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Scientific Research

Scientific Research

Accurate Thermography Promotes the Exploration of Cutting-edge Technology

Scientific Research Application

In the field of research, accurate thermography and thermal distribution data are important parameters for quantitative analysis, which directly affect the reliability of experimental conclusions. The high-resolution infrared thermal imaging camera provides key experimental data for cutting-edge topics such as material phase change research, biothermodynamic analysis, and energy conversion efficiency evaluation, helping deeply understand the research process and phenomena and promote cutting-edge scientific and technological exploration.

High-precision

Super-resolution precise thermography, capturing subtle temperature changes to meet the accuracy requirements in scientific research

Dynamic-Thermal

Real-time recording of test processes such as heat conduction and heat convection to reveal the thermodynamic characteristics of the research object

Non-interference

Passive thermography, without interference with experimental samples and ensuring that the data is true and reliable

Multi-target

Supporting target detection from extremely low temperature to ultra-high temperature, meeting various experimental needs

GIM Helps Research and Innovation

Accelerating technology transformation: accurately analyzing thermal performance and optimizing heat dissipation design
Promoting theoretical breakthroughs: supporting the study of thermal phenomena in basic disciplines
Promoting material innovation: assisting in the study of thermal conductivity characteristics of new materials
Research on thermal distribution of biological tissues: providing thermal data for disease diagnosis and drug development

Academic Research

Infrared thermal imaging cameras have become an important research tool in university laboratories. Through non-contact precise thermography, key data support is provided for basic research such as thermodynamics and fluid mechanics. The high-resolution thermal imaging capability of infrared thermal imaging cameras allows capturing the microscopic heat conduction process, assists in understanding heat transfer and thermodynamic theory and knowledge, helps verify theoretical models, and promotes frontier exploration of disciplines.
- Observation of Disease Mechanism in Mice with Tumor
- Animal and Plant Research
- Temperature Detection in Laser Physical Experiment
Industrial R&D

In development of industrial products, infrared thermal imaging cameras can detect the thermal distribution of prototypes in real time and accurately analyze, observe, and quantify heat dissipation and thermal properties. R&D personnel use thermal imaging data to optimize circuit layout and improve mechanical structure, significantly shortening the debugging and development cycle. Moreover, it provides reliable thermal safety assessment for new energy batteries, electronic devices, etc., accelerating product iteration and upgrading.
- Crystal Chip Material Research
- Temperature Distribution Test of Silicon Carbide Sample
- Probe Temperature Detection
Material Science

Infrared thermal imaging technology can non-destructively obtain key parameters such as thermal conductivity and phase transition temperature of materials, providing an important reference for the research and development of new materials. Researchers use thermal imaging to analyze the interface thermal resistance of composite materials and observe the thermal stability of coatings, guiding the directional development of high-performance insulation materials and thermal conductive materials.
- Detecting the temperature distribution of CS@PW composite materials
- Detecting cracks in carbon fiber sheets
- Recording the temperature rise curve of superhydrophobic nanomaterials
Healthcare

The human body is a natural biological heating element, and its own heat radiation carries a large amount of health status information. Medical infrared thermal imaging is a whole-body thermal imaging technology that passively receives the metabolic heat source of human tissue cells. It can receive the heat radiation on the human body surface that cannot be seen by the human eye, objectively and accurately present the temperature distribution images of various parts of the body, and provide a reference basis for clinical diagnosis with temperature as a research latitude.
- Human Medical Research
- TCM-assisted Dialectics