CN204366662U - Radius of curvature adjustable aspheric surface concavees lens processing unit (plant) - Google Patents

Abstract

The utility model relates to a kind of radius of curvature adjustable aspheric surface concavees lens processing unit (plant), belongs to Precision Machining field.By DC servo motor and piezoelectric actuator grand dynamic/feeding mode that combines of fine motion, in conjunction with the directed movement joint of revolution motion unit, can realize processing the accurate adjustment of the radius of gyration, the realization of spherical grinding machine head revolution motion relies on swinging supporter and the spinning motion motor rotary freedom at two orthogonal directions.Meanwhile, by the accurate servo-actuated adjustment to concavees lens test specimen vertical direction height, the adjustment of the radius of curvature of processed lens can also be realized.The utility model adopts vertical structure, compact, compact in design, its overall dimensions is little, effectively can improve the efficiency of existing aspherics lens grinding technology processing, be applicable to the Precision Machining of microminiature aspheric surface concavees lens optics, to widen the application of microminiature non-spherical lens in fields such as space flight and aviation, military system and optical communications.

Description

Radius of curvature adjustable aspheric surface concavees lens processing unit (plant)

Technical field

The utility model relates to Precision Machining field, particularly non-spherical lens accurate grinding manufacture field, espespecially a kind of radius of curvature adjustable aspheric surface concavees lens processing unit (plant).The aspheric surface concavees lens gone out by this device grinding effectively can improve the effect that aberration corrected by spherical lens, improve image quality, improve system distinguishing ability.Non-spherical lens is very extensive in the application of space flight and aviation, photographing, military system, optical communication and laser application, the utility model because of its compact conformation, with low cost, operate simple and easy, working (machining) efficiency is high, the manufacture that can be microminiature aspheric surface concavees lens provides processing method.

Background technology

Application aspherics components and parts can increase the free degree of optical design, and to improving optical system imaging quality, improve optical property, and reduction appearance and size and weight play an important role.The process technology of small aspherical optics mainly comprises that computer controlled grinding is shaping, ion beam polishing method, compression molding method, Vacuum Coating method, accurate one-point diamond turning etc.At present, method mainly polishing and the compression molding method of processing small aspherical lens, and ion polishing method and Vacuum Coating method are mainly used to process larger reflective asperical.Polishing is the basic processing method of Aspheric optics.According to the basic character of grinding tool and parts, polishing can be divided into point cantact, linear contact lay to contact three kinds with face.General point cantact manufacture method machining accuracy is lower, be mainly used in the thick processing and forming of process of lapping, and the linear contact lay accuracy of manufacture is slightly high, and the accuracy of manufacture of face contact is the highest.Polishing generally realizes by process equipments such as cam profiling machine and Digit Control Machine Tools.For undersized Aspheric optics, generally adopt Digit Control Machine Tool grinding shaping in advance, and then utilize manual finishing method shaping, if high-precision requirement, be then accompanied by inspection in this process and repair band technique.Compression-moulding methods is mainly for plastics optics parts.The optical element produced by this processing method, can be used as general condenser and comparatively easy optical system lens.The plastic aspheric lens great majority of current domestic production adopt metal die hot-forming, as Fresnel lens magnifier and Shi Mite rectification plate.Along with the development of high-precision metal mould, occurred at present meeting the metal die that the surface roughness requirements of optical element and curve form require, the plastic aspherical element optical element therefore adopting compression molding to manufacture can Substitute For Partial glassy state optical element to a certain extent.

As previously mentioned, the main machining method that non-spherical lens process technology adopts is computer controlled grinding and polishing technology, compression molding technology and Ultra-precision diamond turning etc.

(1) computer controlled grinding and polishing technology

Computer controlled grinding and polishing technology develop from computer control optical surface formation technology (CCOS).CCOS technology is the technological thought proposed at first at the seventies initial stage by American I tek company.Its ultraprecise system grinding machine tool that computerizeds control forms grinding to workpiece, and then with the polishing of flexible polishing equipment, while raising fine grinding surface figure accuracy, change surface of the work raw sugar degree, makes it reach optical element quality standard.The general principle of this technology is: the face graphic data detected according to surface characterization test instrument, create the Controlling model of processing, profit computerizeds control small abrasive nose at the residence time of surface of the work and relative pressure to control the removal amount of material, thus realizes carrying out polishing to workpiece.

(2) compression molding technology

Compression molding technology is a comprehensive stronger processing method needing specific lathe, is mainly applicable to the materials such as glass.Under the condition of HTHP and anaerobic, softening optical material is put into high-precision mold, and direct mold pressing goes out to reach the forming part of optical standard.From 20th century the eighties develop this technology 30 years so far nearly mid-term, compression molding technology to have become in manufacturing industry one of comparatively advanced process technology, and is used widely in many countries.Because optical material directly can be molded into precision optical system element by this technology, greatly reduce manufacturing cost, make the optical element of aspherical glass material start to be used widely in optical system, also bring great variety and development to electro-optical system design.This technology not only makes the reduction of optical device weight, volume reduces, material is saved, optical element crosses film and the workload of workpiece assembling reduces, cost reduction, but also improves the quality of optical system imaging, improves the performance of optical system.The feature of die pressing is: 1. can mass production non-spherical lens; 2. Making mold difficulty is large, cost is high, is applicable to super large batch production; 3. the mold pressing of Large diameter cannot be carried out; 4. technological parameter is complicated, as temperature, time, pressure etc.

(3) ultraprecise numerical control Single point diamond turning o

Turning aspheric surface Ultra-precision Turning equipment used is Ultra-precision diamond lathe, its slide carriage kinematic accuracy and main shaft running accuracy higher than general Digit Control Machine Tool a lot.Ultra-precision diamond lathe is the important equipment processing high-accuracy optical element.Ultra-precision diamond lathe is mainly used in small-medium size, the infrared crystal of medium-sized batches and the processing of metal material optical element, be characterized in that machining accuracy is high, production efficiency is high, reproducible, processing cost process with tradition compared with obvious reduction, be applicable to batch production.

