Electron gun convergence cup automatic positioning device of cathode ray tube
专利摘要:
The present invention provides an electron gun convergence cup automatic positioning apparatus of a cathode ray tube for welding assembly with a bulb spacer and loading a convergence cup into an inspection apparatus. The convergence cup automatic positioning device includes: a plunger 402 reciprocating to open and close the outlet of the linear feeder 13 so that one convergence cup 2 is discharged from the linear feeder 13; Driving roller 404 in contact with the convergence cup 2 such that one convergence cup 2 moves in contact with its front end and rotates the convergence cup 2 at its moving position when the plunger 402 is advanced. And driven roller 405; And while the convergence cup 2 is rotated, it is characterized in that it comprises a light sensor 406 for determining the position by checking the position of the electron beam through hole (4) of both ends. Accordingly, even with a simple structure, it is possible to accurately determine the angular position of the convergence cup supplied from the linear feeder without malfunction due to wear of the parts, and furthermore, it is possible to load the welding assembly and inspection line without error. 公开号:KR19990043923A 申请号:KR1019970064970 申请日:1997-11-29 公开日:1999-06-15 发明作者:심종보;권혁우 申请人:김영남;오리온전기 주식회사; IPC主号:
专利说明:
Electron gun convergence cup automatic positioning device of cathode ray tube The present invention relates to an electron gun convergence cup automatic positioning device of a cathode ray tube, and more particularly, to a welding assembly and inspection apparatus of an electron gun convergence cup and a bulb spacer of a cathode ray tube, in which a convergence cup is loaded on a welding assembly and an inspection line. The present invention relates to an electron gun convergence cup automatic positioning device of a cathode ray tube having a simple structure that can be automatically loaded and positioned. Generally, a convergence cup and bulb spacer assembly 1 as shown in FIG. 1 is attached to the front end of the electron gun of the cathode ray tube, and three electron beams in a straight line in the case of an inline electron gun at the bottom of the convergence cup 2. A through hole 4 is formed, and a plurality of bulb spacers 3 are usually attached to the side wall portion thereof, and the bulb spacers 3 come into contact with the inner surface of the neck portion of the bulb, so that the front of the electron gun is connected to the neck portion. It will be kept in the center of the circular section. Therefore, before assembling the electron gun, the bulb cup 3 is assembled to the convergence cup 2 by welding at predetermined positions, and the cup 2 is welded and assembled to the other electrode of the convergence cup 2. And parts are assembled together to form an electron gun. The convergence cup and bulb spacer assembly 1 of this structure is usually assembled by laser welding the bulb spacer 3 supplied from the other side at the welding station while transferring the convergence cup 2 along the welding assembly and inspection line. Later, it is transferred to an inspection station, which is usually inspected by measuring the relative height of the bulb spacer 3 of the assembly 1 and, as a result, unloading or ejecting according to the quantity and fire. However, conventionally, when loading the convergence cup (2) in the welding assembly and inspection line, the position of the electron beam through hole (4) of the convergence cup (2) by checking the convergence cup (2) by loading Robert After rotating by a predetermined angle and loading into the positioner of the welding assembly and inspection line 15, a complicated structure of Robert was required. When the precision is degraded due to abrasion of the connecting portion, it is difficult to load the convergence cup 2. There was a problem such as being. Accordingly, the present invention is to solve the above problems, the automatic positioning of the electron gun convergence cup of the cathode ray tube of a simple structure that can determine the angular position of the convergence cup supplied from the linear feeder and load it into the welding assembly and inspection line The object is to provide a device. 