CN203804645U - Adjustable rigidity and frequency micro-feeding device based on movable supporting - Google Patents

Abstract

The utility model relates to equipment for processing optical free-form surfaces with the principle of fast knife servo. The utility model specifically relates to a micro-feed device with adjustable stiffness and frequency based on mobile support. The elastic film group is arranged on both sides of the micro-motion workbench, and The micro-motion table is fixed in the base, the drive motor is fixed on the bottom plate, and its motor shaft is connected to the base; it also includes a stepping motor, a claw plate and a bidirectional ball screw mechanism; the bidirectional ball screw mechanism is along the direction of the film group , installed on the base through bearings, the stepping motor is connected with the bidirectional ball screw mechanism; the two claw plates are respectively fixed on the moving parts of the bidirectional ball screw structure, and are respectively located on both sides of the base. The claw groove is arranged in the direction of the film group, and the film group is clamped in the claw groove. The utility model adopts the above-mentioned structure, adjusts the moving support position of the film, and realizes the adjustment of the natural frequency. Compared with the adjustment of the pre-tightening force, the energy consumption is small.

Description

Micro-feeding device with adjustable stiffness and frequency based on mobile support

technical field

The utility model relates to equipment for processing optical free-form surfaces by using the fast knife servo principle. The utility model specifically relates to a micro-feeding device with adjustable stiffness and frequency based on a moving support.

Background technique

In order to achieve precise processing of optical free-form surfaces, precise and stable feed mechanism is particularly important, because it is closely related to the quality of the product. In addition, due to the small size and high precision of the complex optical free-form surface, strict requirements are put forward for the micro-feed mechanism. The micro-feed system is the basis for processing such products, and it is widely used in fast-tool servo feed systems, micro-motion worktables, and macro-micro composite platforms. The traditional micro-feeding device usually adopts a fixed frequency design, but when processing different products, its driving frequency usually changes, which will lead to inconsistent displacement amplification factors, resulting in distortion of displacement amplification. In addition, due to manufacturing and assembly errors, the actual frequency often does not match the design frequency.

Prior art patent number: 201210250524.7 discloses such a fast servo device: the main components of the overall structure of the fast knife servo device include a base, a prestressed film, a micro-motion table, a rotating beam and a piezoelectric driver. The displacement generated by the piezoelectric driver acts on the rotating beam, and the rotating beam drives the movement of the micro-motion table supported by two prestressed films through the flexible hinge. Due to the restraint of the pre-stressed film, the vertical movement of the micro-motion table is suppressed. The main movement produced is the horizontal movement required by the fast tool servo. This device can change the natural frequency of the fast knife servo system by adjusting the pre-tightening force of the pre-stressed film to meet the needs of different driving frequencies of the piezoelectric actuator. This technology overcomes the problem that the frequency of the micro-feeding device cannot be adjusted, but there are two defects in dynamically adjusting the pre-tightening force during work: 1. Excessive energy consumption will be generated; 2. Excessive temperature will be generated, which will affect the fast servo accuracy of the device.

Utility model content

The purpose of this utility model is to propose a micro-feeding device with adjustable stiffness and frequency based on mobile support, which can adjust the natural frequency of the structure according to different driving frequencies, and dynamically adjust the pretightening force during work. The energy consumption is low and the temperature is low. It will not affect the precision of the micro-feeding device.

For this purpose, the utility model adopts the following technical solutions:

A micro-feeding device with adjustable stiffness and frequency based on mobile support, including a base, a bottom plate, a micro-movement table, a film group and a driving motor, the base is fixed on the bottom plate, and the elastic film group is set on the on both sides of the micro-motion workbench, and the micro-motion workbench is fixed in the base, the drive motor is fixed on the base plate, and its motor shaft is connected to the base;

It also includes a stepping motor, a claw plate, and a bidirectional ball screw mechanism; the bidirectional ball screw mechanism is installed on the base through a bearing along the direction of the film group, and the stepping motor and the bidirectional ball screw mechanism Screw mechanism connection;

The two claw plates are respectively fixed on the moving parts of the bidirectional ball screw structure, and are respectively located on both sides of the base. The claw plates are provided with claw grooves arranged along the direction of the film group, so that The film group is clamped in the claw groove.