Although current aspheric surface processing technology is own, through very ripe, for the fragile material such as silicon, glass, Single point diamond turning o is difficult to obtain comparatively ideal aspheric surface, and the wearing and tearing of diamond bit are very serious, and processing cost is high, efficiency is low; The required precision of compression molding method to metal die is higher, the plastic aspherical element workpiece that applicable machining accuracy is lower; And the equipment that ion beam polishing method needs and processing cost higher, and efficiency is low, and these processing methods are all not suitable for for processing aspheric surface concavees lens.During numerical control device processing aspheric surface concavees lens, relatively, therefore when processing the material of this characteristic, easily there is the phenomenons such as Brittle Failure in the yield limit of, poor toughness, intensity and material hard and crisp due to material.Therefore, the aspheric surface processing technology generally used for fragile material is at present grinding, polishing technology.Computer controlled grinding machining method for aspheric surface belongs to fixed abrasive material processing, has processing certainty, the advantage such as reproducible.This technology utilizes that dish type or cup emery wheel can be processed in enormous quantities, medium caliber and the more small-bore non-spherical lens of aspherical degree.But many difficulties are also existed for the lens processing of reduced size.Utilize the machinable material type of Ginding process various, except the fragile materials such as monocrystalline germanium, monocrystalline osmanthus, glass, non-ferrous metal and other plastic or other material can also be processed with.And polishing is the procedure that in the aspheric surface production cycle, holding time is the longest, the polishing technology of optics is the minor material removal processing method on not damaged surface, and aspheric surface polishing precision directly affects the image quality of optical system.

To sum up, for the present Research at aspheric surface concavees lens manufacture field such as above-mentioned computer controlled grinding and polishing technology, compression molding technology and Single point diamond turning o technology, the development of aspheric surface concavees lens processing unit (plant) is faced with many-sided requirements such as miniaturized structure, working (machining) efficiency lifting, cost reduction, precision raising.Therefore, design is a kind of is used for compact conformation, compact, equipment and manufacturing cost lower, machining accuracy and the higher radius of curvature adjustable aspheric surface concavees lens processing unit (plant) of efficiency very necessary.

Summary of the invention

The purpose of this utility model is to provide a kind of radius of curvature adjustable aspheric surface concavees lens processing unit (plant), solves the problems referred to above that prior art exists.The utility model adopts vertical layout, size of main body is 82mm × 82mm × 263mm, accurate controlled feeding displacement is exported by grand Fine Feed unit, can be adjusted the processing radius of gyration of spherical grinding machine head and the radius of curvature of concavees lens test specimen respectively by revolution motion unit and spinning motion unit, the lens Installation and adjustment unit of device possesses three-axis accurate adjustment of displacement function.The utility model is applicable to the Precision Machining of microminiature aspheric surface concavees lens optics, have compact conformation, with low cost, operate simple and easy, that working (machining) efficiency is high and portable feature, the manufacture that can be small aspherical concavees lens provides processing method.

Above-mentioned purpose of the present utility model is achieved through the following technical solutions:

Radius of curvature adjustable aspheric surface concavees lens processing unit (plant), comprise grand Fine Feed unit, revolution motion unit, spinning motion unit, lens Installation and adjustment unit, cooling unit and supporting base unit, feeding motor flange 40 wherein in grand Fine Feed unit and feeding bracing frame 36 are rigidly connected with the upper mounting plate 4 in supporting base unit and right side riser 37 screw thread respectively, orientation revolution rotary joint 13 in revolution motion unit and directional swing joint 14 are rigidly connected with the flexible hinge 32 in grand Fine Feed unit and the spinning motion motor 42 in spinning motion unit respectively by revoluting motor flange 30 and spinning motor flange 15, swinging supporter 27 in spinning motion unit is connected with the unit left side vertical plate 5 of supporting base and the center positioning hole interference of right side riser 37 respectively by outer oscillation bearing 16, mobile platform substrate 46 in lens Installation and adjustment unit is threaded connection mode and is arranged in the spill locating slot of pedestal 20 in supporting base unit, and the cooling liquid container 9 in cooling unit is by being rigidly connected with left side vertical plate 5 screw thread in supporting base unit,

Described grand Fine Feed unit comprises encoder 1, DC servo motor 2, decelerator 3, feeding motor flange 40, shaft coupling 6, ball-screw fixed supporting seat 7, ball-screw 8, piezoelectric stack 31, flexible hinge 32, guide rail slide block 33, leading screw flange 34, linear guides 35, feeding bracing frame 36 and brake 39, wherein DC servo motor assembly realizes the feed motion of directed revolution rotary joint 13 at vertical direction in conjunction with ball-screw-transmission assembly as grand dynamic feeding subelement, the piezoelectric actuator be made up of piezoelectric stack 31 and flexible hinge 32 realizes the precise jiggle feeding of directed revolution rotary joint 13 at vertical direction, brake 39 is for preventing freely gliding of ball-screw-transmission assembly causes owing to realizing self-locking under the unexpected powering-off state of system leading screw flange 34, flexible hinge 32 adopts arc transitional type hinge format and exports the uniform displacement of constant amplitude,

Described revolution motion unit comprises revolution disc type electric machine 12, directed revolution rotary joint 13, directional swing joint 14 and revoluting motor flange 30, described directional swing joint 14, revoluting motor flange 30 are rigidly connected with spinning motor flange 15, flexible hinge 32 respectively, and directed revolution rotary joint 13, directional swing joint 14 are by precise rolling bearing and rotation alignment pin composition;

