Laboratory shakers are divided into various types, including orbital shakers, plate shakers, incubator shakers, and solar shakers.

FG orbital shakers are widely used laboratory equipment found in various laboratories, including those in pharmaceutical factories, universities, research centers, food industries, and more. By creating orbital motion, the orbital shaker provides optimal conditions for mixing samples and culture media.

Since the beginning of 2017, FG has launched a new era in the production of high-quality rotary shakers with the introduction of its latest series. Fine design details such as ergonomic bodies, ease of use, and the use of high-quality materials have positioned these shakers among the top laboratory equipment.

The designers of the FG E-series laboratory equipment have clearly aimed to meet the needs of a wide range of users while adhering to international standards. As such, features like uniform pressure and motion distribution, a digital display, smooth and uniform motion across the entire surface, exclusive CMT technology, an infrared speed counter for maintaining constant speed, and a motor protection system to prevent burnout during overloading have been incorporated.

FG’s design manager assures you that this series of orbital shakers is fully competitive with European models, and you will realize this after evaluating FG’s shakers.

One of the key features of the FG TM40 orbital shaker is the use of four cranks at the four corners of the device instead of springs. With the unique CMT system, for the first time in the world, we have replaced the four springs at the corners with four cranks.

This method ensures that no matter where the load is placed on the moving platform, the resulting pressure is evenly distributed across the entire surface, preventing pressure from being concentrated at a single point. As a result, the device maintains a smooth and stable motion, and the mixing process of solutions is performed correctly and in less time.

Additionally, since the moving platform and the device’s base are connected via cranks rather than springs, the movement of the platform does not transfer to the base. Therefore, issues such as noise, vibration, and the device moving on the table are not observed in FG laboratory shakers.

At FG, by utilizing CMT technology, we have increased the load capacity on the moving platform to 10 kilograms. Even under these conditions, the orbital shaker continues to operate smoothly and efficiently, and the device is capable of continuous operation with uninterrupted motion.