How to convert continuous linear motion into rotary motion

In modern industrial plants, the ability to convert the linear motion generated by hydraulic cylinders into rotary motion represents a fundamental engineering solution for simplifying mechanical systems. This transformation makes it possible to eliminate complex kinematic systems made up of multiple rigid elements connected to each other, replacing them with a more compact, efficient and easily maintainable system.

Hydraulic rotary actuators are born precisely to respond to this need, integrating into a single component the power of hydraulic cylinders and the versatility of rotary motion.

Motion conversion is not only a technical issue but often represents the key to optimising the available space, reducing maintenance costs and increasing the overall reliability of the system.

The operating principle of rotary actuators

Hydraulic rotary actuators operate according to a simple mechanical principle: a double-acting hydraulic cylinder drives a rack which, in turn, meshes with a pinion gear integral with the output shaft. When the pressurised hydraulic fluid enters the cylinder chamber, the piston moves linearly pushing the rack. This rectilinear movement of the rack rotates the pinion gear, transforming the linear thrust into rotary torque on the output shaft.

The heart of this system is the rack-and-pinion mechanism, a kinematic solution that guarantees a constant and predictable transmission ratio. Unlike other motion conversion systems, this configuration offers the advantage of generating high torques while maintaining compact dimensions.

In Conforti actuators, the presence of adjustable end-of-stroke adjusters allows phase adjustment of the system with an adjustment range of ±5°, allowing millimetric adjustments to adapt the actuator to the specifications of the application. This level of precision is decisive in applications where angular positioning must respect tight tolerances.

Advantages of simplifying kinematic systems

The replacement of complex kinematic chains with a rotary actuator brings tangible benefits on several fronts. First of all, a drastic reduction in overall dimensions is achieved: where supports, joints, levers and articulated connections were previously required, now a single integrated component performs the entire function. This compactness translates into greater design freedom and the possibility of optimising the space available on the machine.

From a maintenance point of view, the rack-and-pinion system enclosed in a single body significantly reduces the number of wear points and critical connections. Fewer components means less possibility of failure and simpler, faster maintenance interventions.

Technical characteristics and performance

Modern rotary actuators can generate significant torques while maintaining compact dimensions. The models cover a wide range of performance: from compact solutions with torques of 6 daNm up to more robust units capable of delivering 120 daNm. The typical working pressure is around 100 bar, allowing heavy loads to be managed safely.

The constructive versatility allows actuators to be made with rotation angles variable from 90° up to 270°, covering practically every application need. For each degree of rotation there corresponds a specific stroke of the internal cylinder.

The integrated adjustable cushioning systems represent a distinctive feature of particular value. This functionality is essential in applications where it is necessary to slow down moving masses.

Position control and monitoring

Technological evolution has led to the integration of detection systems that transform rotary actuators into intelligent components. Versions equipped with magnetic piston and stainless steel barrel allow magnetic sensors to be positioned along the cylinder stroke. These sensors, fixed to the tie-rods by means of specific brackets, detect the passage of the piston providing precise feedback on the angular position of the shaft.

Traditional REED or PNP magnetoresistive type sensors offer discrete signalling, ideal for confirming the achievement of preset positions. For applications requiring even more sophisticated control, there are programmable sensors capable of detecting the piston within a variable range and providing continuous position via digital signal.

These advanced devices also allow programming two circuit-closing intervals modifiable via software, even on board the machine, offering operational flexibility without mechanical interventions.

The digital connection of these intelligent sensors makes it possible to monitor additional parameters such as the working temperature, enabling predictive maintenance based on the actual operating conditions. This level of information integrates perfectly with modern industrial automation systems, contributing to the digitalisation of production plants.

Conclusions

This technology eliminates the complexity of articulated mechanical systems, offering the designer a versatile tool that combines power, precision and ease of maintenance. The progressive integration of intelligent detection systems is further expanding the application possibilities, making these components increasingly central in modern automation systems.

For applications requiring rotary motion, evaluating the use of hydraulic rotary actuators can lead to more efficient and reliable solutions. The experience of Conforti Oleodinamica in the design of hydraulic cylinders makes it possible to identify the optimal configuration for each specific need, guaranteeing high performance and durability over time.

For technical insights on selecting the most suitable components for your applications, you can consult the complete range of ISO 6020/2 cylinders and compact cylinders, complementary solutions that, integrated with rotary actuators, allow complete and high-performance hydraulic systems to be realised.