Described spinning motion unit comprises spinning motor flange 15, outer oscillation bearing 16, swinging supporter 27, outer swinging axle 28, interior oscillation bearing 29, spinning motion motor 42 and interior movable pendulum axle 43, described swinging supporter 27 is rigidly connected with outer swinging axle 28, stationary part and the interior swinging axle 43 of spinning motion motor 42 are rigidly connected, and outer swinging axle 28, interior swinging axle 43 are socketed in the locating hole of left and right side riser 5,37 and swinging supporter 27 respectively by outer oscillation bearing 16, interior oscillation bearing 29;

Described lens Installation and adjustment unit comprises concavees lens test specimen 17, workbench 25, spherical grinding machine head 26 and Three Degree Of Freedom feeding subelement, described Three Degree Of Freedom feeding subelement comprises x to adjustment knob 18, x to feeding platform 19, y to adjustment knob 21, y to feeding platform 22, z to feeding platform 23, alignment pin 45, z to feeding motor 46, support supporting plate 24 and mobile platform substrate 46, described spherical grinding machine head 26 is socketed by the rotating shaft of its locating hole and spinning motion motor 42, supports supporting plate 24 and is rigidly connected with workbench 25 screw thread; Three Degree Of Freedom feeding subelement is carried out initial alignment to workbench 25 and is realized the change of processed concavees lens test specimen 17 radius of curvature by the vertical direction displacement of servo-actuated adjustment workbench 25;

Described cooling unit comprises cooling liquid container 9, cooling liquid container trip bolt 10 and cooling tube 11, described cooling liquid container 9 is rigidly connected by cooling fluid trip bolt 10 and left side vertical plate 5, and and install with right side riser 37 rigidly connected feeding bracing frame 36 symmetry, thus play counterweight effect; Cooling tube 11 is flexible hose, and its initial position is in the edge near-end of processed concavees lens test specimen 17; The flow of cooling fluid increases with the raising of revolve round the sun disc type electric machine 12 and spinning motion motor 42 rotating speed;

Described supporting base unit comprises upper mounting plate 4, left side vertical plate 5, pedestal 20, right side riser 37 and riser mounting screw 38, described upper mounting plate 4 and pedestal 20 are equipped with and left and right side riser 5,37 wide and rectangle locating slots be arranged symmetrically with, to realize the parallel installation of left side vertical plate 5 and right side riser 37 and to ensure the depth of parallelism of itself and upper mounting plate 4 and pedestal 20.

Described flexible hinge 32 and piezoelectric actuator realize vertical direction, and namely z moves to Fine Feed, and described flexible hinge 32 has envelope structure in cylinder ring form, and described piezoelectric actuator is made up of the piezoelectric stack 31 of four xy plane annular array arrangements; When high frequency excitation voltage acts on four piezoelectric stacks 31 simultaneously, this driver exports the uniform displacement of high frequency constant amplitude, can realize the high-frequency reciprocating grinding of spherical grinding machine head 26 pairs of concavees lens test specimens 17; Maximum effective output displacement of described piezoelectric actuator is 42.1 μm, and corresponding to spherical grinding machine head 26 at horizontal plane, the maximum displacement namely on xy plane and vertical direction is respectively 24.2 μm and 6.8 μm.

Described orientation revolution rotary joint 13, directional swing joint 14 all can provide the swing free degree of a direction of rotation; After grand Fine Feed unit exports the drive displacement determined, with grand Fine Feed unit final drive assembly---flexible hinge rigidly connected revolution disc type electric machine 12 exports identical displacement, vertical displacement is changed by the motion in revolution rotary joint 13 and directional swing joint 14, realize the accurate adjustment to the radius of gyration of spherical grinding machine head 26 circus movement track, namely processing object of the present utility model can contain the concavees lens test specimen 17 of different-diameter size; The range of work of the utility model attainable concavees lens test specimen 17 diameter is 7.2mm-26.3mm, and directed revolution rotary joint 13 and the attainable pendulum angle scope in directional swing joint 14 are respectively 90 °-180 ° and 72 °-180 °.

The processing radius of curvature of the non-spherical surface part of described concavees lens test specimen 17 is adjustable, after feeding displacement is determined in grand Fine Feed unit output, the revolution motion radius of spherical grinding machine head 26 is determined thereupon, namely the circular motion track of spherical grinding machine head 26 is determined, after z determines angular displacement to feeding motor 45 output, workbench 25 drives concavees lens test specimen 17 in the vertical direction to produce displacement, spherical grinding machine head 26 increases with the contact area of concavees lens test specimen 17 or reduces, corresponding grinding amount also increases or reduces, corresponding to the different feeding displacements that grand Fine Feed unit exports, the revolution motion radius of spherical grinding machine head 26 changes thereupon, by adjusting the vertical direction displacement of concavees lens test specimen 17 further, realize the accurate continuous setup to concavees lens test specimen 17 radius of curvature.

Described left side vertical plate 5 and right side riser 37 are all processed with at the geometric centre axes place closing on spherical grinding machine head 26 longitudinal stripe that width is 1mm, immediately below this striped, the side that workbench 25 closes on left side vertical plate 5 and right side riser 37 is also processed with horizontal rectangular channel that width is 3mm and width is the longitudinal stripe of 1mm, the length of rectangular channel is longer than the processing diameter of concavees lens test specimen 17 so that guarantee the uniformity of the central point of concavees lens test specimen 17 and the geometric center of workbench 25, the longitudinal stripe of workbench 25 also with left side vertical plate 5, the longitudinal stripe of right side riser 37 keeps alignment to guarantee that the geometric center of workbench 25 is on the connection axis of two longitudinal stripes.

