Semiconductor refrigeration chips have many important applications in the medical industry, such as medical imaging equipment, biological sample storage, laser medical equipment, biomedical imaging devices, etc., helping various medical devices maintain stable working temperatures and ensuring the accuracy and reliability of medical equipment.

The PCR analysis system adopts a partitioned thermal cycle module and uses semiconductor refrigeration chips for temperature rise and fall. The maximum temperature rise and fall rate is 5-7 ℃/S, which requires high stability and reliability of the semiconductor cooler.

Constant temperature metal bath, using long-life and high-efficiency semiconductor refrigeration chips, enables the instrument to have high control accuracy and smooth operation.

Applied to static CT machines, the cold surface of semiconductor refrigeration chips is physically bonded to the surface of the heat source, so that the heat source can reach the controlled working temperature and the temperature control accuracy can reach ± 0.1 ℃.

Magnetic resonance imaging (MRI) uses strong magnetic fields and radio waves to create detailed images of body organs. During the imaging process, the device itself generates a large amount of heat, which affects the imaging effect. The use of thermoelectric systems for precise temperature control of equipment can ensure its normal operation.

Centrifuges are used to separate medical samples, in order to analyze and study the material composition of the samples. When the centrifuge rotates at high speed, it also generates heat. If this heat is transferred to the sample, it will affect the quality of the sample.

Medical diagnostic reagents need to be cooled below ambient temperature to inhibit microbial growth and prevent contamination of the reagents. The thermoelectric system has the advantage of precise temperature control, which can ensure that the reagents are stable in a suitable refrigerated environment, thereby extending the service life of the reagents.

Digital microscopes measure and analyze cells in real-time by capturing high-resolution images. The stable operation of digital microscopes requires very strict temperature requirements. The thermoelectric system ensures the normal operation of equipment through precise temperature control to obtain high-quality images.