CN104889076A - Concentrated testing device of 3D glasses - Google Patents

Abstract

The invention discloses a concentrated testing device of 3D glasses. The device comprises a fixed plate arranged on a frame, wherein a turntable driven by an intermittent driving device is arranged on the fixed plate; multiple positioning tools for positioning the 3D glasses are uniformly arranged at the periphery of the turntable; power supply devices are arranged on the turntable corresponding to all the positioning tools; an RF testing unit, a 3D testing unit, a key light testing unit and a classification picking device are arranged on the fixed plate at the periphery of the turntable in sequence; a first station on the fixed plate at the periphery of the turntable is a discharge station; the RF testing unit, the 3D testing unit, the key light testing unit and the classification picking device are respectively corresponding to second to fifth stations; and key devices are respectively arranged in the second to fourth stations. The device realizes annular automatic production operation, is small in equipment occupation space, reduces the manual operation, prevents the labor waste, improves the working efficiency, prevents the influence of human factors on testing, and guarantees the consistency of product performances.

Description

A kind of 3D glasses integrated test device

Technical field

The present invention relates to 3D glasses technical field of measurement and test, particularly relate to a kind of 3D glasses integrated test device.

Background technology

At present, the 3D of 3D glasses tests, RF tests and switching on and shutting down press key lamp optical tests is respectively 3 stations, and each station all needs configuration operator to carry out manual operation, not only waste of manpower, and human factor is large to tests affect, causes properties of product uniformity poor; Meanwhile, for completing the flowing water line length that 3 stations detect, take up room large.

Summary of the invention

Embodiment of the present invention technical problem to be solved is: provide a kind of 3D glasses integrated test device, realizes automatically detecting, and reaches and takes up room little and ensure the conforming object of properties of product.

For solving the problems of the technologies described above, the technical scheme of the embodiment of the present invention is: a kind of 3D glasses integrated test device, comprise the fixed head be arranged in frame, described fixed head is provided with the rotating disk driven by intermittent drive unit, the periphery of described rotating disk is evenly provided with some positioning tools for locating 3D glasses, be equipped with electric supply installation with on the described rotating disk of each described positioning tool correspondence position, the described fixed head being positioned at described rotating disk periphery be provided with successively RF test cell, 3D test cell, press key lamp optical tests unit and classification pick device;

The first station be positioned on the described fixed head of described rotating disk periphery is blowing station, and corresponding second station of described RF test cell, described 3D test cell, described press key lamp optical tests unit and described classification pick device difference is to the 5th station;

A key device for switching on and shutting down is respectively equipped with at described second station and the 4th station place.

Improve as one, described positioning tool comprises the locating piece be arranged on described rotating disk, described locating piece is provided with the stopper slot for limiting 3D eye positions, described locating piece is provided with near the side of described RF test cell and carries out the antenna escape groove of testing for described RF test cell;

Described locating piece is also provided with and carries out testing for described 3D test cell and the LED lamplight of through described locating piece thickness dodges hole, described LED lamplight is dodged hole and is arranged with eyeglass is corresponding on described 3D glasses.

As further improvement, described electric supply installation comprises and being arranged on described rotating disk and the lead that arrange corresponding to described positioning tool, described lead is slidably installed the positive and negative electrode simulation mechanism of oriented described 3D glasses continued power, described positive and negative electrode simulation mechanism is provided with the positive conductive electrode shell fragment of feeding pannel positive contact on described 3D glasses with feeding pannel cathode contact on described 3D glasses and the conduction negative pole of elastic telescopic, and described positive conductive electrode shell fragment is obliquely installed to the positive extreme direction of described feeding pannel near one end of described 3D glasses;

The top of described positive and negative electrode simulation mechanism is provided with elastic hold-down mechanism, and described lead is positioned at the side away from described antenna escape groove;

Described first station and described 5th station place are respectively equipped with the first power set driving described positive and negative electrode simulation mechanism vertically to slide.

As improvement further, described positive and negative electrode simulation mechanism comprises the holder be slidably mounted on described lead, described holder is provided with near the side of described 3D glasses and protrudes described holder and compact heap for compressing described 3D glasses; Described holder is made up of insulating materials, described holder is provided with the first T-shaped counterbore, described conduction negative pole is arranged in described first counterbore, the top being positioned at described conduction negative pole is provided with the first conductive electrode be connected with direct current negative pole, is provided with the first power spring between described first conductive electrode and described conduction negative pole;

The described holder being positioned at described first counterbore side is also provided with unthreaded hole, in described unthreaded hole, is provided with the second power spring; Described positive conductive electrode shell fragment to be arranged on described holder and correspondingly with described unthreaded hole position to arrange, and the top of described second power spring is provided with the second conductive electrode be connected with direct current positive pole.

As further improving again, described direct current is button cell;

The top of described holder is provided with the middle base be made up of insulating materials, battery compartment for installing described button cell is arranged at described middle base, described middle base is also provided with inverted T shape second counterbore be all communicated with described battery compartment with described first counterbore, described first conductive electrode is arranged in described second counterbore; The described middle base being positioned at described battery compartment side is provided with the 3rd counterbore of inverted T shape, and described second conductive electrode is arranged in described 3rd counterbore;

Described middle base is provided with the gland be made up of insulating materials, being slidably fitted with the conductive handle for being connected described second conductive electrode and described button cell positive pole between described gland with described middle base, between described conductive handle and described gland, being provided with reposition element.