Described workbench 25 table top is processed with intensive array hole position, workbench 25 is realized by one group of alignment pin 44 be arranged in locating hole with the relative position of concavees lens test specimen 17, and alignment pin 44 contacts with the cylindrical bus retention wire of concavees lens test specimen 17; Spherical grinding machine head 26 is processed with mutually perpendicular two fine thread holes, the output shaft end of spinning motion motor 42 has mutually perpendicular two plane of orientations, and spherical grinding machine head 26 is socketed by two bolt of serrations and is fixedly mounted in the rotating shaft of spinning motion motor 42.

Described spherical grinding machine head 26 revolution motion is by revolution disc type electric machine 12, outer oscillation bearing 16, swinging supporter 27, outer swinging axle 28, interior oscillation bearing 29 and interior swinging axle 43 realize, described swinging supporter 27 realizes the oscillating motion of spherical grinding machine head 26 single direction by outer oscillation bearing 16 and outer swinging axle 28, 42, spinning motion motor realizes the oscillating motion of spherical another single vertical direction of grinding machine head 26 by interior oscillation bearing 29 and interior swinging axle 43, the continuous torque exported in conjunction with revolution disc type electric machine 12 and angular displacement, spherical grinding machine head 26 realizes continuous print speed change circular motion, the speed of circular motion depends on the angular speed that revolution disc type electric machine 12 exports.

The size of main body of described radius of curvature adjustable aspheric surface concavees lens processing unit (plant) is 82mm × 82mm × 263mm.

The beneficial effects of the utility model are: compared with existing apparatus, the utility model have compact conformation, compact, can portability, working (machining) efficiency high, size of main body is 82mm × 82mm × 263mm, be applicable to the Precision Machining of microminiature aspheric surface concavees lens optics, the diameter range can processing concavees lens test specimen is 7.2mm-26.3mm.In addition, concavees lens test specimen of the present utility model is installed convenient, spherical grinding machine head and is easily realized changing, the radius of curvature continuously adjustabe of the processing radius of gyration and concavees lens test specimen, effectively can improve the efficiency of existing aspherics lens grinding technology processing, to widen the application of microminiature non-spherical lens in fields such as space flight and aviation, military system and optical communications.Practical.

Accompanying drawing explanation

Accompanying drawing described herein is used to provide further understanding of the present utility model, forms a application's part, and illustrative example of the present utility model and explanation thereof, for explaining the utility model, are not formed improper restriction of the present utility model.

Fig. 1 is overall appearance structural representation of the present utility model;

Fig. 2 is grand dynamic feeding subelement schematic diagram of the present utility model;

Fig. 3 is micrometer feed subelement of the present utility model, revolution motion unit and spinning motion cell schematics;

Fig. 4 is spherical grinding machine head installation method schematic diagram of the present utility model;

Fig. 5 is concavees lens test specimen localization method schematic diagram of the present utility model;

Fig. 6 is lens Installation and adjustment cell schematics of the present utility model;

Fig. 7 is the schematic diagram that the utility model utilizes longitudinal direction and travers and positions concavees lens test specimen position;

Fig. 8, Fig. 9 are the principle schematic of radius of machining of the present utility model adjustment and radius of curvature adjustment.

In figure: 1, encoder; 2, DC servo motor; 3, decelerator; 4, upper mounting plate; 5, left side vertical plate; 6, shaft coupling; 7, ball-screw fixed supporting seat; 8, ball-screw; 9, cooling liquid container; 10, cooling liquid container trip bolt; 11, cooling tube; 12, revolve round the sun disc type electric machine; 13, directed revolution rotary joint; 14, directional swing joint; 15, spinning motor flange; 16, outer oscillation bearing; 17, concavees lens test specimen; 18, x is to adjustment knob; 19, x is to feeding platform; 20, pedestal; 21, y is to adjustment knob; 22, y is to feeding platform; 23, z is to feeding platform; 24, supporting plate is supported; 25, workbench; 26, spherical grinding machine head; 27, swinging supporter; 28, outer swinging axle; 29, interior oscillation bearing; 30, revoluting motor flange; 31, piezoelectric stack; 32, flexible hinge; 33, guide rail slide block; 34, leading screw flange; 35, linear guides; 36, feeding bracing frame; 37, right side riser; 38, riser mounting screw; 39, brake; 40, feeding motor flange; 41, hinge installing rack; 42, spinning motion motor; 43, interior swinging axle; 44, alignment pin; 45, z is to feeding motor.

Detailed description of the invention

Detailed content of the present utility model and detailed description of the invention thereof is further illustrated below in conjunction with accompanying drawing.

See shown in Fig. 1 to Fig. 9, radius of curvature of the present utility model adjustable aspheric surface concavees lens processing unit (plant), comprise grand Fine Feed unit, revolution motion unit, spinning motion unit, lens Installation and adjustment unit, cooling unit and supporting base unit, feeding motor flange 40 wherein in grand Fine Feed unit and feeding bracing frame 36 are rigidly connected with the upper mounting plate 4 in supporting base unit and right side riser 37 screw thread respectively, orientation revolution rotary joint 13 in revolution motion unit and directional swing joint 14 are rigidly connected with the flexible hinge 32 in grand Fine Feed unit and the spinning motion motor 42 in spinning motion unit respectively by revoluting motor flange 30 and spinning motor flange 15, swinging supporter 27 in spinning motion unit is connected with the unit left side vertical plate 5 of supporting base and the center positioning hole interference of right side riser 37 respectively by outer oscillation bearing 16, mobile platform substrate 46 in lens Installation and adjustment unit is threaded connection mode and is arranged in the spill locating slot of pedestal 20 in supporting base unit, and the cooling liquid container 9 in cooling unit is by being rigidly connected with left side vertical plate 5 screw thread in supporting base unit,