1 is a cross-sectional view showing an assembly of an electron gun convergence cup and a bulb spacer of a cathode ray tube; 2 is a flow chart showing the welding assembly and inspection process of the convergence cup and bulb spacer in FIG. 3 is a schematic plan view of the welding assembly and inspection apparatus of the electron gun convergence cup and bulb spacer of the cathode ray tube to which the convergence cup automatic positioning device of the present invention is applied; 4 is a front sectional view showing a welding assembly and an inspection line for inspecting and unloading a bulb spacer after welding by loading a convergence cup; 5 is a plan view of FIG. 6 is a plan view for explaining the operation of the transfer bar using the cam means, 7 is a front view of FIG. 6 in a state in which the spring means for leftward movement is removed from FIG. 6; 8 is a cross-sectional view of the refilling device for replenishing the convergence cup to the bowl feeder in FIG. 9 shows the configuration of a bowl feeder and a linear feeder for supplying the convergence cup in FIG. 3 together with the location device of the convergence cup and the loading device for welding assembly and loading in the inspection line of FIG. 4. Floor plan shown, 10 is a cross-sectional view of the bowl feeder and linear feeder of FIG. 11 is a side view of FIG. 9, 12 is a plan view showing a bulb spacer feeder together with a bulb spacer pickup and transfer device, 13 is a front view of FIG. 12, 14 is a left side view of FIG. 13, FIG. 15 is a sectional view showing a stopper of the bulb spacer in FIG. 13; 16 is a plan view showing a pusher device for contacting a convergence cup with a bulb spacer transferred to a welding station by a pickup and transfer device, 17 is a configuration diagram showing a height inspection device, 18 is a configuration of the tilt angle inspection device, FIG. 19 is a time chart of the cam diagram of the up and down cams and the transfer cams of the convergence cup and the rotational movement of the transfer, pushing, welding and convergence cups of the bulb spacer; * Explanation of symbols for the main parts of the drawings 1: convergence cup and bulb spacer assembly 2: convergence cup 3: bulb spacer 4: electron beam through hole 10: welding assembly and inspection device 11: convergence cup refilling device (11) 12,16 bowl feeder 13,17 linear feeder 14: location and loading device 15: welding assembly and inspection line 18: bulb spacer rotation device 19: pickup and transfer device 20: welding apparatus 21: eject chute 30: pusher 31: fixing table 32: air cylinder 33: pusher 40: height inspection device 41: contact block 42: gap sensor 50: tilt angle inspection device 51: Bulb spacer insert block 51 ': Insertion groove 52: defective detection sensor 100: hopper 101,201,301,602,702 Vibration means 102 Information guide 103: overflow finger 200,601: bowl 203: touch sensor 204: Tachibaa 300,701: linear feeder plate 401: air cylinder 402: plunger 404: driving roller 405: driven roller 406: optical sensor 407: air cylinder 408: connecting fixture 409: air cylinder 410: adsorption bar 411: vacuum hose 501: fixed plate 502,503: guide block 511: up-down connecting rod 512,513: fixing plate 521 to 524: spring 531: driven rollers 532 to 535 ': up-down cam 540: positioner 540 ': knockout-bar 550: step motor 551: transfer bar 552: convergence cup seating groove 553: round-trip block 554: guide block 555: spring 556: Chain 557: guide sprocket 558: driven lever 559,561: shaft 560: transfer cam 703: solenoid 704: stopper 801: bulb spacer rotator 802: Rotary Cylinder 810: Pickup Finger 811: air chuck In order to realize the above object, the present invention is provided with one positioner in each of a plurality of stations arranged in a line with a constant interval to form a welding assembly and inspection line, the electron gun of the cathode ray tube when the plurality of positioners are up The convergence cup is placed on top of it to perform welding or inspection process and transfer by step by transfer means when it is down, and the positioner has a location and loading device for determining and loading the position of the convergence cup from the linear feeder. A welding assembly and inspection device for an electron gun convergence cup of a cathode ray tube and a bulb spacer, the apparatus comprising: a plunger reciprocating to open and close an outlet of the linear feeder so that one convergence cup is discharged from the linear feeder; A driving roller and a driven roller contacting the convergence cup so that one convergence cup moves in contact with its front end and rotates the convergence cup at its moving position when advancing the plunger; And while the convergence cup is rotated, it provides an electron gun convergence cup automatic positioning device of the