JP2011149917A - Probe cleaning unit, and panel inspection device and probe cleaning method having the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a probe cleaning unit that selects only a probe assembly having a probe requiring cleaning and efficiently cleans the probe by easy operation. <P>SOLUTION: This probe cleaning unit includes an arm section movably attached to a probe unit of a panel inspection device between positions corresponding to at least the probe assemblies, a body section attached to the arm section, a moving base supported by the body section linearly reciprocatably, a means for linearly reciprocating the moving base with respect to the body section, and a distance adjusting mechanism for adjusting the distance between the arm section and the moving base so that a first cleaning means attached to the moving base comes into contact with the tips of a plurality of probes of the probe assemblies when the moving base is linearly reciprocated with respect to the body section. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a probe cleaning unit used for cleaning a probe in an inspection apparatus for a display panel such as a liquid crystal panel, a panel inspection apparatus including the probe cleaning unit, and a probe cleaning method.

  In a lighting inspection device that inspects the presence or absence of a defect in a pixel by actually lighting a display panel such as a liquid crystal panel, a probe unit having a plurality of probe assemblies each having a plurality of probes is mounted relative to the panel to be inspected. It is necessary to bring the plurality of probes into contact with the electrodes of the panel to be inspected. However, when the probe comes into contact with the electrode of the panel to be inspected, it is inevitable that metal such as aluminum, which is an electrode material, is scraped off and attached to the tip of the probe as metal waste. Since the attached metal debris becomes an insulator when oxidized, if the number of contact between the probe and the electrode increases, the electrical continuity between the probe and the electrode is hindered by the metal debris oxide adhering to the probe tip. May come. In addition to metal, which is an electrode material, foreign material such as sealant flaws and other dust remaining around the electrode may adhere to the tip of the probe. As the number of inspection panels increases, The frequency of contact failure between the probe and the electrode tended to increase.

  For this reason, conventionally, in a panel inspection apparatus that performs inspection by bringing a probe into contact with an electrode of a panel to be inspected, when a certain number of display panels are inspected, the probe assembly is removed from the probe unit, and polishing treatment is performed. The work is set on a tool, and the tip of the probe is polished and cleaned, and after the cleaning, the work of attaching to the probe unit is performed regularly. However, it takes time and labor to remove the probe assembly from the probe unit and attach it to the probe unit, and the work load increases, and inspection cannot be performed during that time, so inspection efficiency deteriorates. There was a problem.

  In order to eliminate such inconveniences, it has been conventionally proposed to polish and clean the probe tip while the probe assembly is attached to the probe unit. For example, in Patent Document 1, after inspecting a predetermined number of liquid crystal panels, a polished glass plate is placed on an inspection table instead of the liquid crystal panel, and the probe tip is brought into contact with the polished glass plate. A method of polishing a part is disclosed. However, this polishing method requires a large polished glass plate that is approximately the same size as the liquid crystal panel. When polishing, the polished glass plate is placed on the inspection table, and when polishing is completed, the polished glass plate is removed from the inspection table. In addition, it takes time and effort, and since all the probes come into contact with the polished glass during polishing, there is a disadvantage that even a clean probe is polished.

  In Patent Document 2, a resin insulating film mixed with an abrasive is formed between the electrodes of the liquid crystal panel to be inspected, and when a contact failure occurs between the probe and the electrode, the position of the probe is shifted. A method has been proposed in which the probe tip is cleaned by bringing the probe into contact with a resin insulating film on the liquid crystal panel. However, in this method, it is necessary to form a resin insulating film on each liquid crystal panel, and the manufacturing cost of the liquid crystal panel increases. Also in this case, since all the probes come into contact with the resin insulating film containing the abrasive during polishing, there is a disadvantage that even clean probes are polished.

  Furthermore, Patent Document 3 discloses a panel inspection apparatus in which a swing arm is attached to each probe assembly including a plurality of probes, and a cleaning bar is attached to the tip of the swing arm. When the chuck top on which the liquid crystal panel is placed rises, the swing arm swings accordingly, the cleaning bar contacts the electrode surface of the liquid crystal panel to clean the electrode surface, and the cleaning bar also contacts the tip of the probe. Thus, the probe can be cleaned. However, in the panel inspection apparatus disclosed in Patent Document 3, a swing arm having a cleaning bar must be attached to each probe assembly, and the manufacturing cost of the inspection apparatus increases. Since the cleaning of the probe tip only involves bringing the cleaning bar into contact with the probe tip, for example, there is an unsatisfactory effect that metal debris such as attached aluminum cannot be sufficiently removed.

JP 7-199141 A JP 2000-66184 A JP 2008-45937 A

  The present invention has been made to solve the above-mentioned disadvantages of the prior art, and does not require a large frosted glass plate or special liquid crystal panel, and selects only a probe assembly that is heavily soiled. It is an object of the present invention to provide a probe cleaning unit, a panel inspection apparatus including the probe cleaning unit, and a probe cleaning method that can clean the probe well.

  As a result of various trials and errors to solve the above-mentioned problems, the present inventors have found that the probe cleaning unit having the probe cleaning means is placed between the positions corresponding to the individual probe assemblies constituting the probe unit. By making it movable, it has been found that it is possible to efficiently polish and clean a probe that is extremely dirty and needs to be cleaned in a probe assembly unit, and the present invention has been completed.