It also includes a capacitive plate group located at the end of the micro-motion worktable in the feeding direction; the capacitive plate set includes two electrodes arranged in parallel and fixed to the micro-motion worktable and the base respectively.

An insulating layer is provided on the non-working surfaces of the two parallel electrodes.

The driving motor is fixed to the bottom plate through the driving motor seat.

The stepping motor is fixed on the bottom plate through the stepping motor seat.

The bearing is fixed on the base through a bearing seat.

The base, the micro-movement workbench and the film group are of an integrated structure.

The one-piece structure is made of metal.

The one-piece structure is fixed to the bottom plate by bolts.

The driving motor is a voice coil motor.

The utility model adopts the above-mentioned structure, which can adjust the natural frequency of the structure according to different driving frequencies, and dynamically adjusts the pretightening force during operation, which consumes less energy, has low temperature, and does not affect the precision of the micro-feeding device.

Description of drawings

Fig. 1 is a top view structural diagram of an example of the utility model.

Fig. 2 is a schematic structural view of an example of the utility model viewed from above.

Fig. 3 is a deformation schematic diagram of an example of the present film set.

Among them: bearing seat 1, base 2, bottom plate 3, micro-motion table 4, film group 5, stepping motor seat 6, stepping motor 7, driving motor seat 8, driving motor 9, bearing 10, claw plate 11, Two-way ball screw mechanism 12, capacitor plate group 13, insulating layer 14.

Detailed ways

The technical scheme of the utility model will be further described below in conjunction with the accompanying drawings and through specific embodiments.

As shown in Figures 1 to 2, the micro-feeding device based on the frequency-adjustable stiffness of the mobile support includes a base 2, a base plate 3, a micro-motion table 4, a film group 5 and a drive motor 9, and the base 2 Fixed on the bottom plate 3, the elastic film group 5 is arranged on both sides of the micro-motion table 4, and the micro-motion table 4 is fixed in the base 2, and the driving motor 9 is fixed On the bottom plate 3, its motor shaft is connected to the base 2;

It also includes a stepper motor 7, a claw plate 11 and a bidirectional ball screw mechanism 12; the bidirectional ball screw mechanism 12 is installed on the base 2 through a bearing 10 along the direction of the film group 5, and the step The feed motor 7 is connected to the bidirectional ball screw mechanism 12;

The two claw plates 11 are respectively fixed on the moving parts of the two-way ball screw structure 12, respectively located on both sides of the base 2, and the claw plates 11 are arranged along the direction of the film group 5. The claw groove, the film group 5 is clamped in the claw groove.

The drive motor 9 is used to drive functional components such as cutters installed on the inching workbench 4, and the micro-feed generated acts on the parts to be processed, so that the functional components such as cutters process the workpieces to be processed. Due to the restraining effect of the film group 5, the movement of the micro-motion table 4 in the non-feed direction is suppressed, and the drive motor 9 can only produce a small displacement in the feed direction, causing the micro-motion table 4 to produce displacement in the feed direction , so as to drive the cutting tool into or out of the knife; and the film group 5 is an elastic metal sheet, so that the micro-motion table 4 has a fixed vibration frequency, which matches the operating frequency of the drive motor 9 .

The stepping motor 7 drives the two-way ball screw mechanism, so that the claw discs 11 arranged on both sides of the micro-motion table 4 move toward each other along the direction of the film group 5, changing the film The effective deformation length of the group 5, so as to adjust the natural frequency of the micro-motion table 4.

It also includes a capacitor plate group 13 located at the end of the feeding direction of the micro-movement table 4; the capacitor plate group 13 includes two electrodes arranged in parallel, fixed on the micro-motion table 4 and the The base 2 is described. It is used to detect the displacement of the micro-motion table 4.

An insulating layer 14 is provided on the non-working surfaces of the two parallel electrodes. It is used to prevent the capacitive plate set 13 from being interfered by other metals and affecting its measurement accuracy.

The driving motor 9 is fixed to the bottom plate 3 through the driving motor base 8 .

The stepping motor 7 is fixed on the bottom plate 3 through the stepping motor base 6 .

The bearing 10 is fixed on the base 2 through the bearing housing 1 .

The base 2, the micro-movement table 4 and the film set 5 are of an integrated structure. The base 2, the micro-movement workbench 4 and the film group 5 are obtained by milling and EDM processes of the whole material, which avoids assembly errors in parts assembly, is simple to process, and improves the precision of the micro-feeding device.