As further improvement, described RF test cell comprises the test antenna be positioned at below described antenna escape groove, and described test antenna is driven to described positioning tool direction by the second power set;

Described press key lamp optical tests unit comprises the color sensor that arrange corresponding to described antenna escape groove, and described color sensor is driven to described positioning tool direction by the 3rd power set.

As further improving, described key device comprises the first support be arranged on described fixed head, described first support is provided with the guide rail be arranged in parallel with described rotating disk, described guide rail is provided with the slide block driven by the 4th power set, described slide block is provided with two spaced back-up blocks, be provided with the pressing axis for pressing button on described 3D glasses described in two between back-up block, back-up block described in two is all protruded at the two ends of described pressing axis;

Described pressing axis described in two between back-up block is provided with back-up ring, between described back-up ring and the described back-up block away from described 3D glasses side, is provided with stage clip; Described pressing axis away from described 3D glasses one end is provided with rotation-preventing mechanism.

As further improvement, described 3D test cell comprises the lower mount pad be positioned at below described positioning tool, and described lower mount pad is driven to described positioning tool direction by the 5th power set; Described fixed head is provided with the second support, described second support is provided with the 6th power set and drives and extend to the upper mount pad above described positioning tool, one of them in described upper mount pad and described lower mount pad is provided with LED, another is provided with electrooptical device, and described LED and described electrooptical device are corresponding up and down to be arranged and dodges with described LED lamplight that hole is corresponding to be arranged.

Improve as one, described classification pick device comprises the 3rd support be arranged on described fixed head, and described 3rd support is rotatablely equipped with the cylinder driven by electric rotating machine, and described cylinder vertically drives the sucker extended to above described positioning tool;

The all sides of described cylinder are provided with the fan-shaped catch being no more than 180 °, described 3rd support is provided with the photoelectric sensor switch for responding to described catch, when arriving feeding position, described photoelectric sensor switch detects the end edge of described catch and sends signal and control described electric rotating machine and stop operating, and described electric rotating machine is turned left by feeding position or the angle of turning right all is less than the fan angle of described catch.

As further improving, described 3rd support is also provided with the limited block limiting described catch swing offset, described limited block and described photoelectric sensor switch are 180 ° and distribute.

Owing to have employed technique scheme, the beneficial effect of the embodiment of the present invention is:

Due to the rotating disk of each positioning tool correspondence position on be equipped with electric supply installation, thus carry out continued power by electric supply installation to the 3D glasses in positioning tool, the test for other operations follow-up provides effective guarantee; Owing to the fixed head of rotating disk periphery being provided with successively RF test cell, 3D test cell, press key lamp optical tests unit and classification pick device, thus achieve annular automation continuous productive process, not only equipment occupation space is little, and decrease manual operation, avoid manpower waste, and substantially increase operating efficiency, it also avoid the impact of human factor on test simultaneously, and then ensure that the uniformity of properties of product.

Dodging hole because locating piece is provided with stopper slot, antenna escape groove and LED lamplight, thus realize the accurate location to 3D glasses by stopper slot, is laying the foundation smoothly of follow-up test; Dodge hole by antenna escape groove and LED lamplight, meet the needs of RF test cell and 3D test cell.

Due to the positive and negative electrode simulation mechanism of oriented 3D glasses continued power that lead is slidably installed, thus at work, first power set drive the upwards action of positive and negative electrode simulation mechanism, afterwards 3D glasses are positioned in positioning tool, then positive and negative electrode simulation mechanism is close to 3D glasses under the effect of elastic hold-down mechanism, until positive conductive electrode shell fragment and conduction negative pole realize power supply respectively at the feeding pannel positive pole on 3D glasses and feeding pannel cathode contact.Adopt this device, under the prerequisite realizing continued power, realizing flexible power supply by the conduction negative pole of positive conductive electrode shell fragment and elastic telescopic, compared with powering with conventional rigid, avoiding when completing power supply action, cause the problem of feeding pannel positive pole and the damage of feeding pannel negative pole or damage, meanwhile, for the stability of powering when ensureing test lays the first stone, and compared with artificial fetching battery, substantially increase operating efficiency, reduce labour intensity.

Because positive conductive electrode shell fragment is obliquely installed, thus when elastic hold-down mechanism presses down, by the structure that is obliquely installed ensure positive conductive electrode shell fragment to the positive extreme direction bending of feeding pannel and with feeding pannel positive contact; Because lead is positioned at the side away from antenna escape groove, thus when preventing dial rotation, lead and each test cell interfere and affect normal work.