  That is, the present invention includes a probe unit including one or a plurality of probe assemblies each having a plurality of probes, and the probe units are moved relative to the panel to be inspected so that the plurality of probes are inspected. A probe cleaning unit for use in a panel inspection apparatus that is in contact with an electrode of the panel and inspects a panel to be inspected; the probe cleaning unit corresponds to at least each of the probe assemblies with respect to the probe unit of the panel inspection apparatus An arm part movably attached between the positions to be moved; a main body part attached to the arm part; a movement base supported by the main body part so as to be able to reciprocate linearly; Means for reciprocating linearly with respect to the body; and reciprocating the moving base linearly with respect to the main body. And a distance adjusting mechanism for adjusting the distance between the arm portion and the moving base so that the first cleaning means attached to the moving base contacts the tips of the plurality of probes of the probe assembly. The problem described above is solved by providing a probe cleaning unit.

  Since the probe cleaning unit of the present invention is configured as described above, when the probe becomes dirty and needs cleaning, the probe cleaning unit is moved to the position of the probe assembly including the probe. The probe can be cleaned in units of the probe assembly while the probe assembly is still attached to the probe unit. As the first cleaning means, any means may be used as long as it is usually used for polishing and cleaning of the probe tip. Metal scraps etc. attached to the probe in contact with the probe tip Preferably, a polishing body that can remove the foreign matter, or a cleaning brush that can remove dust attached to the probe in contact with the probe tip, or wrinkles of the sealing agent, and the like.

  In a preferred aspect of the probe cleaning unit of the present invention, a cleaning body base to which second cleaning means is attached is attached to the moving base, and the moving base is reciprocated linearly with respect to the main body. A first cleaning position where the first cleaning means attached to the moving base can come into contact with the tips of the plurality of probes of the probe assembly, and the second cleaning means attached to the cleaning body base. Is provided with a cleaning means switching mechanism for moving the moving base with respect to the arm portion between the second cleaning position and the second cleaning position where it can come into contact with the tips of the plurality of probes of the probe assembly.

  As the second cleaning means, as in the case of the first cleaning means, any means can be used as long as it is normally used for polishing and cleaning the probe tip, but it is in contact with the probe tip. A cleaning brush that can remove dust adhering to the probe and sealant wrinkles, or an abrasive that can remove foreign matter such as metal debris attached to the probe in contact with the probe tip is preferably used. . Although the 1st cleaning means and the 2nd cleaning means may be the same or different, since the different one can respond to various dirt, it is convenient.

  When the probe cleaning unit of the present invention includes the cleaning body base, the cleaning body base reciprocates linearly with respect to the main body at the second cleaning position with respect to the moving base. The second cleaning means that is attached to the cleaning body base when attached is movably attached between a cleaning position that contacts the tips of the plurality of probes of the probe assembly and a retracted position that does not contact. Is preferred.

  Moreover, the probe cleaning unit of this invention WHEREIN: In the preferable one aspect | mode, the said movement base contains a movement base main body and the cleaning body support part, and the said movement base main body can reciprocate linearly with respect to the said main body part. The cleaning body support portion is supported so as to be swingable with respect to the moving base body about a swinging shaft parallel to a reciprocating shaft of the moving base body. In the case of such a configuration, even if the tip of the probe row in the probe assembly to be cleaned and the first cleaning means are not parallel and both are inclined relatively, for example, the first When the cleaning means is lifted from the lower side of the probe row and brought into contact with the tip end portion of the probe row, the cleaning body support portion rotates around the swing shaft following the inclination of the probe row tip portion, and the first cleaning means And the tip of the probe row are in a parallel state. This prevents the first cleaning means from coming into contact with the tip end of the probe row, and the cleaning by the first cleaning means is performed without unevenness and also prevents the probe row tip end from being reduced. In addition, what is necessary is just to attach the said cleaning body base to the said cleaning body support body which can swing freely, when attaching a cleaning body base to a movement base. As a result, even when the probe is cleaned by the second cleaning means attached to the cleaning body base, the cleaning body base rotates around the swing shaft following the inclination of the tip of the probe row, and the second cleaning means and the probe There is an advantage that contact with the front end of the row is prevented.

  The probe cleaning unit of the present invention may be attached to the probe unit of the panel inspection apparatus so as to be movable at least between positions corresponding to the probe assemblies, and the attachment mechanism is not particularly limited. When the cleaning unit is detachably attached to each of the probe assemblies via the arm portion, there is an advantage that the probe cleaning unit can be moved between the probe assemblies by a simple mechanism. This is preferable. Further, when the arm portion is attached to the probe unit via a guide mechanism that guides the movement thereof linearly, preferably linearly along the plurality of probe assemblies, a plurality of probe cleaning units of the present invention are provided. This is preferable because the advantage that it can be easily moved between the probe assemblies is obtained.