See shown in Fig. 1 to Fig. 4, described grand Fine Feed unit comprises encoder 1, DC servo motor 2, decelerator 3, feeding motor flange 40, shaft coupling 6, ball-screw fixed supporting seat 7, ball-screw 8, piezoelectric stack 31, flexible hinge 32, guide rail slide block 33, leading screw flange 34, linear guides 35, feeding bracing frame 36 and brake 39, wherein DC servo motor assembly realizes the feed motion of directed revolution rotary joint 13 at vertical direction in conjunction with ball-screw-transmission assembly as grand dynamic feeding subelement, the piezoelectric actuator be made up of piezoelectric stack 31 and flexible hinge 32 realizes the precise jiggle feeding of directed revolution rotary joint 13 at vertical direction, brake 39 is for preventing freely gliding of ball-screw-transmission assembly causes owing to realizing self-locking under the unexpected powering-off state of system leading screw flange 34, flexible hinge 32 adopts arc transitional type hinge format and exports the uniform displacement of constant amplitude,

Described revolution motion unit comprises revolution disc type electric machine 12, directed revolution rotary joint 13, directional swing joint 14 and revoluting motor flange 30, described directional swing joint 14, revoluting motor flange 30 are rigidly connected with spinning motor flange 15, flexible hinge 32 respectively, and directed revolution rotary joint 13, directional swing joint 14 are by precise rolling bearing and rotation alignment pin composition;

Described spinning motion unit comprises spinning motor flange 15, outer oscillation bearing 16, swinging supporter 27, outer swinging axle 28, interior oscillation bearing 29, spinning motion motor 42 and interior movable pendulum axle 43, described swinging supporter 27 is rigidly connected with outer swinging axle 28, stationary part and the interior swinging axle 43 of spinning motion motor 42 are rigidly connected, and outer swinging axle 28, interior swinging axle 43 are socketed in the locating hole of left and right side riser 5,37 and swinging supporter 27 respectively by outer oscillation bearing 16, interior oscillation bearing 29;

See shown in Fig. 5 to Fig. 7, described lens Installation and adjustment unit comprises concavees lens test specimen 17, workbench 25, spherical grinding machine head 26 and Three Degree Of Freedom feeding subelement, described Three Degree Of Freedom feeding subelement comprises x to adjustment knob 18, x is to feeding platform 19, y is to adjustment knob 21, y is to feeding platform 22, z is to feeding platform 23, alignment pin 45, z is to feeding motor 46, support supporting plate 24 and mobile platform substrate 46, described spherical grinding machine head 26 is socketed by the rotating shaft of its locating hole and spinning motion motor 42, support supporting plate 24 to be rigidly connected with workbench 25 screw thread, Three Degree Of Freedom feeding subelement is carried out initial alignment to workbench 25 and is realized the change of processed concavees lens test specimen 17 radius of curvature by the vertical direction displacement of servo-actuated adjustment workbench 25,

Described cooling unit comprises cooling liquid container 9, cooling liquid container trip bolt 10 and cooling tube 11, described cooling liquid container 9 is rigidly connected by cooling fluid trip bolt 10 and left side vertical plate 5, and and install with right side riser 37 rigidly connected feeding bracing frame 36 symmetry, thus play counterweight effect; Cooling tube 11 is flexible hose, and its initial position is in the edge near-end of processed concavees lens test specimen 17; The flow of cooling fluid increases with the raising of revolve round the sun disc type electric machine 12 and spinning motion motor 42 rotating speed;

Described supporting base unit comprises upper mounting plate 4, left side vertical plate 5, pedestal 20, right side riser 37 and riser mounting screw 38, described upper mounting plate 4 and pedestal 20 are equipped with and left and right side riser 5,37 wide and rectangle locating slots be arranged symmetrically with, to realize the parallel installation of left side vertical plate 5 and right side riser 37 and to ensure the depth of parallelism of itself and upper mounting plate 4 and pedestal 20.

Described flexible hinge 32 and piezoelectric actuator realize vertical direction, and namely z moves to Fine Feed, and described flexible hinge 32 has envelope structure in cylinder ring form, and described piezoelectric actuator is made up of the piezoelectric stack 31 of four xy plane annular array arrangements; When high frequency excitation voltage acts on four piezoelectric stacks 31 simultaneously, this driver exports the uniform displacement of high frequency constant amplitude, can realize the high-frequency reciprocating grinding of spherical grinding machine head 26 pairs of concavees lens test specimens 17; Maximum effective output displacement of described piezoelectric actuator is 42.1 μm, and corresponding to spherical grinding machine head 26 at horizontal plane, the maximum displacement namely on xy plane and vertical direction is respectively 24.2 μm and 6.8 μm.

Described orientation revolution rotary joint 13, directional swing joint 14 all can provide the swing free degree of a direction of rotation; After grand Fine Feed unit exports the drive displacement determined, with grand Fine Feed unit final drive assembly---flexible hinge rigidly connected revolution disc type electric machine 12 exports identical displacement, vertical displacement is changed by the motion in revolution rotary joint 13 and directional swing joint 14, realize the accurate adjustment to the radius of gyration of spherical grinding machine head 26 circus movement track, namely processing object of the present utility model can contain the concavees lens test specimen 17 of different-diameter size; The range of work of the utility model attainable concavees lens test specimen 17 diameter is 7.2mm-26.3mm, and directed revolution rotary joint 13 and the attainable pendulum angle scope in directional swing joint 14 are respectively 90 °-180 ° and 72 °-180 °.

The processing radius of curvature of the non-spherical surface part of described concavees lens test specimen 17 is adjustable, after feeding displacement is determined in grand Fine Feed unit output, the revolution motion radius of spherical grinding machine head 26 is determined thereupon, namely the circular motion track of spherical grinding machine head 26 is determined, after z determines angular displacement to feeding motor 45 output, workbench 25 drives concavees lens test specimen 17 in the vertical direction to produce displacement, spherical grinding machine head 26 increases with the contact area of concavees lens test specimen 17 or reduces, corresponding grinding amount also increases or reduces, corresponding to the different feeding displacements that grand Fine Feed unit exports, the revolution motion radius of spherical grinding machine head 26 changes thereupon, by adjusting the vertical direction displacement of concavees lens test specimen 17 further, realize the accurate continuous setup to concavees lens test specimen 17 radius of curvature.