Because holder is provided with the first counterbore and unthreaded hole be communicated with battery compartment, thus realized the separation of cathode circuit and cathode traces by the first counterbore and unthreaded hole; By positive conductive electrode shell fragment and the first power spring between the first conductive electrode and conduction negative pole, achieve flexible power supply, simultaneously by the elastic force that the first power spring and the second power spring produce, ensure the second conductive electrode and direct current positive pole, positive conductive electrode shell fragment and the second power spring, the first conductive electrode and direct current negative pole and conduct electricity negative pole and the contact of the first power spring when being energized.

Because the first conductive electrode is arranged in the second counterbore, second conductive electrode is arranged in the 3rd counterbore, thus during power spring effect, the moving displacement of the first conductive electrode and the second conductive electrode is limited by the second counterbore and the 3rd counterbore, on the basis ensureing electrical contact, be convenient to button cell and conductive handle are installed, meanwhile, effectively can ensure the stationarity of button cell in battery compartment by conductive handle; Owing to being provided with reposition element between conductive handle and gland, thus stretching by reposition element, be convenient to picking and placeing of button cell, meanwhile, achieve conductive handle and contact with the second conductive electrode with direct current positive pole all the time, ensure that carrying out smoothly of work.

Because guide rail is provided with the slide block driven by the 4th power set, thus at work, first pressing axis contacts button, 4th power set continue forward motion afterwards, now pressing axis is slided to the opposite direction of the 4th power set action on back-up block, until the 4th power set action puts in place, stage clip shrinks in this process, and the expanding force that its compression produces acts in pressing axis and also finally acts on button.Adopt this device, the automatic switching action of 3D glasses can not only be completed, and can realize pressing the constant force of button, simultaneously, act on the pressing force good stability on button, avoid in tradition, cylinder directly acts on button, and impulsive force and air pressure fluctuation cause the pressing force fluctuation acted on button, cause damage of product, and, prevent pressing axis from rotating by rotation-preventing mechanism, guarantee uniformity and the stationarity of each actuation of keys; In addition, this apparatus structure is simple, stable performance, economy and durability.

Because cylinder is provided with fan-shaped catch, 3rd support is provided with the photoelectric sensor switch for responding to catch, thus electric rotating machine is according to the test result of each test cell, carry out turning left or turning right to feeding position, when photoelectric sensor switch detects the end edge of catch, then sucker arrives feeding position, electric rotating machine stops operating, afterwards, cylinder drives sucker descending absorption 3D glasses, and realize classification pickup certified products or defective work, electric rotating machine action afterwards, certified products are placed to certified products material road, defective work is placed to defective work material road, this structure is adopted to achieve automatic material taking, operating efficiency is high, simultaneously, effectively prevent electric rotating machine from rotating in a circumferential direction, cause the tracheae that is connected with sucker and other line body to rotate be wound around and cause the accident, the classification pickup of certified products or defective work can also be realized and place, and this apparatus structure is simple, stable action, cost is low.

Owing to the 3rd support being also provided with the limited block of restriction catch swing offset, thus when photoelectric sensor switch damages, by the stop of limited block to catch, prevent electric rotating machine from rotating in a circumferential direction.

Accompanying drawing explanation

Fig. 1 is the structural representation of the embodiment of the present invention;

Fig. 2 is the structural representation of positioning tool in Fig. 1;

Fig. 3 is the structural representation that positioning tool coordinates with 3D glasses;

Fig. 4 is the structural representation of another angle of Fig. 3;

Fig. 5 is the structural representation of drive unit and electric supply installation in Fig. 1;

Fig. 6 is the structural representation of electric supply installation in Fig. 5;

Fig. 7 is the structural representation of positive and negative electrode simulation mechanism in Fig. 6;

Fig. 8 is the structural representation that positive and negative electrode simulation mechanism coordinates with 3D glasses;

Fig. 9 is the structural representation of holder and middle base in Fig. 8;

Figure 10 is the structural representation of RF test cell and key device in Fig. 1;

Figure 11 is the structural representation of key device in Figure 10;

Figure 12 is the A-A sectional view in Figure 11;

Figure 13 is the structural representation of 3D test cell in Fig. 1;

Figure 14 is the structural representation of press key lamp optical tests unit and key device in Fig. 1;

Figure 15 is the structural representation of pick device of classifying in Fig. 1;

Figure 16 is the axonometric drawing of Figure 15;

In figure: 1, fixed head, 2, rotating disk, 3, drive unit, 31, reducing motor, 32, protractor, 33, testing agency, 34, power shaft, 4, positioning tool, 41, locating piece, 42, stopper slot, 43, antenna escape groove, 44, LED lamplight dodges hole, and 45, groove, 46, projection, 47, positioning convex, 48, dodge gap, 49, installation portion, 5, electric supply installation, 51, first power set, 52, positive and negative electrode simulation mechanism, 521, holder, 5211, conduction negative pole, 5212, first power spring, 5213, second power spring, 5214, first counterbore, 5215, unthreaded hole, 522, middle base, 5221, battery compartment, 5222, first conductive electrode, 5223, second conductive electrode, 5224, second counterbore, 5225, 3rd counterbore, 523, gland, 524, conductive handle, 5241, reposition element, 525, compact heap, 526, positive conductive electrode shell fragment, 5261, bending part, 53, connecting plate, 54, contiguous block, 541, 4th counterbore, 55, lead, 56, block, 561, extending column, 57, flexible member, 6, RF test cell, 61, second power set, 62, test antenna, 63, first support, 64, key device, 641, 4th power set, 642, guide rail, 643, slide block, 644, pressing axis, 6441, back-up ring, 645, back-up block, 646, stage clip, 647, Anti-rotary block, 648, alignment pin, 649, guide finger, 7, 3D test cell, 71, upper mount pad, 72, second support, 73, 5th power set, 74, lower mount pad, 75, 6th power set, 8, press key lamp optical tests unit, 81, color sensor, 82, 3rd power set, 9, classification pick device, 91, 3rd support, 92, cylinder, 93, catch, 94, photoelectric sensor switch, 95, sucker, 96, limited block, 97, electric rotating machine, 10, 3D glasses, 101, feeding pannel positive pole, 102, feeding pannel negative pole.