  In addition to the position corresponding to each of the probe assemblies, it is desirable that the arm portion is movably attached between a position corresponding to each of the probe assemblies and a retracted position. When the probe cleaning unit of the present invention is attached to the probe unit so that the probe cleaning unit can also be moved to the retracted position, the probe cleaning unit of the present invention may be moved to the retracted position when not in use. This is convenient because it does not hinder the inspection, and there is no risk of loss or the need for separate storage.

  This invention solves said subject by providing the panel inspection apparatus provided with the above probe cleaning units. When the panel inspection apparatus includes the probe cleaning unit of the present invention as described above, when the probe needs to be cleaned, the probe can be cleaned with a simple operation at any time.

  The present invention further includes a probe unit including one or a plurality of probe assemblies each having a plurality of probes, and the probe units are moved relative to the panel to be inspected so that the plurality of probes are inspected. A probe cleaning method in a panel inspection apparatus for inspecting a panel to be inspected by bringing it into contact with the electrodes of the probe, and a probe cleaning unit comprising a main body portion that supports a moving base to which the cleaning means is attached so as to reciprocate linearly. The probe unit of the panel inspection apparatus is attached so as to be movable at least between positions corresponding to each of the probe assemblies. When a probe that requires cleaning is generated, the probe assembly to which the probe is attached is attached to the probe unit. Move the probe cleaning unit to the corresponding position, and at that position, move the probe cleaning unit. By reciprocating the base to the probe tip, by providing a probe cleaning method in panel inspection apparatus for cleaning the probe tip is to solve the above problems.

  The probe cleaning unit and the probe cleaning method of the present invention are mainly suitably applied to a panel inspection apparatus that performs lighting inspection of a display panel such as a liquid crystal panel, but are not limited thereto. The probe cleaning unit and the probe cleaning method of the present invention include a probe unit including one or a plurality of probe assemblies each having a plurality of probes, and the plurality of probe units are moved relative to the inspection target panel. Any panel inspection apparatus may be used as long as it is in contact with the electrode of the inspection target panel and inspects the inspection target panel.

  According to the present invention, since the probe can be cleaned with a simple operation while the probe assembly is attached to the probe unit, the probe assembly can be removed from the probe unit for cleaning or after cleaning. There is no need to attach the panel inspection apparatus, and the panel inspection apparatus can be stopped for a minimum time when the probe is cleaned, and the display panel can be inspected efficiently. Further, according to the present invention, the probe that needs to be cleaned can be cleaned in units of the probe assembly to which the probe is attached, so even a clean probe that does not need to be cleaned can be cleaned. That can be minimized and polished for cleaning.

It is a front view which shows an example of the panel inspection apparatus with which the probe cleaning unit of this invention is attached. It is a front view which shows an example of the probe cleaning unit of this invention. It is a figure which shows the state which attached the probe cleaning unit to the probe assembly. It is a figure which shows the state which moved the probe cleaning unit to the 1st cleaning position. It is a figure which shows the state which is adjusting the distance of a main-body part and an arm part in a 1st cleaning position. It is a figure which shows the grinding | polishing state of the probe front-end | tip by a grinding | polishing body. It is a figure which shows the state which moved the probe cleaning unit to the 2nd cleaning position. It is a figure which shows the cleaning state of the probe front-end | tip with a cleaning brush. It is a figure which shows the state which moved the probe cleaning unit to the retracted position. It is a front view which shows another example of the probe cleaning unit of this invention. It is a top view of FIG. It is a figure which shows another example of the probe cleaning unit of this invention. It is a partial expanded partial sectional view of FIG. It is X-X 'sectional drawing of FIG. It is a figure which shows the state in which the rotation range of the cleaning body support part is restrict | limited. It is a figure which shows the state in which the rotation range of the cleaning body support part is restrict | limited. It is a figure which shows the example in which the up-and-down position of a rotation range restriction body is adjustable. It is a figure explaining the rocking | fluctuation operation | movement of a cleaning body support part. It is a figure explaining the rocking | fluctuation operation | movement of a cleaning body support part.

  Hereinafter, the present invention will be described in detail with reference to the drawings, but the present invention is not limited to the illustrated one.

  FIG. 1 is a front view showing an example of a panel inspection apparatus to which a probe cleaning unit of the present invention is attached. In FIG. 1, 1 is a panel inspection apparatus, 2 is its inspection unit, 3 is a loader unit, and 4 is a display panel that is a sample object. An example of the display panel 4 is a liquid crystal panel. However, the display panel 4 is not particularly limited as long as the display panel 4 is inspected by bringing a probe of a panel inspection apparatus into contact with the electrode. For example, an EL display panel or a plasma display panel may be used, and the thickness of the panel is not limited.

  5 is a probe unit, and 6 is a probe assembly. As shown in the figure, a plurality of probe assemblies 6 are attached to each of the probe units 5 and 5, and each probe assembly 6 includes a plurality of probes (not shown). 7 is an alignment camera, 8 is a monitor screen, 9 is a control device, and the control device 9 is used for various storage devices, arithmetic processing devices, and external devices for signals and data required for the normal panel inspection device 1. An input / output interface for performing input / output and an input / output device are provided.

