Against the backdrop of rapid advancements in global medical technology, high-resolution imaging, deep tissue observation, and high-speed data transmission have become crucial trends in modern medical equipment. With the widespread adoption of multiphoton microscopy, OCT (Optical Coherence Tomography), and advanced endoscopic systems in hospitals and research institutions, the performance requirements for core rotating connection components are constantly increasing. This is particularly true in applications where fiber optic and electrical signals need to be transmitted simultaneously, where the stability and precision of slip rings have become critical factors affecting imaging quality and diagnostic efficiency.
Based on these industry demands, JINPAT has launched a new generation of integrated slip rings combining vias and fiber optics, providing a highly stable and integrated rotating transmission solution for medical imaging equipment. This product is not simply a combination of fiber optics and an electrical slip ring, but rather an innovative achievement resulting from systematic research and structural optimization tailored to the imaging needs, signal transmission characteristics, and long-term continuous operation requirements of medical applications.
Regarding the fiber optic module, the product supports a 1700nm operating wavelength. Compared to conventional communication wavelengths, the 1700nm band exhibits lower scattering and higher penetration in biological tissues, enabling deeper and faster imaging. It has proven highly suitable for multiphoton microscopy, tissue imaging, hyperspectral detection, and other high-end biomedical optical systems. With the accelerating trend towards precision medicine, this band is becoming a key cutting-edge solution adopted by medical institutions both domestically and internationally. Furthermore, this product utilizes 200/220 large-core fiber. Compared to traditional single-mode or multimode fibers, the large-core design can withstand higher optical power input, meeting the requirements of research-grade laser systems and high-energy imaging equipment. Combined with JINPAT's precision optical path design, the product maintains an ultra-low insertion loss of ≤1dB and a loss variation of ≤0.5dB even during rotation, providing a stable and reliable optical transmission foundation for high-resolution images.
Regarding the hollow shaft structure, this slip ring boasts an extremely compact design while supporting high-speed rotation from 0 to 3000rpm, making it suitable for high-speed scanning and rotating imaging equipment. Its electrical components can stably transmit two sets of 70MHz DC high-frequency signals, enabling the system to maintain high-sensitivity and high-real-time signal feedback, meeting the precision control requirements of high-end medical equipment. The deep integration of optical, electrical, and signal channels within a single rotary interface makes the device structure simpler, more reliable, and easier to maintain.
Thanks to the high bandwidth transmission capability of optical fiber and the high stability of the via structure, this slip ring is widely applicable to various medical imaging devices, including multiphoton fluorescence microscopes, medical endoscope systems, OCT imaging equipment, and biospectral analysis instruments. Whether in research-grade experimental platforms or hospital clinical imaging systems, this slip ring provides faster data links, more stable optical path transmission, and superior image performance.
As the global medical industry continues to develop towards higher resolution, deep tissue imaging, and high-speed data processing, innovation in core components plays a crucial role in improving overall equipment performance. JINPAT is committed to the research and development of high-end rotary connection technology, using slip ring solutions with higher precision, higher stability, and higher integration to help medical institutions and research units across China and the world improve diagnostic efficiency and research capabilities. In the future, we will continue to promote the in-depth application of optoelectronic integration technology and contribute more technical strength to the upgrading of medical imaging equipment.