Detailed description of the invention

In order to make object of the present invention, technical scheme and advantage clearly understand, below in conjunction with drawings and Examples, the present invention is further elaborated.Should be appreciated that specific embodiment described herein only in order to explain the present invention, be not intended to limit the present invention.

As shown in Figure 1, a kind of 3D glasses integrated test device, comprise the fixed head 1 be arranged in frame, this fixed head 1 is provided with the rotating disk 2 driven by intermittent drive unit 3, on the periphery of rotating disk 2, annular array has some mounting grooves, the rotating disk 2 being positioned at each mounting groove is equipped with the positioning tool 4 for locating 3D glasses 10, electric supply installation 5 is equipped with on the rotating disk 2 of each positioning tool 4 correspondence position, the fixed head 1 being positioned at rotating disk 2 periphery is provided with RF test cell 6 successively, 3D test cell 7, press key lamp optical tests unit 8 and classification pick device 9, the first station be positioned on the fixed head 1 of rotating disk 2 periphery is blowing station, RF test cell 6, 3D test cell 7, press key lamp optical tests unit 8 and classification pick device 9 are arranged to the 5th station one_to_one corresponding with the second station respectively, a key device 64 for switching on and shutting down is respectively equipped with at the second station and the 4th station place, this drive unit 3, electric supply installation 5, RF test cell 6,3D test cell 7, press key lamp optical tests unit 8, classification pick device 9 are all connected with ECU with key device 64.

As shown in Figure 5, this drive unit 3 comprises the protractor 32 that reducing motor 31 is driven by power shaft 34, the output shaft of this protractor 32 is connected with rotating disk 2, is provided with testing agency 33 between this power shaft 34 and fixed head 1, and this testing agency 33 is preferably photoelectric sensor switch and is connected with ECU.

As Fig. 2 to Fig. 4 jointly shown in, this positioning tool 4 comprises the locating piece 41 be arranged in mounting groove, the both sides of this locating piece 41 are equipped with the installation portion 49 be overlapped on rotating disk 2, this locating piece 41 is provided with location 3D glasses and the arc-shaped limit groove 42 suitable with 3D glasses 10, and the locating piece 41 being positioned at stopper slot 42 both sides is provided with positioning convex 47; This locating piece 41 is provided with near the side of RF test cell 6 and carries out the antenna escape groove 43 of testing for RF test cell 6; Recessed locating piece 41 is provided with and the groove 45 be communicated with antenna escape groove 43 with the locating piece 41 of bridge of the nose correspondence position on 3D glasses 10; The projection 46 suitable with nose clip on 3D glasses 10 is provided with in this groove 45; This locating piece 41 is also provided with and carries out testing for 3D test cell 7 and the LED lamplight of through locating piece 41 thickness dodges hole 44, this LED lamplight dodges that hole 44 is corresponding with eyeglass on 3D glasses 10 to be arranged; Positioning convex 47 away from antenna escape groove 43 side is provided with dodges gap 48 for what dodge electric supply installation 5.Thus accurate location is realized to the 3D glasses 10 being positioned at stopper slot 42, be laying the foundation smoothly of follow-up test; Positioning convex 47 is avoided to hinder electric supply installation 5 to power to 3D glasses 10 by dodging gap 48, simultaneously, dodge hole 44 by antenna escape groove 43 and LED lamplight, meet the needs of RF test cell and 3D test cell, to ensure that each test cell completes test smoothly.

As Fig. 6 to Fig. 9 jointly shown in, this electric supply installation 5 comprises and being arranged on rotating disk 2 and the lead 55 that arrange corresponding to positioning tool 4, when rotating to prevent rotating disk 2, lead 55 and each test cell interfere, this lead 55 is positioned at the side away from antenna escape groove 43, this lead 55 is slidably installed the positive and negative electrode simulation mechanism 52 of oriented 3D glasses 10 continued power, this positive and negative electrode simulation mechanism 52 is corresponding with dodging gap 48 to be arranged, this positive and negative electrode simulation mechanism 52 is provided with the positive conductive electrode shell fragment 526 contacted with feeding pannel positive pole 101 on 3D glasses 10 and the conduction negative pole 5211 contacting also elastic telescopic with feeding pannel negative pole 102 on 3D glasses 10, this lead 55 is provided with to be positioned at above positive and negative electrode simulation mechanism 52 and also exerts a force to the elastic hold-down mechanism on positive and negative electrode simulation mechanism 52.Flexible power supply is realized by the conduction negative pole 5211 of positive conductive electrode shell fragment 526 and elastic telescopic, compared with powering with conventional rigid, avoid when completing power supply action, cause the problem that feeding pannel positive pole 101 and feeding pannel negative pole 102 damage or damage, meanwhile, for the stability of powering when ensureing test lays the first stone, and compared with artificial fetching battery, substantially increase operating efficiency, reduce labour intensity.

