CN202701883U - Ultra-precision workpiece shaft system with built-in motor for drive and double encoders for feedback - Google Patents

Abstract

The utility model discloses an ultra-precision workpiece shaft system with a built-in motor for drive and double encoders for feedback, and relates to the technical field of machine tools. The ultra-precision workpiece shaft system has high precision, high speed and high position feedback resolution ratio. The specific scheme includes that the built-in motor is mounted on the outer side of a rear bearing of an ultra-precision workpiece shaft, a high-precision position feedback encoder is mounted at a position close to the built-in motor, a speed feedback encoder is mounted at the tail end of the workpiece shaft and is far away from the built-in motor, feedback signals of the two encoders are simultaneously accessed into a control system and are switched in the system as needed, and different functions are realized. The built-in motor is directly mounted on the shaft, so that the influence of a mechanical transmission link on precision can be maximally reduced. One of the two encoders for feedback is used for speed feedback control, the other encoder is used for position feedback control, two control signals are accessed into the system, the requirement of the system on interface frequency can be met, and the system is used for switching the feedback signals in different working states.

Description

Inner electric machine drives, Dual-encoder feedback ultraprecise workpiece spindle system

Technical field

The utility model relates to a kind of workpiece spindle system for ultra-precision machine tool, has very high rotating accuracy, can realize high rotating speed, also can realize very high position control accuracy simultaneously.

Background technology

Be one of core technology of Modern High-Tech's product manufacturing towards the ultraprecise processing technology of micro-structural and the research of equipment, in an increasingly wide range of applications at many high-technology fields.Wherein the workpiece spindle system is one of the most key part of ultraprecise process unit, realizes the high rotating accuracy of workpiece spindle system, and high-speed and high position feedback accuracy is significant to microstoning.Traditional workpiece spindle system adopts belt pulley to drive, motor encoder is as speed feedback device, and position feedback also is to connect external encoder by Timing Belt to realize, this structure has been introduced more frame for movement, to realizing high-speed and high accuracy has certain influence.Therefore, use of the new technology, develop more reasonable reliably ultraprecise workpiece spindle system, very important meaning is arranged.

The utility model content

The utility model purpose is that a kind of inner electric machine drives, Dual-encoder feedback ultraprecise workpiece spindle system for micro-structural ultraprecise process unit is developed, and has high-precision high-speed and high position feedback resolutions.

Concrete scheme is, a kind of inner electric machine drives, Dual-encoder feedback ultraprecise workpiece spindle system, inner electric machine is installed in the ultraprecise workpiece spindle rear bearing outside, at the workpiece spindle tail end, the high precision position feedback coder is installed in position near inner electric machine, and the workpiece spindle tail end is away from inner electric machine position installation rate feedback coder, two encoder feedback signals are access control system simultaneously, switches in system and realizes not same-action.

For reaching the purpose of design requirement, adopted the inner electric machine driving, the form of Dual-encoder feedback, inner electric machine is directly installed on the axle, can at utmost reduce the Accuracy that the mechanical transfer link is brought.Two encoders that are used for feedback, one as speed feedback control, and one two control signal connecting systems can satisfy the system interface frequency requirement as position feedback control, under the different operating state, carry out the switching of feedback signal by system.

Description of drawings

Fig. 1 is that inner electric machine drives, Dual-encoder feedback ultraprecise workpiece spindle system schematic.

Fig. 2 is the feedback control principle schematic diagram.

The specific embodiment

Drive for inner electric machine among Fig. 1, Dual-encoder feeds back ultraprecise workpiece spindle system schematic, and wherein 1 is that workpiece spindle fore bearing, 2 is that workpiece spindle rear bearing, 3 is that workpiece spindle rotating part, 4 is that workpiece spindle shell, 5 is that inner electric machine rotor, 6 is that inner electric machine stator, 7 is that position feedback encoder, 8 is the speed feedback encoder.

Inner electric machine rotor 5 is installed on the workpiece spindle rotating part 3, workpiece spindle rear bearing 2 outsides, near the workpiece spindle rear bearing, position feedback encoder 7 is installed in the position of close inner electric machine rotor 5 on the workpiece spindle rotating part 3, and speed feedback encoder 8 is installed in the tail end of workpiece spindle rotating part 3.

Two encoder feedback signals are access control system respectively, and Fig. 2 is feedback control principle figure, system's inbound pacing feedback coder feedback signal when carrying out speed control, and when carrying out Position Control, system's receiving position feedback coder feedback signal.

Claims (1)

1. an inner electric machine driving, Dual-encoder feed back ultraprecise workpiece spindle system, it is characterized in that: inner electric machine is installed in the ultraprecise workpiece spindle rear bearing outside, at the workpiece spindle tail end, the high precision position feedback coder is installed in position near inner electric machine, the workpiece spindle tail end, away from inner electric machine position installation rate feedback coder, two encoder feedback signals are access control system simultaneously, switches and uses.

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