cathode ray tube, characterized in that it comprises a light sensor for determining the position of each of the electron beam through hole to determine the position. And a control device for stopping the rotation of the driving roller and reversing the plunger when the angular position is determined by the optical sensor, and a roller may be attached to the front end of the plunger to facilitate the rotation. When the angular position is determined, the convergence cup may be controlled by the control device to be sucked by the adsorption bar of the loading device and loaded into the weld assembly light inspection line. Hereinafter, with reference to the accompanying drawings, an embodiment of the present invention, as follows. First, in the overall schematic plan view of the welding assembly and inspection apparatus of the electron gun convergence cup and bulb spacer of the cathode ray tube according to the present invention as shown in FIG. 3, the convergence cup 2 is a refill device 11, a bowl feeder 12, Loading into the initial station ST1 of the welding assembly and inspection line 15 while the initial positioner 540 (shown in FIGS. 4 and 6) is up via the linear feeder 13 and the location and loading device 14. The convergence cup 2 is transferred one by one while the positioner 540 is down along the respective stations ST1 to ST9 of the welding assembly and inspection line 15 to process the corresponding stations ST1 to ST9. Will be performed. The bulb spacer 3 is supplied to the welding station ST5 via the bowl feeder 16, the linear feeder 17, the rotary device 18, the pickup and the transfer device 19, and is pushed by the pusher device 30. The laser welding is performed by the welding apparatus 20 while being supported at a predetermined position of the convergence cup 2, and this is repeated as many times as necessary for the bulb spacer 3, and then through the various inspection processes, the eject chute 21 Through the volume, it is ejected, separated by fire. Figure 2 shows a process performed in the welding assembly and inspection apparatus of the electron gun convergence cup and bulb spacer of the cathode ray tube according to the present invention described above. In Fig. 2, the convergence cup (2: denoted C / C in Figs. 2 and 19) and the bulb spacer (3: denoted B / S in Figs. 2 and 19) are processed and prepared, respectively, in steps S1 and step. In S21, the bowl feeders 12 and 16 are fed into the bowl feeder and linearly fed in steps S2 and S22 by the linear feeders 13 and 17 connected to the bowl feeders 12 and 16. As such, the bowl feeders 12 and 16 and the linear feeders 13 and 17 may include the convergence cup 2 accommodated by the bowl 200 and 601 and the vibration means 201 and 602 in FIGS. 9, 10, 12, and 13. When the bulb spacers 3 are discharged one by one, the linear spacers 13 and 17, which are similarly constituted by the vibration means 301 and 702 and the linear feeder plates 300 and 701, are continuously flowed in a row. In the case of the convergence cup (2), because the size is larger than the bulb spacer (3) can be accommodated in the bowl 200 is limited it can be provided with a separate refilling device (11) in Figs. The refilling device 11 includes a hopper 100 capable of storing a large amount of convergence cup 2, a flow guide 102 of the convergence cup 2 communicated with the lower end of the hopper 100, It comprises a vibrating means 101, the vibrating means 101 by the detection signal when there is no convergence cup (2) on the bottom of the bowl 200 by the Tachiba 204 and the touch sensor 203. This operation causes the convergence cup 2 to flow through the flow guide 102. In order to prevent the convergence cup 2 from flowing excessively from the hopper 100 into the flow guide 101, an overflow preventing plate 103 is installed on the top of the flow guide 101 as shown in FIG. 8. Can be. In the case of the convergence cup 2 through the linear feeding step (step S2 and step S22) in FIG. 2, the convergence cup 2 is positioned at the welding assembly and inspection line 15 in the positioning step (step S3). ), The position of the convergence cup 2 is first set so that the position can be set through the electron beam passing hole 4. Also, in step S4, the welding assembly and inspection line 15 is loaded into the initial positioner 540. That is, as shown in FIG. 11, which is the right side view of FIGS. 9 and 9, the convergence cup 2 continuously fed from the linear feeder 13 is reciprocated by the air cylinder 401 at its exit. By the advance of the plunger 