  The display panel 4 conveyed from the outside is taken into the loader unit 3 by a mechanical hand, set on a set stage movable in the XYZθ directions, and conveyed to the inspection unit 2. The display panel 4 transported to the inspection unit 2 uses a plurality of alignment cameras 7 provided on the display panel 4 and the set stage, and a plurality of display panels 4 are provided in the electrodes and the probe assemblies 6. The alignment is performed so that the probe is in a predetermined positional relationship. Next, the display panel 4 is moved toward the probe assembly 6 by the set stage, the plurality of probes of the probe assembly 6 come into contact with the electrodes of the display panel 4, and the lighting inspection of the display panel 4 is performed.

  The probe cleaning unit of the present invention is used by being attached to the probe unit 5 of the panel inspection apparatus 1, in particular, the probe assembly 6, and by contacting the electrode of the display panel 4, It is possible to always keep the electrical continuity between the probe and the electrode in a good state by removing dirt, foreign matter, etc. adhering to the vicinity periodically or as needed.

  FIG. 2 is a front view showing an example of the probe cleaning unit of the present invention, and is shown as a partial sectional view together with the probe assembly 6 to which the probe cleaning unit is attached. In FIG. 2, reference numeral 10 denotes a probe cleaning unit of the present invention, and the probe cleaning unit 10 includes an arm portion 11, a main body portion 12, and a moving base 13. Reference numeral 14 denotes a cleaning means switching portion attached to the arm portion 11, 15 denotes a switching lever, 15a denotes a rotating shaft, 15b denotes a moving shaft, and the switching lever 15 is connected to the cleaning means switching portion 14 via the rotating shaft 15a. Is supported rotatably.

  Reference numeral 16 denotes a positioning shaft. The lower end of the positioning shaft 16 is connected to the main body portion 12 via a fine adjustment screw 17, and the upper end passes through the arm portion 11 and moves the switching lever 15 via the connecting shaft 18. It is connected to the shaft 15b. Reference numeral 19 denotes a guide shaft, and 20 denotes a fall prevention pin. The main body 12 is supported by the positioning shaft 16 and the guide shaft 19 so as to be movable in the vertical direction in the figure with respect to the arm 11.

  The moving base 13 has a bearing portion 13a, and a slide shaft 21 attached to the main body portion 12 is fitted inside the bearing portion 13a. 21 a and 21 b are stoppers attached to the slide shaft 21, 22 is a tension spring, and 23 is a slide grip attached to the moving base 13. When the operator applies a force to the moving base 13 via the slide grip 23, the moving base 13 can be reciprocated linearly between the stoppers 21a and 21b along the slide shaft 21. Instead of the operator reciprocating the moving base 13 manually, for example, a small air cylinder may be attached between the moving base 13 and the main body 12 and the moving base 13 may be reciprocated by air pressure. In this example, the movable base 13 is attached to the main body 12 so as to be reciprocally movable. However, in some cases, the movable base 13 is fixed to the main body 12 and the main body 12 is fixed to the arm 11. It may be attached so that it can reciprocate. In this case, however, the weight of the reciprocating portion increases, the cleaning efficiency is deteriorated, and the structure for attaching the main body 12 to the arm 11 becomes complicated. It is preferable to attach to the main-body part 12 so that reciprocation is possible.

  Reference numeral 24 denotes a first cleaning means, which is a polishing body in this example, but may be a cleaning brush which will be described later instead of the polishing body, or may be a cleaning means normally used for cleaning the probe tip. Anything is acceptable. The first cleaning means is detachably attached to the upper surface of the moving base 13 so that it can be replaced when it is consumed or damaged. When an abrasive body is used as the first cleaning means 24, any material can be used as the abrasive body as long as foreign substances such as metal debris attached to the tip of the probe described later can be polished and removed. For example, a polishing paper or a polishing sheet coated with or adhering a normal abrasive, or a ceramic plate or polished glass can be used.

  Reference numeral 25 denotes a cleaning body base, and the cleaning body base 25 is rotatably supported between a horizontal position and a vertical position in the drawing with respect to the moving base 13 via a rotation shaft 25a. It is desirable that a locking mechanism for temporarily locking the cleaning body base 25 with respect to the moving base 13 is provided between the cleaning body base 25 and the moving base 13 in the horizontal position and the vertical position in the drawing. Thereby, even when the moving base 13 reciprocates, the cleaning body base 25 is stably held by the moving base 13. Reference numeral 26 denotes a second cleaning means, which is a cleaning brush in this example, but may be an abrasive body instead of the cleaning brush, and any other cleaning means usually used for cleaning the probe tip. It may be something like this. The second cleaning means is detachably attached to the cleaning body base 25 so that it can be replaced when worn or damaged. When a cleaning brush is used as the second cleaning means 26, the cleaning brush may be made of any material as long as foreign matter such as dust adhering to the tip of the probe, which will be described later, or a flaw on the sealing material can be removed by brushing. For example, natural animal hair can be used.

