Technology-Leading Manufacturer Of Industrial Automation Safety Sensors

Home / All / Laser Distance Displacement Sensor /

Measuring the Thickness of Lithium Battery Electrodes Using High-Precision Laser Displacement Sensors

Measuring the Thickness of Lithium Battery Electrodes Using High-Precision Laser Displacement Sensors

Jul 19,2024

High-Precision Laser Displacement Sensors for Accurate Thickness Measurement of Lithium Battery Electrodes

As the electric vehicle market continues to expand, the demand for lithium batteries is increasing. In the production process of lithium batteries, the thickness of the electrodes is a crucial factor affecting battery performance and safety. Therefore, precise thickness measurement of lithium battery electrodes is a key aspect of the production process. In recent years, laser displacement sensors, as high-precision measuring devices, have been widely used in the thickness measurement of lithium battery electrodes. This paper will introduce the working principle, application scenarios, measurement methods, experimental results, and application prospects of laser displacement sensors in the thickness measurement of lithium battery electrodes.
usage scenarios of distance sensor

Principle of Operation for Laser Displacement Sensor

1. Laser Emission: The laser displacement sensor emits a laser beam directed at the object being measured.
2. Beam Reflection: The beam reflects off the surface of the object.
3. Beam Reception: The sensor's light-sensitive receiver captures the reflected beam, usually at a fixed angle.
4. Triangulation Method: The method is based on the principle of geometric triangulation. A laser beam is emitted by a laser source and directed towards the surface of the object being measured through a lens. The laser light reflected off the object's surface is captured by a receiver through another lens. The position of the reflected light spot on the receiver changes according to the displacement of the object. By analyzing these changes in position, the sensor calculates the displacement using geometric triangulation.
This method is well-suited for high-precision, short-distance measurements, as it can detect even minute changes in the position of the reflected light spot, enabling measurements with micrometer-level accuracy. (To learn about the differences between laser distance sensors and laser displacement sensors, please click here.)
Principle of Operation for Laser Distance Sensor
In the thickness measurement of lithium battery electrodes, laser displacement sensors can achieve high-precision thickness measurement and also detect the surface profile of the electrodes, providing strong support for quality control in the production process.

Method of Measurement for Laser Displacement Sensors

In the thickness measurement of lithium battery electrodes, the specific measurement method of the laser displacement sensor is as follows:
Method of Measurement for Laser Displacement Sensors

Thickness Measurement:

 
First, fix the laser displacement sensor on the test bench and adjust the distance between the sensor and the measured electrode to ensure that the laser beam can correctly hit the surface of the electrode. Then, operate the control system to scan the electrode with the laser displacement sensor and record the displacement data of each point. By processing and analyzing the displacement data, the thickness distribution of the electrode can be determined.

Accuracy Calibration:

 
To ensure measurement accuracy, the laser displacement sensor needs to be periodically calibrated. Generally, standard reference blocks can be used for calibration. Place the standard reference block on the test bench and adjust the position relationship between the laser displacement sensor and the reference block so that the laser beam can vertically hit the surface of the reference block. Then, operate the control system to scan the reference block with the laser displacement sensor and record the displacement data. By analyzing and processing these data, the accuracy error of the sensor can be determined and corresponding adjustments and compensations can be made.

Stability Check:

 
To ensure the reliability of measurement results, the stability of the laser displacement sensor needs to be periodically checked. Generally, long-term monitoring can be used for stability checks. Place the laser displacement sensor on the test bench to scan a fixed measured object and record the measurement data over a period. By analyzing and processing these data, the stability error of the sensor can be determined and corresponding adjustments and compensations can be made.

Advantages of Using Laser Displacement Sensors for Measurement

Through experimental results and analysis, we found that laser displacement sensors have the following advantages in the thickness measurement of lithium battery electrodes:
High Precision: The accuracy of laser displacement sensors can reach the micron level or even higher, enabling high-precision thickness measurement of lithium battery electrodes.

Non-Contact: Laser displacement sensors use non-contact measurement methods, avoiding scratches and deformation caused by contact and effectively preventing measurement errors due to contact.

Fast Measurement: Laser displacement sensors have a very fast measurement speed, allowing for the measurement of a large number of samples in a short time, greatly improving production efficiency.

High Degree of Automation: Laser displacement sensors can be used with automated production lines to achieve automated measurement and data acquisition, reducing labor costs and error rates.

Recommended Laser Displacement Sensors

GFL-Z Series Laser Displacement Sensors
Sensing Distance
Repeatability
Linearity
Output
30 mm (±5)
10 µm
±0.1%F.S.
Analog / RS485
50 mm (±15)
30 µm
NPN / Analog / RS485
100 mm (±35)
70 µm
200 mm (±80)
200 µm
±0.2%F.S.
400 mm (±200)
400 µm / 800 µm

Applications of Laser Displacement Sensors

Laser displacement sensors are versatile measurement tools capable of accurately measuring physical quantities such as length, distance, vibration, speed, and angle. Laser displacement sensors play a crucial role in applications such as small part identification, conveyor belt monitoring, material overlap detection, robotic position control, liquid level monitoring, thickness measurement, vibration analysis, collision testing, and various automotive tests.

Related Laser Displacement Sensors

Laser displacement | COMS Laser Sensor | DADISICK
By converting from the laser into electrical signals. determine various characteristics,distance, displacement, or position.
Laser displacement | COMS Laser Sensor | DADISICK
By converting from the laser into electrical signals. determine various characteristics,distance, displacement, or position.
Laser measurement distance|Laser Ranging Sensor|DADISICK
Output method: NPN/PNP+analog+RS485 Resolution: 1mm Laser type: red semiconductor laser Class II laser 655+10nm<1m Reaction time: 50-200ms Measure distance: 0.1-50m
DB-Y100 | Laser Detector Sensor | DADISICK
By converting from the laser into electrical signals. determine various characteristics,distance, displacement, or position.

DADISICK has always been committed to high-end security sensor products, focusing on technological research and development and product innovation. Our products are widely used in industries such as automation equipment, mechanical manufacturing, automobile manufacturing, and electronics manufacturing, helping to reduce the rate of industrial accidents and ensure employee safety. We continue to introduce new products that meet market demands, providing support for enterprise safety production.

*Replacement Services:In a highly competitive market, businesses need to continually improve their products to maintain market share. We provide safety sensor replacement services.

*Improving or adjusting product lines:When a company enters new markets or shifts focus, it may need to refine its product line. We offer safety sensor products and technical support for this transition.

*Automation IndustryMonitor equipment operation status, promptly halt or adjust machine actions to ensure production process safety.

*Mechanical ManufacturingMonitor mechanical motion components, prevent potential hazards, safeguard employee safety and production line smooth operation.

*Automotive ManufacturingSafety monitor high-risk processes on vehicle assembly lines, enhance worker safety and production efficiency.

*Chemical IndustryReal-time monitoring of production environment, ensure safety in handling toxic and hazardous substances.

*Food and Beverage IndustryMonitor production line equipment operation, prevent food contamination and waste.

*Logistics and WarehousingUsed for AGV navigation and obstacle avoidance, ensure safe transportation of goods.

*Wood Processing, Textile, Papermaking, Printing, Rubber, and Plastic industries, among others, safety sensors are used to monitor various production processes, ensuring safety and efficiency.