Described left side vertical plate 5 and right side riser 37 are all processed with at the geometric centre axes place closing on spherical grinding machine head 26 longitudinal stripe that width is 1mm, immediately below this striped, the side that workbench 25 closes on left side vertical plate 5 and right side riser 37 is also processed with horizontal rectangular channel that width is 3mm and width is the longitudinal stripe of 1mm, the length of rectangular channel is longer than the processing diameter of concavees lens test specimen 17 so that guarantee the uniformity of the central point of concavees lens test specimen 17 and the geometric center of workbench 25, the longitudinal stripe of workbench 25 also with left side vertical plate 5, the longitudinal stripe of right side riser 37 keeps alignment to guarantee that the geometric center of workbench 25 is on the connection axis of two longitudinal stripes.

Described workbench 25 table top is processed with intensive array hole position, workbench 25 is realized by one group of alignment pin 44 be arranged in locating hole with the relative position of concavees lens test specimen 17, and alignment pin 44 contacts with the cylindrical bus retention wire of concavees lens test specimen 17; Spherical grinding machine head 26 is processed with mutually perpendicular two fine thread holes, the output shaft end of spinning motion motor 42 has mutually perpendicular two plane of orientations, and spherical grinding machine head 26 is socketed by two bolt of serrations and is fixedly mounted in the rotating shaft of spinning motion motor 42.

Described spherical grinding machine head 26 revolution motion is by revolution disc type electric machine 12, outer oscillation bearing 16, swinging supporter 27, outer swinging axle 28, interior oscillation bearing 29 and interior swinging axle 43 realize, described swinging supporter 27 realizes the oscillating motion of spherical grinding machine head 26 single direction by outer oscillation bearing 16 and outer swinging axle 28, 42, spinning motion motor realizes the oscillating motion of spherical another single vertical direction of grinding machine head 26 by interior oscillation bearing 29 and interior swinging axle 43, the continuous torque exported in conjunction with revolution disc type electric machine 12 and angular displacement, spherical grinding machine head 26 realizes continuous print speed change circular motion, the speed of circular motion depends on the angular speed that revolution disc type electric machine 12 exports.

Shown in Fig. 9, the adjustable aspheric surface concavees lens of the radius of curvature involved by the utility model processing unit (plant), this device adopts vertical layout, and overall dimensions is about 82mm × 82mm × 263mm.The concrete model of the main components related in the utility model is: the model of encoder 1 is Maxon MR-512, the model of DC servo motor 2 is Maxon EC-max22, the model of decelerator 3 is Maxon GP-32S, the model of revolution disc type electric machine 12 is Maxon EC-Flat20, the model of piezoelectric stack 31 is XP-8 × 8/18, and the model of spinning motion motor 42 is Maxon EC-max30.

In concrete test process, testing arrangement should be placed in air supporting vibration isolation table to weaken the impact of external vibration on grinding.First disc type concavees lens test specimen 17 is placed on the location panel of workbench 25, and makes the center of circle of concavees lens test specimen 17 as far as possible consistent with the geometric center of workbench 25.X is respectively driven to feeding platform 19 and y to feeding platform 22 to realize the adjustment of workbench 25 horizontal plane displacement to adjustment knob 18 and y to adjustment knob 21 by adjustment x, when the longitudinal stripe in left side vertical plate 5 and right side riser 37 and workbench 25 lateral width are the longitudinal stripe conllinear of 1mm, the initial position of workbench 25 can be guaranteed.

Further, by observing the horizontal rectangle groove edge of workbench 25 and the distance of the outer bus of concavees lens test specimen 17, the relative position of concavees lens test specimen 17 with workbench 25 is determined by the alignment pin 44 that can be arranged in locating hole by a group.Complete concavees lens test specimen 17 be installed on location after, DC servo motor 2 is driven to export controllable precise displacement by pulse/direction controlling mode, leading screw flange 34 and hinge installing rack 41 is driven to move downward, thus make directed revolution rotary joint 13 and directional swing joint 14 all produce larger pendulum angle, now, swinging supporter 27 produces large-angle swinging momentum by outer oscillation bearing 16 and outer swinging axle 28 around left side vertical plate 5 and right side riser 37, and the chord length of spherical grinding machine head 26 movement locus should be greater than the diameter of concavees lens test specimen 17.

Drive z to export to feeding motor 45 and determine angular displacement, workbench 25 drives concavees lens test specimen 17 to produce small size displacement upwards, and after drive concavees lens test specimen 17, with spherical grinding machine head 26, initial contact occurs, z stops to feed motion.Now, manually adjust flexible cooling tube 11 and guarantee that its initial position is in the edge near-end of processed concavees lens test specimen 17, open the flow valve of cooling liquid container 9 and discharge cooling fluid to concavees lens test specimen 17 concave surface.Drive revolution disc type electric machine 12 and spinning motion motor 42 and processing the starting stage guarantee its low-speed running, after entering the steady grinding stage, improve the rotating speed driving revolution disc type electric machine 12 and spinning motion motor 42 gradually, now the flow of cooling fluid increases with the raising of revolve round the sun disc type electric machine 12 and spinning motion motor 42 rotating speed.On this basis, by applying high frequency excitation voltage to four piezoelectric stacks 31 simultaneously, the uniform displacement of the exportable high frequency constant amplitude of driver as micrometer feed subelement, can realize the high-frequency reciprocating grinding of spherical grinding machine head 26 pairs of concavees lens test specimens 17 under the processing radius of gyration determined.Completing, this peripheral grinding processing determining the radius of gyration is thick, further driving DC servo motor 2 exports slightly oppositely displacement, drive hinge installing rack 41 upwards small movements, directional swing joint 14 also produces small size backswing angle, and now the chord length of spherical grinding machine head 26 movement locus slightly reduces.