  The arm part 11 includes an arm base 11 a, and the arm base 11 a and the arm part 11 are connected by a hinge 27. 28 is a knob screw for fixing the arm portion 11 to the arm base 11a, and 29 is a mounting screw for attaching the arm portion 11 to the probe assembly 6 via the arm base 11a. The arm portion 11 is provided with a through hole 11b through which the attachment screw 29 passes, and the arm base 11a is provided with an attachment hole 11c into which the attachment screw 29 is engaged. In the figure, although only one through hole 11b, one attachment hole 11c, and one attachment screw 29 are shown, the through hole 11b and the attachment hole 11c are spaced apart along the depth direction in the figure. Two arm portions 11 and two arm bases 11a are provided at positions corresponding to each other. Accordingly, there are also two mounting screws 29. Thus, since the arm portion 11 is attached to the probe assembly 6 by the two attachment screws 29, the probe cleaning unit 10 rotates around the attachment screw 29 when attached to the probe assembly 6. Nor.

  The probe assembly 6 normally includes a suspension base 6a, a suspension block 6b, a probe assembly base 6c, and a plurality of probes 6p attached to the probe assembly base 6c. It is attached to the base 5a of the unit 5. The probe assembly 6 is not different from a normal probe assembly except that a screw hole 6h into which the mounting screw 29 is inserted is provided on the upper surface of the suspension base 6a. If it is difficult to directly provide the screw hole 6h in the suspension base 6a, a separate attachment base having the screw hole 6h may be prepared and the attachment base may be attached to the suspension base 6a. Of course, two screw holes 6h are provided along the depth direction in the figure corresponding to the mounting holes 11c of the arm base 11a. Further, the screw hole 6h takes into account the length of the arm portion 11 and the position of the mounting hole 11c, and the first cleaning means 24 and the second cleaning means 26 are connected to the tip of the probe 6p when the moving base 13 reciprocates. Needless to say, it is provided at a position where it can come into contact.

  FIG. 3 shows a state in which the probe cleaning unit 10 is attached to the probe assembly 6. As shown in the figure, the probe cleaning unit 10 is attached to the probe assembly 6 by means of a mounting screw 29 and is positioned relative to the probe assembly 6 at the same time. In the state shown in the drawing, the switching lever 15 is in a counterclockwise position rotated counterclockwise, the main body portion 12 of the probe cleaning unit 10 is lowered with respect to the arm portion 11, and the moving base 13 is the second base. In the cleaning position.

  FIG. 4 shows a state in which the switching lever 15 is rotated clockwise from the state shown in FIG. 3 to raise the main body 12 with respect to the arm 11 as shown by an arrow in the figure, and the movable base 13 is moved to the first cleaning position. The moved state is shown. When the moving base 13 is in the first cleaning position and the moving base 13 is reciprocated linearly with respect to the main body 12, the first cleaning means 24 (abrasive body in this example) attached to the moving base 13 is obtained. The probe assembly 6 can be in contact with the tips of the plurality of probes 6p.

  However, in actuality, even in the first cleaning position, the first cleaning means 24 attached to the moving base 13 and the plurality of probes 6p attached to the probe assembly 6 are in the vertical positions in the figure. Since there may be a slight deviation, as shown in FIG. 5, when the fine adjustment screw 17 is rotated to move the main body 12 with respect to the arm 11 and the movable base 13 is reciprocated, The distance between the arm portion 11 and the moving base 13 is adjusted so that the first cleaning means 24 attached to the moving base 13 contacts the tips of the plurality of probes 6p of the probe assembly 6. That is, the fine adjustment screw 17 constitutes a distance adjustment mechanism that adjusts the distance between the arm portion 11 and the moving base 13. When the moving base 13 is reciprocated linearly with respect to the main body 12, the first cleaning means 24 attached to the moving base 13 comes into contact with the tips of the plurality of probes 6 p of the probe assembly 6. Whether the position is in the position is, for example, whether the tip portion of the probe 6p and the surface of the first cleaning means 24 are observed with a microscope equipped in the panel inspection apparatus 1, and the focus positions are the same. Judgment can be made by examining whether or not.

  The fine adjustment screw 17 is, for example, a screw member having a lower end rotatably coupled to the main body portion 12 and having a male screw or a female screw that engages with a female screw or a male screw formed on the positioning shaft 16 above. Can be configured. Alternatively, instead of the fine adjustment screw 17, for example, a distance adjustment mechanism may be configured by a rack and a pinion mechanism, and the pinion may be rotated to move the main body portion 12 up and down with respect to the arm portion 11 by a minute distance. . Thus, the distance adjusting mechanism that adjusts the distance between the arm portion 11 and the moving base 13 only needs to be able to adjust the distance between them, and there is no particular limitation on the mechanism.

  When the adjustment of the distance between the arm portion 11 and the moving base 13 is completed by the fine adjustment screw 17, the moving base 13 reciprocates linearly with respect to the main body portion 12 via the slide grip 23 as shown in FIG. Let As the moving base 13 reciprocates, the first cleaning means 24 attached to the moving base 13 comes into contact with the tip of the probe 6p. In this example, since the first cleaning means 24 is an abrasive body, the abrasive body polishes the tip of the probe 6p as the moving base 13 reciprocates, and adheres to metal scraps such as aluminum, sealing The tip of the probe 6p is cleaned by removing the scissors and other foreign matters. As described above, the moving base 13 may be reciprocated using an actuator such as an air cylinder (not shown).