This positive and negative electrode simulation mechanism 52 comprises and is slidably mounted on lead 55 upper fixed seat 521, is respectively equipped with the first power set 51 driving holder 521 vertically to slide at the first station and the 5th station place; This holder 521 is made up of insulating materials and correspondingly with dodging gap 48 is arranged, holder 521 away from 3D glasses 10 side is provided with the middle base 522 be made up of insulating materials, inverted T shape second counterbore 5224 that this middle base 522 is provided with battery compartment 5221 and is communicated with battery compartment 5221, the middle base 522 being positioned at battery compartment 5221 side is provided with the 3rd counterbore 5225 of inverted T shape; Be provided with the holder 521 of the second counterbore 5224 correspondence position the first counterbore 5214 be communicated with the second counterbore 5224, be provided with the holder 521 of the 3rd counterbore 5225 correspondence position the unthreaded hole 5215 be communicated with the 3rd counterbore 5225.

This positive conductive electrode shell fragment 526 to be arranged on holder 521 and correspondingly with unthreaded hole 5215 position to arrange, be provided with in 3rd counterbore 5225 and be connected and second conductive electrode 5223 suitable with the 3rd counterbore 5225 with direct current positive pole, be provided with the second power spring 5213 between this positive conductive electrode shell fragment 526 and second conductive electrode 5223, this second power spring 5213 is arranged in unthreaded hole 5215; This conduction negative pole 5211 is arranged in the first counterbore 5214, be provided with in this second counterbore 5224 and be connected and first conductive electrode 5222 suitable with the second counterbore 5224 with direct current negative pole, between this first conductive electrode 5222 and conduction negative pole 5211, be provided with the first power spring 5212 being positioned at the first counterbore 5214.

This direct current is be arranged on the button cell in battery compartment 5221, also can for the dc source being undertaken connecting by wire.

The top of this middle base 522 is provided with the gland 523 be made up of insulating materials, the conductive handle 524 for being connected the second conductive electrode 5223 and direct current positive pole is slidably fitted with between this gland 523 with middle base 522, reposition element 5241 is provided with between this conductive handle 524 and gland 523, this reposition element 5241 is preferably back-moving spring, thus realize conductive handle 524 by reposition element 5241 and contact with the second conductive electrode 5223 with direct current positive pole all the time, ensure that carrying out smoothly of work.

This holder 521 is provided with near the side of 3D glasses 10 and protrudes holder 521 and compact heap 525 for compressing 3D glasses 10, thus locate on the basis of 3D glasses 10 at positioning tool 4, realize compressing, ensure that the stationarity of contact in power supply process between each electrode and 3D glasses 10.

This positive conductive electrode shell fragment 526 is obliquely installed to feeding pannel positive pole 101 direction near one end of 3D glasses 10, and positive conductive electrode shell fragment 526 is provided with a bending part 5261 near the end of 3D glasses 10 one end, thus ensure that positive conductive electrode shell fragment 526 contacts to feeding pannel positive pole 101 direction bending with feeding pannel positive pole 101 by the structure that is obliquely installed, meanwhile, being aided with bending part 5261 prevents positive conductive electrode shell fragment 526 from scratching 3D glasses 10.

This holder 521 is connected with contiguous block 54 by connecting plate 53, this contiguous block 54 is made up of metal material and is slidably mounted on lead 55, thus by the slip of contiguous block 54 on lead 55 that metal material is made, realize the vertical motion of positive and negative electrode simulation mechanism 52, the holder 521 preventing insulating materials from making slides and wearing and tearing occurs and affects service life on lead 55.

This elastic hold-down mechanism comprises and to be arranged on lead 55 and away from the block 56 of rotating disk 2 one end, this block 56 is provided with the extending column 561 extended to contiguous block 54 direction, four counterbore 541 suitable with extending column 561 is provided with the contiguous block 54 of extending column 561 correspondence position, be provided with flexible member 57 between this block 56 and the 4th counterbore 541, this flexible member 57 is preferably set in the Compress Spring on extending column 561.Structure is simple, effectively can provide and act on thrust on contiguous block 54, for 3D glasses 10 continued power is laid a good foundation, and low cost of manufacture.

As Fig. 1 and Figure 10 jointly shown in, this RF test cell 6 comprises the test antenna 62 be positioned at below antenna escape groove 43, and this test antenna 62 is driven to positioning tool 4 direction by the second power set 61.