The one-piece structure is made of metal.

The one-piece structure is fixed to the bottom plate 3 by bolts.

The driving motor 9 is a voice coil motor.

As shown in Fig. 3, described membrane group 5 is fixed according to the rigidity formula of one end guide beam:

${\mathrm{<span\; class="notranslate">\; k</span>}}_{\mathrm{<span\; class="notranslate">\; b</span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; f</span>}}{{\mathrm{<span\; class="notranslate">\; the\; y</span>}}_{\mathrm{<span\; class="notranslate">\; max</span>}}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; 12</span>}\mathrm{<span\; class="notranslate">\; EI</span>}}{{\mathrm{<span\; class="notranslate">\; L</span>}}^{\mathrm{<span\; class="notranslate">\; 3</span>}}}$

Among them, F is the force, y _max is the deformation displacement distance of the guide beam end in the Y-axis direction, E is the elastic modulus of the material, I is the bending stiffness, and L is the length of the deformed beam. E is affected by the characteristics of the material, and there will be deviations for different batches of materials. The moment of inertia I is proportional to the width of the beam section, and proportional to the cubic equation of the height of the section. It is affected by the machining accuracy, especially the thickness, and the machining error has a great influence on the stiffness. L is the length of the deformation section, and the film group 5 changes the length of the deformation section L by moving the support, so as to realize adjustment of stiffness and frequency.

The technical principles of the present utility model have been described above in conjunction with specific embodiments. These descriptions are only for explaining the principle of the utility model, and cannot be construed as limiting the protection scope of the utility model in any way. Based on the explanations herein, those skilled in the art can think of other specific implementations of the present utility model without creative work, and these forms will all fall within the protection scope of the present utility model.

Claims (10)

1. A micro-feeding device with adjustable stiffness and frequency based on mobile support, including a base, a bottom plate, a micro-motion workbench, a film group and a drive motor, the base is fixed on the bottom plate, and the elastic film group is set on The two sides of the micro-motion worktable, and the micro-motion worktable is fixed in the base, the drive motor is fixed on the bottom plate, and the motor shaft is connected to the base, and it is characterized in that: It also includes a stepping motor, a claw plate, and a bidirectional ball screw mechanism; the bidirectional ball screw mechanism is installed on the base through a bearing along the direction of the film group, and the stepping motor and the bidirectional ball screw mechanism Screw mechanism connection; The two claw plates are respectively fixed on the moving parts of the bidirectional ball screw structure, and are respectively located on both sides of the base. The claw plates are provided with claw grooves arranged along the direction of the film group, so that The film group is clamped in the claw groove. 2. The micro-feeding device based on the adjustable stiffness frequency of the mobile support according to claim 1, characterized in that: it also includes a capacitor plate group, which is located at the end of the micro-motion worktable in the feeding direction; The capacitor plate group includes two electrodes arranged in parallel, which are respectively fixed on the micro-movement table and the base. 3 . The frequency-adjustable micro-feeding device based on a mobile support according to claim 2 , wherein an insulating layer is provided on the non-working surfaces of the electrodes arranged in parallel. 4 . 4 . The micro-feeding device with adjustable stiffness and frequency based on a mobile support according to claim 1 , wherein the drive motor is fixed to the bottom plate through the drive motor mount. 5 . The micro-feeding device with adjustable stiffness and frequency based on a mobile support according to claim 1 , wherein the stepping motor is fixed to the bottom plate through the stepping motor mount. 6 . 6 . The micro-feeding device with adjustable stiffness and frequency based on mobile support according to claim 1 , wherein the bearing is fixed to the base through a bearing seat. 7 . 7. The micro-feeding device with adjustable stiffness and frequency based on the mobile support according to claim 1, characterized in that: the base, the micro-movement table and the film group are of an integrated structure. 8. The micro-feeding device with adjustable stiffness and frequency based on the mobile support according to claim 7, characterized in that: the integrated structure is made of metal. 9. The micro-feeding device with adjustable stiffness and frequency based on a mobile support according to claim 7, characterized in that: the integrated structure is fixed to the bottom plate by bolts. 10. The frequency-adjustable micro-feeding device based on a mobile support according to claim 1, wherein the driving motor is a voice coil motor.