  7, from the state shown in FIG. 5, the switching lever 15 is rotated counterclockwise to lower the main body 12 with respect to the arm 11, and the moving base 13 is moved from the first cleaning position to the second cleaning position. It shows the state moved. At this position, as shown by the arrow in the figure, the cleaning body base 25 attached to the movable base 13 is rotated around the rotation shaft 25a and brought into a vertical state in the figure to be attached to the cleaning body base 25. The second cleaning means 26 (cleaning brush in this example) contacts the tip of the probe 6p when the moving base 13 is reciprocated linearly with respect to the main body 12. be able to. If the tip of the second cleaning means 26 does not come into contact with the tip of the probe 6p or the contact is too deep, the fine adjustment screw 17 is rotated in the same manner as in the first cleaning position. What is necessary is just to adjust the distance of 12 and the arm part 11. FIG.

  After the adjustment of the distance between the arm portion 11 and the moving base 13 by the fine adjustment screw 17 is performed as necessary, the moving base 13 is moved with respect to the main body portion 12 via the slide grip 23 as shown in FIG. Reciprocate linearly. As the moving base 13 reciprocates, the second cleaning means 26 attached to the cleaning body base 25 comes into contact with the tip of the probe 6p. In this example, since the second cleaning means 26 is a cleaning brush, the cleaning brush comes into contact with the tip of the probe 6p with the reciprocating movement of the moving base 13, and the adhered sealing material flaw, dust, Other foreign matters are removed and the tip of the probe 6p is cleaned.

  As described above, when the cleaning of the plurality of probes 6p provided in one probe assembly 6 is completed, and there is another probe assembly 6 ′ that requires the cleaning of the probe, the probe cleaning unit The two mounting screws 29 fixing the 10 to the current probe assembly 6 are loosened to unscrew the suspension base 6a, and the probe cleaning unit 10 is moved to a position corresponding to the other probe assembly 6 ′. And move it. At that position, the probe cleaning unit 10 is attached to the probe suspension base 6a of the new probe assembly 6 ′ by means of a mounting screw 29, and the probe 6p by the first cleaning means 24 and / or the second cleaning means 26 as described above. Cleaning is performed. In this way, the probe cleaning unit 10 of the present invention can be sequentially moved between positions corresponding to the probe assembly that requires cleaning, and is attached to the probe assembly at each position to clean the probe. Is done.

  FIG. 9 shows a state where the probe cleaning unit 10 is moved to the retracted position. That is, by removing the knob screw 28 from the state shown in FIG. 3 and rotating the arm portion 11 around the hinge 27, the probe cleaning unit 10, that is, the arm portion 11, the main body portion 12, and the moving base 13 is rotated. Can be moved to a retracted position behind the probe assembly 6. Since the probe cleaning unit 10 is located on the opposite side of the probe 6p at the retracted position, it does not hinder the inspection of the display panel 4. The probe cleaning unit 10 may be removed from the probe assembly 6 after the cleaning of the probe 6p is completed. However, if the probe cleaning unit 10 is removed, a separate storage place is required, and it is attached to the probe assembly 6 again during cleaning. Therefore, it is preferable to move to the retreat position when not in use, as in this example. The knob screw 28 may be once removed and then attached to the arm base 11a again.

  The retracted position of the probe cleaning unit 10 is not limited to the rear of the probe assembly 6 shown in FIG. For example, a dummy assembly in which a screw hole 6h is formed in the base 5a of the probe unit 5 similarly to the probe assembly 6, and the probe cleaning unit 10 that has been cleaned is used as the dummy assembly with the dummy assembly as a retracted position. You may make it attach to a solid. The place where such a dummy assembly is provided is not limited to the base 5a of the probe unit 5, but may be provided at an appropriate place of the panel inspection apparatus 1.

  FIG. 10 is a front view showing another example of the probe cleaning unit 10 of the present invention, and shows a state where it is attached to the probe assembly 6. In the example shown in FIG. 10, the arm base 11 a is not provided, and the arm portion 11 extends to the rear of the probe assembly 6 and is attached to the linear guide 31 via the guide block 30. As shown in the figure, the linear guide 31 is attached to the base 5 a of the probe unit 5. Reference numeral 32 denotes a fixing screw for the guide block 30. The guide block 30 and the linear guide 31 constitute a guide mechanism. Further, in this example, the knob screw 28 does not fix the arm portion 11 to the arm base 11a, but fixes the arm portion 11 to the suspension base 6a of the probe assembly 6 and the probe cleaning unit 10 to the probe assembly 6. Positioning with respect to. In FIG. 10, the knob screw 28 is directly attached to the suspension base 6a through the arm portion 11. However, if it is difficult to form a screw hole in the suspension base 6a, a screw hole is separately provided. It is also possible to attach the attachment base formed with the suspension base 6a to the suspension base 6a and attach the knob screw 28 to the attachment base through the arm portion 11.

  To move the probe cleaning unit 10 to a position corresponding to the other probe assembly 6 ′, the knob screw 28 is removed, the fixing screw 32 is loosened, and the probe cleaning unit 10 is moved along the linear guide 31 as shown in FIG. It may be moved linearly in the depth direction. The probe cleaning unit 10 that has been moved to a position corresponding to another probe assembly 6 ′ that requires cleaning of the probe 6p, attaches the knob screw 28 to the suspension base 6a through the arm portion 11 at that position. The probe assembly 6 'is positioned and fixed, and at the same time, the fixing screw 32 is tightened to fix the probe assembly 6'.

