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P+F Pepperl+Fuchs encoders are widely used in tobacco equipment, water conservancy equipment, power equipment, textile machinery, woodworking machinery, injection molding machinery, rubber equipment, medical equipment, CNC machine tools, metallurgical machinery, printing machinery, testing machines, elevators, motors, Food packaging equipment and other fields. okplazas.com operates P+F Pepperl+Fuchs encoders, Koyo encoders, Turck encoders, power supplies, surges, safety barriers, sensors and other world-renowned brands of industrial control products such as SICK and Phoenix. Welcome new and old users and friends to inquire about purchasing!

P+F Pepperl+Fuchs encoders, both absolute and incremental encoders, are generally used in speed control or position control system detection elements. Rotary encoders are devices used to measure speed. It is divided into single-channel output and dual-channel output. The technical parameters mainly include the number of pulses per revolution and the power supply voltage. Single output means that the output of the rotary encoder is a set of pulses, while the dual output rotary encoder outputs two sets of pulses with a phase difference of 90 degrees. The two sets of pulses can not only measure the speed, but also determine the direction of rotation. Rotary encoders can convert the rotational position or amount of rotation into analog (such as analog quadrature signals) or digital electronic signals, and are generally installed on rotating objects, such as motor shafts. Linear encoders convert linear positions or linear displacements into electronic signals in a similar way. Encoders can be divided into absolute type or incremental type. The signal of the absolute encoder divides the position into many areas, each area has its unique number, and then the number is output, which can provide clear position information without previous position information. The signal of the incremental encoder is periodic, and the signal itself cannot provide clear position information. If a certain position is used as the criterion, the signal can be counted continuously to obtain clear position information.