Repeat aforesaid operations step, the precision adjustment of processing the radius of gyration can be realized, can complete and the peripheral grinding at concavees lens test specimen 17 different radii place is processed.When the radius of curvature of aspheric surface concavees lens test specimen 17 is known, z can adjust its angular displacement exported by the curvature value corresponding according to difference processing revolution to feeding motor 45, and then drive concavees lens test specimen 17 in the vertical direction to produce corresponding displacement calculating amount, namely cut 26 by pot mill and adjust grinding amount, to realize the accurate continuous setup to concavees lens test specimen 17 radius of curvature with the change of concavees lens test specimen 17.

The foregoing is only preferred embodiment of the present utility model, be not limited to the utility model, for a person skilled in the art, the utility model can have various modifications and variations.All the utility model is done any amendment, equivalent replacement, improvement etc., all should be included within protection domain of the present utility model.

Claims (8)

1. a radius of curvature adjustable aspheric surface concavees lens processing unit (plant), it is characterized in that: comprise grand Fine Feed unit, revolution motion unit, spinning motion unit, lens Installation and adjustment unit, cooling unit and supporting base unit, feeding motor flange (40) wherein in grand Fine Feed unit and feeding bracing frame (36) are rigidly connected with the upper mounting plate (4) in supporting base unit and right side riser (37) screw thread respectively, orientation revolution rotary joint (13) and directional swing joint (14) in revolution motion unit is rigidly connected with the flexible hinge (32) in grand Fine Feed unit and the spinning motion motor (42) in spinning motion unit respectively by revoluting motor flange (30) and spinning motor flange (15), swinging supporter (27) in spinning motion unit is connected with the unit left side vertical plate (5) of supporting base and the center positioning hole interference of right side riser (37) respectively by outer oscillation bearing (16), mobile platform substrate (46) mode of being threaded connection in lens Installation and adjustment unit is arranged in the spill locating slot of pedestal (20) in supporting base unit, and the cooling liquid container (9) in cooling unit is by being rigidly connected with left side vertical plate (5) screw thread in supporting base unit,

Described grand Fine Feed unit comprises encoder (1), DC servo motor (2), decelerator (3), feeding motor flange (40), shaft coupling (6), ball-screw fixed supporting seat (7), ball-screw (8), piezoelectric stack (31), flexible hinge (32), guide rail slide block (33), leading screw flange (34), linear guides (35), feeding bracing frame (36) and brake (39), wherein DC servo motor assembly realizes the feed motion of directed revolution rotary joint (13) at vertical direction in conjunction with ball-screw-transmission assembly as grand dynamic feeding subelement, the piezoelectric actuator be made up of piezoelectric stack (31) and flexible hinge (32) realizes the precise jiggle feeding of directed revolution rotary joint (13) at vertical direction, brake (39) is for preventing freely gliding of ball-screw-transmission assembly causes owing to realizing self-locking under the unexpected powering-off state of system leading screw flange (34), flexible hinge (32) adopts arc transitional type hinge format and exports the uniform displacement of constant amplitude,

Described revolution motion unit comprises revolution disc type electric machine (12), directed revolution rotary joint (13), directional swing joint (14) and revoluting motor flange (30), described directional swing joint (14), revoluting motor flange (30) are rigidly connected with spinning motor flange (15), flexible hinge (32) respectively, and directed revolution rotary joint (13), directional swing joint (14) are by precise rolling bearing and rotation alignment pin composition;

Described spinning motion unit comprises spinning motor flange (15), outer oscillation bearing (16), swinging supporter (27), outer swinging axle (28), interior oscillation bearing (29), spinning motion motor (42) and interior movable pendulum axle (43), described swinging supporter (27) and outer swinging axle (28) are rigidly connected, stationary part and the interior swinging axle (43) of spinning motion motor (42) are rigidly connected, outer swinging axle (28), interior swinging axle (43) is respectively by outer oscillation bearing (16), interior oscillation bearing (29) is socketed on a left side, right side riser (5, 37) and in the locating hole of swinging supporter (27),

Described lens Installation and adjustment unit comprises concavees lens test specimen (17), workbench (25), spherical grinding machine head (26) and Three Degree Of Freedom feeding subelement, described Three Degree Of Freedom feeding subelement comprises x to adjustment knob (18), x is to feeding platform (19), y is to adjustment knob (21), y is to feeding platform (22), z is to feeding platform (23), alignment pin (45), z is to feeding motor (46), support supporting plate (24) and mobile platform substrate (46), described spherical grinding machine head (26) is socketed by the rotating shaft of its locating hole and spinning motion motor (42), support supporting plate (24) to be rigidly connected with workbench (25) screw thread, Three Degree Of Freedom feeding subelement is carried out initial alignment to workbench (25) and is realized the change of processed concavees lens test specimen (17) radius of curvature by the vertical direction displacement of servo-actuated adjustment workbench (25),

Described cooling unit comprises cooling liquid container (9), cooling liquid container trip bolt (10) and cooling tube (11), described cooling liquid container (9) is rigidly connected by cooling fluid trip bolt (10) and left side vertical plate (5), and and install with right side riser (37) rigidly connected feeding bracing frame (36) symmetry, thus play counterweight effect; Cooling tube (11) is flexible hose, and its initial position is in the edge near-end of processed concavees lens test specimen (17); The flow of cooling fluid increases with the raising of revolve round the sun disc type electric machine (12) and spinning motion motor (42) rotating speed;

Described supporting base unit comprises upper mounting plate (4), left side vertical plate (5), pedestal (20), right side riser (37) and riser mounting screw (38), described upper mounting plate (4) and pedestal (20) are equipped with and the rectangle locating slot that be arranged symmetrically with wide with left and right side riser (5,37), to realize the parallel installation of left side vertical plate (5) and right side riser (37) and to ensure the depth of parallelism of itself and upper mounting plate (4) and pedestal (20).