  FIG. 11 is a plan view of FIG. 10, in which the main body 12 and the cleaning means switching unit 14 are omitted. As shown in the figure, the linear guide 31 is arranged linearly along the plurality of probe assemblies 6. Thus, the probe cleaning unit 10 is attached to the base 5a of the probe unit 5 so as to be movable between positions corresponding to the plurality of probe assemblies 6, and there is a probe assembly 6 that needs to be cleaned. If necessary, the probe assembly 6 can be moved to a position corresponding to the probe assembly 6 to clean the plurality of probes 6p provided in the probe assembly 6.

  Reference numeral 33 denotes a dummy assembly which is a retracted position of the probe cleaning unit 10. That is, when not in use, the probe cleaning unit 10 can be moved to the retracted position corresponding to the dummy assembly 33 and fixed at that position. Of course, even if the probe cleaning unit 10 is fixed at this position, the retracted position is selected so as not to interfere with the inspection of the display panel 4 by the panel inspection apparatus 1.

  In the example described above, a polishing body is used as the first cleaning unit 24 and a cleaning brush is used as the second cleaning unit 26. However, the second cleaning unit uses a cleaning brush as the first cleaning unit 24. A polishing body may be used as the means 26, or both the first cleaning means and the second cleaning means may be used as polishing bodies, or both may be used as cleaning brushes, and one may be used as a backup for the other. Both the first cleaning means and the second cleaning means may be used as abrasives, and the roughness may be different, or both may be used as cleaning brushes, and the softness of the hair may be changed. . Furthermore, cleaning means other than the polishing body and the cleaning brush may be used as the first cleaning means or the second cleaning means.

  12 is a view showing another example of the probe cleaning unit of the present invention, and FIG. 13 is a partially enlarged partial sectional view of FIG. The same members as those in the example described above are denoted by the same reference numerals. 12 and 13, reference numeral 13 a denotes a movable body base main body, and reference numeral 13 b denotes a cleaning body support portion, which constitutes the movable base 13. The moving base main body 13a is supported by the slide shaft 21 so as to be able to reciprocate linearly with respect to the main body portion 12 in the same manner as the moving base 13 described above. By applying a force to the movable base body 13, the movable base body 13 a can be linearly reciprocated between the stoppers 21 a and 21 b along the slide shaft 21. Instead of the operator manually reciprocating the moving base body 13a, for example, a small air cylinder may be attached between the moving base body 13a and the body part 12, and the moving base body 13a may be reciprocated by air pressure. The good thing is the same as in the example described above.

  Reference numeral 34 denotes a mounting base fixed to the movable base body 13a, 35 denotes a mounting screw, 36 and 36 denote bearings, and 37 denotes a rotation range limiting body. The cleaning body support portion 13b is attached to the movable base main body 13a by the attachment screw 35 via the attachment base 34. The mounting base 34 is not necessarily required, and the cleaning body support portion 13b may be directly attached to the movable base body 13a with the mounting screw 35 without using the mounting base 34. Since the bearings 36 and 36 are disposed between the inner surface of the through hole through which the attachment screw 35 penetrates in the cleaning body support portion 13 b and the attachment screw 35, the cleaning body support portion 13 b is arranged around the attachment screw 35. It is free to rotate. However, since the rotation range of the cleaning body support portion 13b is limited by the rotation range limiting body 37 as will be described later, the cleaning body support portion 13b can swing around the mounting screw 35 within a certain angle range. It is only. The axis of the mounting screw 35, that is, the axis of oscillation of the cleaning body support portion 13b is parallel to the slide shaft 21, which is the axis on which the movable base body 13a reciprocates linearly.

  FIG. 14 is a cross-sectional view taken along the line X-X ′ in FIG. 13. As shown in the figure, a gap w is provided between the upper surface of the cleaning body support portion 13b and the lower surface of the rotation range limiting body 37, and the cleaning body support portion 13b is mounted within a range allowed by the gap w. The screw 35 is rotatable about the axis of the screw 35, that is, about the swing axis. That is, as shown in FIG. 15, when the cleaning body support portion 13 b rotates around the mounting screw 35 in the clockwise direction indicated by the arrow in the drawing, for example, by an angle α, the upper surface of the cleaning body support portion 13 b becomes the rotation range limiting body. The lower surface of 37 is in contact with the point t1 (actually a line having a length in a direction perpendicular to the paper surface), and further rotation of the cleaning body support portion 13b is prevented. Similarly, as shown in FIG. 16, when the cleaning body support portion 13 b rotates around the mounting screw 35 in the counterclockwise direction indicated by the arrow in the drawing by an angle α, the upper surface of the cleaning body support portion 13 b becomes restricted in the rotation range. The lower surface of the body 37 abuts on the point t2 (actually a line having a length in a direction perpendicular to the paper surface), and further rotation of the cleaning body support portion 13b is prevented.