402, it engages between the driving roller 404 and the driven roller 405 one by one to rotate together when the driving roller 404 rotates. At this time, the other convergence cup 2 is in the standby state at the exit of the linear feeder 13, and when the plunger 402 is backward, the outlet is opened so that one convergence cup 2 can be discharged. The above operation is repeated. During the rotation, when the position of the electron beam through hole 4 is confirmed by the optical sensor 406, the driving roller 404 immediately stops by the confirmation signal, and the suction bar 410 is waiting on the upper portion. Is inserted into the convergence cup 2 in advance of the air cylinder 408 and brought into a vacuum state through the vacuum hose 411, the convergence cup 2 is attached to the adsorption bar 410, and then the air cylinder As the 408 retracts and the air cylinder 407 retracts, the convergence cup 2 is positioned above the positioner 540 of the first station ST1 of the weld assembly and inspection line 15. At this time, when the air cylinder 408 is advanced and the vacuum state of the vacuum hose 411 is released at the same time, the convergence cup 2 has the positioning pin protruding from the upper end of the positioner 540 of the convergence cup 2. It is loaded while being inserted into the electron beam passing hole (4). The connecting fixture 408 is a fixing device for fixing the air cylinder 408 to the connecting rod of the air cylinder 407. In this way, the convergence cup 2 of which the loading operation is completed is transferred one step through the welding assembly and inspection line 15 to perform a predetermined process at each station ST1 to ST9 and be discharged. In the welding assembly and inspection apparatus according to the present invention in the welding assembly and inspection line 15, forge girls 540 are disposed at respective stations ST1 to ST9, and the plurality of positioners 540 are disposed during the process execution time. It is up, held in its rising position, and then in the down state, the transfer is carried out and the down state (step S5) is maintained for the time to transfer to the next stations ST1 to ST9. For example, in FIG. 2, after the convergence cup 2 is loaded, the positioner 540 is lowered (step S5) and is moved to the welding station ST5 in step S6. However, in FIG. 3 and below, three steps are interposed between the welding station ST5 and the loading station ST1, indicating that other processes may be performed. For example, inspection of the convergence cup 2 itself, or the process of air | atmosphere is mentioned. 4 to 6 disassemble the positioner 540 of the welding assembly and inspection line 15, its up-down device and the transfer means. In FIG. 4, the transfer bar 551 shown in FIG. 6 is shown in dashed-dotted line and in FIG. 5 in a removed state. In FIG. 4 and FIG. 5, a positioner 540 is disposed at each of the stations ST1 to ST8, and the positioner 540 is disposed up and down via an up-down connecting rod 511 by up-down cams 532 to 535 installed at a lower portion thereof. Up and down along a predetermined cam diagram. The final station ST9 is provided with a knockout-bar 540 'which is fixed to the positioner 540 of the previous station ST8 and moves up and down together, and is transferred to the station ST9 when it is up after transfer. The assembled and inspected convergence cup and bulb spacer assembly 1 is discharged from the transfer means into the eject suit. Cam diagrams of the up-down cams 532-535 are shown in FIG. 19 as an example. In FIG. 19, the up-down cam diagram C / C UP / DOWN of the convergence cup 2 is down during the transfer T of the convergence cup 2 in the transfer diagram C / C TRANSFER of the convergence cup 2. Must be up (eg between θ9 and 360 degrees) and up at the time of untransfer (UT) for return (between θ1 and θ5). In addition to these conditions, the up state must be maintained for a time required to perform a predetermined process at each station ST1 to ST9 (between θ1 and θ8). This up state is required, for example, during the transfer and pushing and welding time of the plurality of bulb spacers 3 in the welding station ST5. That is, in the welding station ST5, the positioner 540 is connected to the up-down connecting rod 511 via the step motor 550, as shown in FIG. 3, and C / C ROTATING and R / S TRANSFER in FIG. As shown in the PUSHING, WELDING diagram, the positioner 540 is configured to be intermittently rotated at a predetermined rotation angle to weld the bulb spacer 3 at each rotation