As shown in figure 14, this press key lamp optical tests unit 8 comprises the color sensor 81 that arrange corresponding to antenna escape groove 43, and this color sensor 81 is driven to positioning tool 4 direction by the 3rd power set 82.

As Figure 11 and Figure 12 jointly shown in, this key device 64 comprises the first support 63 be arranged on fixed head 1, this first support 63 is provided with the guide rail 642 be arranged in parallel with rotating disk 2, this guide rail 642 is provided with the slide block 643 driven by the 4th power set 641, this slide block 643 is provided with two spaced back-up blocks 645, be provided with the pressing axis 644 for pressing button on 3D glasses 10 between two back-up blocks 645, two back-up blocks 645 are all protruded at the two ends of this pressing axis 644; Pressing axis 644 between two back-up blocks 645 is provided with back-up ring 6441, is provided with stage clip 646 between this back-up ring 6441 and the back-up block 645 away from 3D glasses 10 side, the pressing axis 644 away from 3D glasses 10 one end is provided with rotation-preventing mechanism.Thus at work, first pressing axis 644 contacts button, 4th power set 641 continue forward motion afterwards, now pressing axis 644 is slided to the opposite direction of the 4th power set 641 action on back-up block 645, until the 4th power set 641 action puts in place, stage clip 646 shrinks in this process, and the expanding force that its compression produces acts in pressing axis 644 and also finally acts on button.Adopt this device, the automatic switching action of 3D glasses 10 can not only be completed, and can realize pressing the constant force of button, simultaneously, act on the pressing force good stability on button, avoid in tradition, cylinder directly acts on button, impulsive force and air pressure fluctuation cause the pressing force fluctuation acted on button, cause damage of product; In addition, this apparatus structure is simple, stable performance, economy and durability.

This rotation-preventing mechanism comprises the Anti-rotary block 647 be arranged in pressing axis 644, is provided with the vertically disposed alignment pin 648 with pressing axis 644 between this Anti-rotary block 647 and pressing axis 644; The guide finger 649 be arranged on Anti-rotary block 647 is provided with between this Anti-rotary block 647 and back-up block 645.Thus pass through the effect of alignment pin 648 and guide finger 649, prevent pressing axis 644 from rotating, guarantee uniformity and the stationarity of each actuation of keys.

As Fig. 1 and Figure 13 jointly shown in, this 3D test cell 7 comprises the lower mount pad 74 be positioned at below positioning tool 4, and this lower mount pad 74 is driven to positioning tool 4 direction by the 5th power set 73; Be provided with the second support 72 with the fixed head 1 of lower mount pad 74 correspondence position, this second support 72 is provided with the 6th power set 75 and drives and extend to the upper mount pad 71 above positioning tool 4; One of them on this in mount pad 71 and lower mount pad 74 is provided with LED, another is provided with electrooptical device, this LED and electrooptical device are corresponding up and down to be arranged and dodges with LED lamplight that hole 44 is corresponding to be arranged, and this electrooptical device is preferably phototriode.

As Fig. 1, Figure 15 and Figure 16 jointly shown in, this classification pick device 9 comprises the 3rd support 91 be arranged on fixed head 1,3rd support 91 is rotatablely equipped with the cylinder 92 that electric rotating machine 97 drives, this cylinder 92 vertically drives the sucker 95 extended to above positioning tool 4, this electric rotating machine 97 is stepper motor, and this cylinder 92 is all connected with ECU with electric rotating machine 97; This cylinder 92 weeks sides are provided with the fan-shaped catch 93 being no more than 180 degree, 3rd support 91 is provided with for responding to catch 93 and the photoelectric sensor switch 94 be connected with automatically controlled electricity unit, when arriving feeding position, photoelectric sensor switch 94 detects the end edge of catch 93 and sends signal and control electric rotating machine 97 and stop operating, and this electric rotating machine 97 is turned left by feeding position or the angle of turning right all is less than the fan angle of catch 93; 3rd support 91 is also provided with the limited block 96 of restriction catch 93 swing offset, this limited block 96 distributes in 180 ° with photoelectric sensor switch 94.Effectively prevent electric rotating machine 97 from rotating in a circumferential direction, cause the tracheae that is connected with sucker 95 and other line body to rotate and be wound around and cause the accident; And the classification pickup of certified products or defective work can be realized and place; By the stop 93 of limited block 96 pairs of catch, when preventing photoelectric sensor switch 94 from damaging, electric rotating machine 97 rotates in a circumferential direction.

In this programme, the first power set 51 are cylinder to the 6th power set 75, also can be other power source.

For the ease of understanding, the following operation principle giving a kind of 3D glasses integrated test device that the embodiment of the present invention provides:

First, first power set 51 action makes contiguous block 54 along lead 55 upward sliding, realize positive and negative electrode simulation mechanism 52 to be separated with positioning tool 4, then first 3D glasses 10 is put into positioning tool 4, first power set 51 slowly return afterwards, in this process, positive and negative electrode simulation mechanism 52 is by elastic hold-down mechanism force feed on positioning tool 4, and then positive and negative electrode simulation mechanism 52 is powered to 3D glasses 10, rear drive equipment 3 drive turntable rotation, according to the signal that testing agency 33 transmits to ECU, accessory drive 3 stops action, now, positioning tool 4 rests on RF test cell, 3D glasses 10 are started shooting by pressing axis 644 by key device 64 action afterwards, while pressing axis 644 return, second power set 61 drive test antenna near 3D glasses 10, in pairing process after powering, the RF signal received is input to frequency spectrograph by test antenna 62, it is qualified that analysis RF power judges whether, and then complete RF test, meanwhile, second the 3D glasses 10 being in the first station are put into next positioning tool 4.