2. radius of curvature according to claim 1 adjustable aspheric surface concavees lens processing unit (plant), it is characterized in that: described flexible hinge (32) and piezoelectric actuator realize vertical direction, namely z moves to Fine Feed, described flexible hinge (32) has envelope structure in cylinder ring form, and described piezoelectric actuator is made up of the piezoelectric stack (31) of four xy plane annular array arrangements; When high frequency excitation voltage acts on four piezoelectric stacks (31) simultaneously, this driver exports the uniform displacement of high frequency constant amplitude, can realize the high-frequency reciprocating grinding of spherical grinding machine head (26) to concavees lens test specimen (17); Maximum effective output displacement of described piezoelectric actuator is 42.1 μm, and corresponding to spherical grinding machine head (26) at horizontal plane, the maximum displacement namely on xy plane and vertical direction is respectively 24.2 μm and 6.8 μm.

3. radius of curvature according to claim 1 adjustable aspheric surface concavees lens processing unit (plant), is characterized in that: described orientation revolution rotary joint (13), directional swing joint (14) all can provide the swing free degree of a direction of rotation, after grand Fine Feed unit exports the drive displacement determined, with grand Fine Feed unit final drive assembly---flexible hinge rigidly connected revolution disc type electric machine (12) exports identical displacement, vertical displacement is by the motion conversion of revolution rotary joint (13) and directional swing joint (14), realize the accurate adjustment to the radius of gyration of spherical grinding machine head (26) circus movement track, namely processing object contains the concavees lens test specimen (17) of different-diameter size, the range of work of concavees lens test specimen (17) diameter is 7.2mm-26.3mm, the pendulum angle scope that directed revolution rotary joint (13) and directional swing joint (14) realizes is respectively 90 °-180 ° and 72 °-180 °.

4. radius of curvature according to claim 1 adjustable aspheric surface concavees lens processing unit (plant), is characterized in that: the processing radius of curvature of the non-spherical surface part of described concavees lens test specimen (17) is adjustable, after feeding displacement is determined in grand Fine Feed unit output, the revolution motion radius of spherical grinding machine head (26) is determined thereupon, namely the circular motion track of spherical grinding machine head (26) is determined, after z determines angular displacement to feeding motor (45) output, workbench (25) drives concavees lens test specimen (17) in the vertical direction to produce displacement, spherical grinding machine head (26) increases with the contact area of concavees lens test specimen (17) or reduces, corresponding grinding amount also increases or reduces, corresponding to the different feeding displacements that grand Fine Feed unit exports, the revolution motion radius of spherical grinding machine head (26) changes thereupon, by adjusting the vertical direction displacement of concavees lens test specimen (17) further, realize the accurate continuous setup to concavees lens test specimen (17) radius of curvature.

5. radius of curvature according to claim 1 adjustable aspheric surface concavees lens processing unit (plant), it is characterized in that: described left side vertical plate (5) and right side riser (37) are all processed with at the geometric centre axes place closing on spherical grinding machine head (26) longitudinal stripe that width is 1mm, immediately below this striped, the side that workbench (25) closes on left side vertical plate (5) and right side riser (37) is also processed with horizontal rectangular channel that width is 3mm and width is the longitudinal stripe of 1mm, the length of rectangular channel is longer than the processing diameter of concavees lens test specimen (17) so that guarantee the uniformity of the central point of concavees lens test specimen (17) and the geometric center of workbench (25), the longitudinal stripe of workbench (25) also with left side vertical plate (5), the longitudinal stripe on right side riser (37) keeps alignment to guarantee that the geometric center of workbench (25) is on the connection axis of two longitudinal stripes.

6. radius of curvature according to claim 1 adjustable aspheric surface concavees lens processing unit (plant), it is characterized in that: described workbench (25) table top is processed with intensive array hole position, workbench (25) is realized by one group of alignment pin (44) be arranged in locating hole with the relative position of concavees lens test specimen (17), and alignment pin (44) contacts with the cylindrical bus retention wire of concavees lens test specimen (17); Spherical grinding machine head (26) is processed with mutually perpendicular two fine thread holes, the output shaft end of spinning motion motor (42) has mutually perpendicular two plane of orientations, and spherical grinding machine head (26) is socketed by two bolt of serrations and is fixedly mounted in the rotating shaft of spinning motion motor (42).

7. radius of curvature according to claim 1 adjustable aspheric surface concavees lens processing unit (plant), it is characterized in that: described spherical grinding machine head (26) revolution motion is by revolution disc type electric machine (12), outer oscillation bearing (16), swinging supporter (27), outer swinging axle (28), interior oscillation bearing (29) and interior swinging axle (43) realize, described swinging supporter (27) realizes the oscillating motion of spherical grinding machine head (26) single direction by outer oscillation bearing (16) and outer swinging axle (28), spinning motion motor (42) then realizes the oscillating motion of spherical grinding machine head (26) another single vertical direction by interior oscillation bearing (29) and interior swinging axle (43), the continuous torque exported in conjunction with revolution disc type electric machine (12) and angular displacement, spherical grinding machine head (26) realizes continuous print speed change circular motion, the speed of circular motion depends on the angular speed that revolution disc type electric machine (12) exports.

8. the adjustable aspheric surface concavees lens of the radius of curvature according to claim 1 to 7 any one processing unit (plant), is characterized in that: the size of main body of described radius of curvature adjustable aspheric surface concavees lens processing unit (plant) is 82mm × 82mm × 263mm.