angle position, and the entire bulb spacer 3 After welding, it goes down. The stations ST6 to ST7 may be appropriately selected between θ1 and θ8 during the time required for the inspection process, and thus, a cam diagram may be selected that varies according to the characteristics of each process. In FIG. 4, fixing plates 512 are provided to fix two or more up-down connecting rods so that the stations ST2 to ST4 follow the cam diagram of one up-down cam 533, and similarly to stations ST6 to ST8. Fixing plates 512 and 513 are installed. On the other hand, each connecting rod 511 is configured to reduce the resistance through the rolling motion by contacting the cam surface of the up-down cams 532 to 535 via the driven roller 531 at the lower end, the up-down cams 532 to 535 The handle 22 is fixed to the shaft 530 of the up-down cams 532-535 to adjust the point of action of the. Accordingly, the point of action of the cam can be easily adjusted when it differs from other movements, and when the point of action of any one of the cams differs, the up-down cams 532 to 535 each have a bolt 532 on the shaft 530. And 535 to be assembleably fixed, the mutual relationship can be adjusted. In addition, as shown in FIG. 3, the down stroke may be configured to ensure the down stroke by tension springs 522 and 524 in addition to its own weight during the down stroke, and the compression springs 521 and 523 to prevent excessive rise by inertia during up stroke. It may be installed between the guide blocks 502 and 503 fixed to the fixing plate 501 and the connecting rod 511. 5 and 6 show the transfer means. The transfer means is a pair of transfer bar 551 is fixed by the reciprocating block 553 at a predetermined interval that the positioner 540 can be up and down, guided by the guide roller 554 and between the stations The convergence cup 2 is transferred by reciprocating by the interval. In the transfer bar 551, the convergence cup seating grooves 552 are formed inward to each other so that the convergence cup 2 is held at a predetermined position when the positioner 540 is down by the up-down cams 532 to 535. It is inserted into the seating groove 552. As such, the convergence cup 2 is transferred from the seated groove 552 to the seated groove 552 and then up at a predetermined position by the positioner 540 to perform a predetermined process. 7 shows an example of a reciprocating mechanism of the transfer bar 551 and the reciprocating block 553 using a cam and a spring. A tension spring 555 is installed at one end of the reciprocating block 553 to move to the right in the drawing, and the other end is connected to one end of the driven lever 558 via a chain 556 and a guide sprocket 557. The other end of the driven lever 558 is fixed to the frame by the shaft 559, and the transfer cam 560, which rotates together with the shaft 561 in the middle, contacts the driven lever 558 at the bottom thereof, By rotating 558 in accordance with its cam diagram, the reciprocating block 553 moves to the left through the chain 556 against the elastic force of the tension spring 555. In the case where the transfer means has such a structure and the same axis as the axis 530 of the up-down cam or the same rotation as the axis 530, the cam curve of FIG. 19 is illustrated by the C / C TRANSFER of FIG. 19. In addition to this structure, a conventional air cylinder may be used as the transfer means. In FIG. 2, the bulb spacer 3 is fed in a continuous alignment state from the linear feeder 17 in step S22, and then the bulb spacer rotator of the rotating device 18 at the end of the linear feeder plate 701 in FIGS. 12 and 13. The solenoid 703 and the stopper 704 operate to flow to 801 and not to flow one or more of the bulb spacers 3 from the end of the linear feeder plate 701 as shown in FIGS. 13 and 15. ) Stop the flow. Thereafter, when the rotary cylinder 802 rotates in step S23, the rotator 801 rotates together to rotate the bulb spacer 3 by 90 degrees in an upright state, and the pick-up finger 810 is waiting for the air chuck 811. ), The bulb spacer 3 in the upright state is gripped as shown in Figs. 12 to 14 (step S24). After being held by the pick-up finger 810 in this manner, the rotator 801 returns to the win state, and as shown in FIG. 12, the air chuck 811 is positioned 811 ′, that is, the welding assembly and inspection line 15. ) Is transferred to the welding station ST5 by the reciprocating means (not shown) (step S25). By moving in this way, the upright bulb spacer 3 gripped by the pick-up finger 810 is a predetermined