Afterwards, the 3D glasses 10 completing RF test turn to 3D test cell 7 with rotating disk 2, then the 5th power set 73 drive lower mount pad 74 up, 6th power set 75 drive upper mount pad 71 descending, then LED is opened, light is irradiated to the liquid crystal lens of 3D glasses, phototriode is according to the optical information output voltage signal received, by analyze this voltage signal judge whether qualified, and then complete 3D test, meanwhile, the 3rd the 3D glasses 10 being in the first station are put into next positioning tool 4, second the 3D glasses 10 being in the second station are carried out RF test, afterwards, first 3D glasses 10 turns to press key lamp optical tests unit 8 with rotating disk 2, afterwards, 3D glasses 10 are shut down by pressing axis 644 by key device 64 action, while pressing axis 644 return, 3rd power set 82 drive color sensor 81 to carry out button light (color) test near 3D glasses 10, after closing key, press key lamp can bright about 2S, light color is detected by color sensor 81, judge that whether LED is bright or whether brightness is inadequate, and then judge whether qualified, and then complete press key lamp optical tests unit 8, meanwhile, the 4th the 3D glasses 10 being in the first station are put into next positioning tool 4, the 3rd the 3D glasses 10 being in the second station are carried out RF test, second the 3D glasses 10 being in the 3rd station are carried out 3D test.

After completing above-mentioned test, first 3D glasses 10 turns to classification pick device 9, first power set 51 with rotating disk 2 and drives positive and negative electrode simulation mechanism 52 vertically to slide, to carry out picking up the 3D glasses 10 after detecting, due to classification pick device 9 last time shutdown time state be again start shooting time original state, now on cylinder 92, the position of rotation of sucker 95 is uncertain, need to detect whether correspond to catch 93 by photoelectric sensor switch 94, and then judge that sucker 95 is towards certified products material road or towards defective work material road, then ECU control electric rotating machine 97 turns left or turns right sucker 95 is rotated to feeding position, when photoelectric sensor switch 94 detects the end edge of catch 93, then sucker 95 arrives feeding position, ECU controls electric rotating machine 97 and stops action, then cylinder 92 drives the descending absorption of sucker 95 first 3D glasses 10, electric rotating machine 97 carries out turning left or turning right according to the result that each test cell detects afterwards, certified products are placed to certified products material road, defective work is placed to defective work material road, electric rotating machine 97 is with dynamic air cylinder 92 to reset afterwards, for next picking action is ready, meanwhile, the 5th the 3D glasses 10 being in the first station are put into next positioning tool 4, the 4th the 3D glasses 10 being in the second station are carried out RF test, the 3rd the 3D glasses 10 being in the 3rd station are carried out 3D test, second the 3D glasses 10 being in the second station are carried out press key lamp optical tests, carries out streamlined operation and so forth.

In sum, adopt this 3D glasses integrated test device, achieve annular automation continuous productive process, not only equipment occupation space is little, and decrease manual operation, avoid manpower waste, and substantially increase operating efficiency, it also avoid the impact of human factor on test simultaneously, and then ensure that the uniformity of properties of product.

The foregoing is only preferred embodiment of the present invention, not in order to limit the present invention, all any amendments done within the spirit and principles in the present invention, equivalent replacement and improvement etc., all should be included within protection scope of the present invention.

Claims (10)

1. a 3D glasses integrated test device, comprise the fixed head be arranged in frame, it is characterized in that: described fixed head is provided with the rotating disk driven by intermittent drive unit, the periphery of described rotating disk is evenly provided with some positioning tools for locating 3D glasses, be equipped with electric supply installation with on the described rotating disk of each described positioning tool correspondence position, the described fixed head being positioned at described rotating disk periphery be provided with successively RF test cell, 3D test cell, press key lamp optical tests unit and classification pick device;

The first station be positioned on the described fixed head of described rotating disk periphery is blowing station, and corresponding second station of described RF test cell, described 3D test cell, described press key lamp optical tests unit and described classification pick device difference is to the 5th station;

A key device for switching on and shutting down is respectively equipped with at described second station and the 4th station place.

2. a kind of 3D glasses integrated test device according to claim 1, it is characterized in that: described positioning tool comprises the locating piece be arranged on described rotating disk, described locating piece is provided with the stopper slot for limiting 3D eye positions, described locating piece is provided with near the side of described RF test cell and carries out the antenna escape groove of testing for described RF test cell;

Described locating piece is also provided with and carries out testing for described 3D test cell and the LED lamplight of through described locating piece thickness dodges hole, described LED lamplight is dodged hole and is arranged with eyeglass is corresponding on described 3D glasses.

