wearing parts and high core-taking rate. The correct use of Q series wireline core barrel can reduce costs and improve work efficiency.
NQ Wireline Coring Core Barrel
Application range
(1) Geological conditions
NQ rope core drilling tools can be used to drill a variety of formations and work best in hard rock formations in grades 6-9. Under the current technical conditions, it is generally not advisable to drill l0~12 grade rock, especially the extremely hard rock with dense rock structure and fine particles without grinding. When drilling into the above rock, the drill bit is extremely easy to wear, the drilling efficiency is extremely low, and the superiority of the NQ wireline coring core barrel cannot be fully utilized.
(2) Drilling depth
NQ rope core drilling tools can be used in shallow holes (100 ~ 300 m) and deep holes. The deeper the drilling, the better the economic and technical effect. The maximum depth of the NQ wireline coring core barrel should be judged according to the strength of the drill rod.
(3) Bit life
The NQ rope is used for core drilling. If the drill bit used is short in life and the drill bit is often drilled during the drilling process, it is easy to lose the meaning of using the core to drill.

Use of NQ rope core drilling tools
1. Relevant technical data
(1) Drilling pressure. The NQ wireline core barrel is the bottom lip of the drill bit, which is larger than the bottom lip of the ordinary diamond drill bit (about l/4), and the required drilling pressure is increased by 25%.
(2) Speed. The rotational speed can be calculated according to the rounding speed of the ordinary diamond drill bit, but the drilling depth should be considered.
(3) Pump volume. Because the NQ wireline core barrel has a small annular gap and the bottom lip of the drill bit is large, the pump volume is calculated according to the consumption of the flushing liquid in the unit of the bottom lip of the drill bit, which is slightly larger than that of the ordinary diamond drilling.
2. Selection of rinse solution
Due to the small annulus between the NQ Wireline Coring Core Barrel and the hole wall, and the inner tube needs to be lowered through the center of the drill pipe column, water and lubricant should be used as the flushing liquid when the formation conditions permit. . Such as: polyacrylamide rinse, water glass rinse, etc. without solid phase rinse. When the drilled formation cannot use clean water as the rinsing liquid, the NQ rope core drilling still needs to use mud as the rinsing liquid. The characteristics of NQ Wireline Coring Core Barrel, the mud used in drilling should have the characteristics of low viscosity, low relative density, fast sanding, good fluidity and anti-mite performance.
The above is an introduction to the use of NQ Wireline Coring Core Barrel from PEERCHEER. If you need it, please contact us.