angle of the convergence cup 2 located on the up positioner 540 of the welding station ST5 in FIG. It is adjacent to the side wall surface of the position. In this state, as shown in FIG. 16, the bulb spacer 3 is pushed toward the convergence cup 2 by the pusher device 30, and the air spacer 811 is disengaged so that the bulb spacer 3 is picked up by the pick-up finger 810. In contact with the convergence cup (2), in which the pick-up finger (810) returns to its original position with the air chuck (811) and is in standby to pick up the next bulb spacer (3). (Step S7 '). The fixing step (step S7 ') may further include a means for reciprocating in a direction perpendicular to the reciprocating movement in addition to the reciprocating movement in order to ensure the separation of the pick-up finger 810 and return to the original position. have. The reciprocating means (not shown) may be a conventional reciprocating means such as an air cylinder, and may also be constituted by the transfer cam 559 and the through ring 555 shown in FIGS. 6 and 7. As described above in the fixed state in which the bulb spacer 3 is pushed to the convergence cup 2, the welding device 20 maintains the up position of the positioner 540 in the welding station ST5 as described above. By firing, the bulb spacer 3 is welded to the convergence cup 2 (step S8 in FIG. 2), and upon completion of welding, the bulb spacer 3 is released (step S8 '), and the step motor 550 After rotation by a predetermined angular displacement (step S9), it is determined by counting whether the previous bulb spacer 3 has been welded in step S10. If the previous bulb spacer 3 has not been welded, the process returns to step S7 'again. To step S10 are repeated. Thus, steps S21 to S25 for supplying the bulb spacer 3 are carried out by placing the desired number of bulb spacers while transferring the convergence cup 2 onto the positioner 540 and up the positioner 540. And (3). That is, as shown in the B / S TRANSFER, PUSHING, WELDING diagram and C / C ROTATING diagram in FIG. 19, the transfer of the bulb spacer 3 during the up time (θ1 to θ8) of the C / C UP / DOWN diagram is shown. , Pushing and fixing the welding and rotation of the convergence cup 2 to a predetermined angular position are repeated N times when the N bulb spacers 3 are attached to one convergence cup 2. When the transfer of the bulb spacer 3 together with the chuck 811 is completed, pushing is performed by the pusher device 30 and the return of the air chuck 811, that is, the untransferring UT is performed. At the time when the pushing is completed, the welding W1 to WN is performed. Therefore, in consideration of such a timing chart, the controller performs control by the controller or transfers the bulb spacer 3 to the welding station by the transfer cam 559 and the spring 555 shown in FIGS. 6 and 7. In such a configuration, the cam surface curve and the cam curve of the transfer cam should be selected in consideration of the B / S TRANSFER diagram of FIG. 19 as an example. In the C / C ROTATING diagram of FIG. 19, the rotation of the bulb spacer 3 can be directly performed at the transfer position of the convergence cup 2. 2) It is not necessary to rotate R1, and the convergence when the bulb spacer 3 is welded at each position where the convergence cup 2 and the positioner 540 have not returned to their original state at the final rotation RN. It will be necessary to return the convergence cup 2 and the positioner 540 to their original state before the down start time θ8 of the cup 2. In FIG. 2, after the welding of the entire bulb spacer 3 is completed in step S10, the positioner 540 is lowered in step S11, and the convergence cup 2 is positioned in the seating groove 552 of the transfer bar 551. (2) is transferred to the inspection stations ST6 and ST7 by the rotation of the transfer cam 560 and the action of the tension spring 555 (step S12), which is shown in FIGS. 17 and 18 in the inspection stations ST6 and ST7. As shown, the weld assembly state of the bulb spacer 3 to the convergence cup 2 is examined by the height inspection apparatus 40 and the inclination-angle inspection apparatus 50 (step S13). In FIG. 17, when the positioner 540 is up by the rotation of the up-down cam 535 as described above from the transfer bar 551, the contact block 41 is positioned at a position corresponding to the height of each bulb spacer 3. By the contact with the contact block 41, the clearance sensor 42 determines the amount and the fire of the height of the bulb spacer 3. In FIG. 18, the