3. a kind of 3D glasses integrated test device according to claim 2, it is characterized in that: described electric supply installation comprises and being arranged on described rotating disk and the lead that arrange corresponding to described positioning tool, described lead is slidably installed the positive and negative electrode simulation mechanism of oriented described 3D glasses continued power, described positive and negative electrode simulation mechanism is provided with the positive conductive electrode shell fragment of feeding pannel positive contact on described 3D glasses with feeding pannel cathode contact on described 3D glasses and the conduction negative pole of elastic telescopic, described positive conductive electrode shell fragment is obliquely installed to the positive extreme direction of described feeding pannel near one end of described 3D glasses,

The top of described positive and negative electrode simulation mechanism is provided with elastic hold-down mechanism, and described lead is positioned at the side away from described antenna escape groove;

Described first station and described 5th station place are respectively equipped with the first power set driving described positive and negative electrode simulation mechanism vertically to slide.

4. a kind of 3D glasses integrated test device according to claim 3, it is characterized in that: described positive and negative electrode simulation mechanism comprises the holder be slidably mounted on described lead, described holder is provided with near the side of described 3D glasses and protrudes described holder and compact heap for compressing described 3D glasses; Described holder is made up of insulating materials, described holder is provided with the first T-shaped counterbore, described conduction negative pole is arranged in described first counterbore, the top being positioned at described conduction negative pole is provided with the first conductive electrode be connected with direct current negative pole, is provided with the first power spring between described first conductive electrode and described conduction negative pole;

The described holder being positioned at described first counterbore side is also provided with unthreaded hole, in described unthreaded hole, is provided with the second power spring; Described positive conductive electrode shell fragment to be arranged on described holder and correspondingly with described unthreaded hole position to arrange, and the top of described second power spring is provided with the second conductive electrode be connected with direct current positive pole.

5. a kind of 3D glasses integrated test device according to claim 4, is characterized in that:

Described direct current is button cell;

The top of described holder is provided with the middle base be made up of insulating materials, battery compartment for installing described button cell is arranged at described middle base, described middle base is also provided with inverted T shape second counterbore be all communicated with described battery compartment with described first counterbore, described first conductive electrode is arranged in described second counterbore; The described middle base being positioned at described battery compartment side is provided with the 3rd counterbore of inverted T shape, and described second conductive electrode is arranged in described 3rd counterbore;

Described middle base is provided with the gland be made up of insulating materials, being slidably fitted with the conductive handle for being connected described second conductive electrode and described button cell positive pole between described gland with described middle base, between described conductive handle and described gland, being provided with reposition element.

6. a kind of 3D glasses integrated test device according to claim 2, it is characterized in that: described RF test cell comprises the test antenna be positioned at below described antenna escape groove, described test antenna is driven to described positioning tool direction by the second power set;

Described press key lamp optical tests unit comprises the color sensor that arrange corresponding to described antenna escape groove, and described color sensor is driven to described positioning tool direction by the 3rd power set.

7. a kind of 3D glasses integrated test device according to claim 6, it is characterized in that: described key device comprises the first support be arranged on described fixed head, described first support is provided with the guide rail be arranged in parallel with described rotating disk, described guide rail is provided with the slide block driven by the 4th power set, described slide block is provided with two spaced back-up blocks, be provided with the pressing axis for pressing button on described 3D glasses described in two between back-up block, back-up block described in two is all protruded at the two ends of described pressing axis;

Described pressing axis described in two between back-up block is provided with back-up ring, between described back-up ring and the described back-up block away from described 3D glasses side, is provided with stage clip; Described pressing axis away from described 3D glasses one end is provided with rotation-preventing mechanism.

8. a kind of 3D glasses integrated test device according to claim 2, it is characterized in that: described 3D test cell comprises the lower mount pad be positioned at below described positioning tool, described lower mount pad is driven to described positioning tool direction by the 5th power set; Described fixed head is provided with the second support, described second support is provided with the 6th power set and drives and extend to the upper mount pad above described positioning tool, one of them in described upper mount pad and described lower mount pad is provided with LED, another is provided with electrooptical device, and described LED and described electrooptical device are corresponding up and down to be arranged and dodges with described LED lamplight that hole is corresponding to be arranged.

9. a kind of 3D glasses integrated test device according to claim 1, it is characterized in that: described classification pick device comprises the 3rd support be arranged on described fixed head, described 3rd support is rotatablely equipped with the cylinder driven by electric rotating machine, and described cylinder vertically drives the sucker extended to above described positioning tool;

The all sides of described cylinder are provided with the fan-shaped catch being no more than 180 °, described 3rd support is provided with the photoelectric sensor switch for responding to described catch, when arriving feeding position, described photoelectric sensor switch detects the end edge of described catch and sends signal and control described electric rotating machine and stop operating, and described electric rotating machine is turned left by feeding position or the angle of turning right all is less than the fan angle of described catch.

10. a kind of 3D glasses integrated test device according to claim 9, it is characterized in that: described 3rd support is also provided with the limited block limiting described catch swing offset, described limited block and described photoelectric sensor switch are 180 ° and distribute.