inclination angle inspection device 50 includes an insertion block 51 and a defect detection sensor 52, and the insertion block 51 has an insertion groove 51 ′ at a position where the bulb spacer 3 can be inserted. If the bulb spacer 3 is not inserted into the insertion groove 51 'when the positioner 540 is up, the defect detection sensor 52 treats the defect as defective. On the other hand, after the positioner 540 is up, the height inspection device 40 and the inclination angle inspection device 50 are also lowered and inspected as shown by the arrows in Figs. When the inspection process is completed in this way, the convergence cup 2 is transferred again and unloaded in step S14. In FIG. 4 and FIG. 5, the first standby at the station ST8 is transferred to the station ST9 and then discharged to the eject chute 21 by the eject bar 540 ′. Although the specific illustration is abbreviate | omitted in the eject chute 21, the well-known rotating door apparatus is installed so that it may discharge separately according to quantity and fire. As described above, according to the configuration and function of the electron gun convergence cup automatic positioning device of the cathode ray tube according to an embodiment of the present invention, the reciprocating plunger 402, the driving roller 404 and the driven roller 405 and the optical sensor The simple configuration of 406 can accurately determine the angular position of the convergence cup supplied from the linear feeder without malfunction due to wear of the parts, and furthermore, it can be loaded into the welding assembly and inspection line without error.
权利要求:
Claims (4) [1" claim-type="Currently amended] One positioner 540 is provided at each of the plurality of stations ST1 to ST9 arranged in a line with a predetermined interval so as to form the welding assembly and inspection line 15, and the cathode ray when the plurality of positioners 540 are up. The electron gun convergence cup 2 of the tube is placed on top of it to perform the welding or inspection process and is transferred step by step by the transfer means when it is down, and the positioner 540 from the linear feeder 13 to the convergence cup ( In the welding assembly and inspection apparatus of the electron gun convergence cup (2) and bulb spacer (3) of the cathode ray tube having a location and loading device for determining and loading the position of 2): A plunger 402 whose location and loading device reciprocates to open and close the outlet of the linear feeder 13 such that one convergence cup 2 is discharged from the linear feeder 13; Driving roller 404 in contact with the convergence cup 2 such that one convergence cup 2 moves in contact with its front end and rotates the convergence cup 2 at its moving position when the plunger 402 is advanced. And driven roller 405; And While the convergence cup 2 is rotated, the electron gun convergence cup of the cathode ray tube, characterized in that it comprises an optical sensor 406 for checking the position of the electron beam through hole (4) at both ends to determine the angular position. Automatic positioning device. [2" claim-type="Currently amended] The electron gun convergence cup of a cathode ray tube according to claim 1, wherein the optical sensor 406 is controlled to stop the rotation of the driving roller 404 and to reverse the plunger 402 when the angular position is determined. Automatic positioning device. [3" claim-type="Currently amended] 3. The electron gun convergence cup automatic positioning device according to claim 1 or 2, wherein a roller is attached to a front end of the plunger (402) to facilitate rotation. [4" claim-type="Currently amended] The cathode ray tube according to claim 1 or 2, wherein the convergence cup (2) is sucked by the suction bar (410) and loaded into the welding assembly and inspection line (15) when the angular position is determined. Electron gun convergence cup automatic positioning device.
类似技术:
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同族专利:
公开号 | 公开日 KR100449998B1|2005-09-26|
引用文献:
公开号 | 申请日 | 公开日 | 申请人 | 专利标题
法律状态:
1997-11-29|Application filed by 김영남, 오리온전기 주식회사 1997-11-29|Priority to KR1019970064970A 1999-06-15|Publication of KR19990043923A 2005-09-26|Application granted 2005-09-26|Publication of KR100449998B1
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申请号 | 申请日 | 专利标题 KR1019970064970A|KR100449998B1|1997-11-29|1997-11-29|Electron gun convergence cup automatic positioning device of cathode ray tube| 相关专利
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