  Thus, by providing the rotation range limiting body 37 having the lower surface opposite to the upper surface of the cleaning body support portion 13b, the range of rotation around the mounting screw 35 of the cleaning body support portion 13b is limited, and cleaning is performed. The body support portion 13b is supported so as to be swingable around the axis of the mounting screw 35, that is, around the swinging shaft, in the range of -α to + α around the horizontal. The swinging range of the cleaning body support portion 13b, that is, −α to + α is usually sufficient to be −5 degrees to +5 degrees, and may be about −3 degrees to +3 degrees.

  The size of the angle α can be adjusted by adjusting the gap w between the upper surface of the cleaning body support portion 13b and the lower surface of the rotation range limiting body 37. For example, FIG. 17 is a cross-sectional view showing only a part of the moving base body 13a. As shown in FIG. 17, the rotation range restricting body 37 can be moved in the vertical direction with respect to the moving base body 13a. The gap w may be adjusted by rotating the attachment and fine adjustment screw 38. Alternatively, instead of allowing the rotation range limiting body 37 to be movable, the cleaning body support portion 13b may be movable in the vertical direction with respect to the moving base body 13a. In addition, an insertion plate having an appropriate thickness may be attached to and detached from the upper surface of the cleaning body support portion 13b and / or the lower surface of the rotation range limiter 37 to adjust the size of the gap w.

  The rotation range restricting body 37 may have any shape and structure that can restrict the rotation range of the cleaning body support portion 13b, and is limited to the one having a lower surface facing the upper surface of the cleaning body support portion 13b. Absent. For example, it may be a rotation range restricting body having an upper surface facing the lower surface of the cleaning body support portion 13b, or when the cleaning body support portion 13b rotates around the mounting screw 35 by a certain angle or more. It may be in contact with the side surface of 13b or a part of the cleaning body support portion 13b to prevent its rotation.

  When the center of gravity of the cleaning body support portion 13b is made lower than the axis of the mounting screw 35 by changing the shape or material of the cleaning body support portion 13b or attaching a weight, the cleaning body support portion 13b itself returns to the horizontal position even if it swings around the axis of the mounting screw 35, so that the rotation range restricting body 37 may not be provided.

  FIG. 18 is a diagram illustrating the swinging operation of the cleaning body support portion 13b. That is, FIG. 18A shows a case where the tip portions of the plurality of probes 6p and the first cleaning unit 24 are in a parallel state. In such a case, with the first cleaning means 24 positioned below the probe row, the switching lever 15 (not shown) is rotated or the fine adjustment screw 17 is rotated to clean the movable base body 13a. When the body support portion 13b is raised with respect to the probe 6p as shown in FIG. 18 (1) (a), the cleaning body support portion 13b rises as it is, and as shown in FIG. 18 (1) (b), The 1st cleaning means 24 (for example, grinding | polishing body) attached to the cleaning body support part 13b contacts with the front-end | tip part of the probe row | line | column which consists of several probe 6p. In this state, when the movable base body 13a is reciprocated linearly along the slide shaft 21 via the slide grip 23 (not shown), the polishing body, for example, the first cleaning means 24 contacts the tip of the probe 6p. Then, the tip of the probe 6p is polished to remove foreign matter such as attached metal debris, and the probe 6p is cleaned.

  FIG. 18 (2) shows a case where the tip of the probe row composed of a plurality of probes 6 p is inclined relative to the first cleaning means 24 by an angle β. Even in such a case, with the first cleaning means 24 positioned below the probe row, the switching lever 15 is rotated or the fine adjustment screw 17 is rotated so that the cleaning body support portion 13b is As shown in FIGS. 18 (2) (a), when the probe 6p is raised, the first cleaning means 24 attached to the cleaning body support portion 13b first has a tip of the probe 6p in the vicinity of the right end in the figure. Although the cleaning body support portion 13b can swing around the axis (swinging shaft) of the mounting screw 35, it naturally rotates and has an inclination that follows the inclination β of the probe array, as shown in FIG. (2) As shown in (b), the entirety of the first cleaning means 24 is in uniform contact with the tip of the probe row composed of the plurality of probes 6p.

  In this state, when the movable base body 13a is reciprocated linearly along the slide shaft 21, the polishing body, for example, the first cleaning means 24 moves while being in contact with the tip of the probe 6p. The tip is polished to remove foreign matters such as attached metal scraps, and the probe 6p is cleaned. As described above, since the cleaning body support portion 13b can swing around the swing shaft, the first end of the probe row is inclined even when it is relatively inclined with respect to the first cleaning means 24. The tip portions of all the probes 6p constituting the probe row can be evenly polished and cleaned without the one cleaning means 24 hitting the tip portion of the probe row. The same applies when the tip of the probe row is inclined in the direction opposite to that shown in FIG.

  FIG. 19 is a diagram illustrating the swinging operation of the cleaning body support portion 13b when the second cleaning means 26 is used instead of the first cleaning means 24. That is, FIG. 19A shows a case where the tip portions of the plurality of probes 6p and the second cleaning means 26 are in a parallel state. In such a case, the fine adjustment screw 17 (not shown) is rotated in a state where the second cleaning means 26 is positioned below the probe row, so that the cleaning body support portion 13b is moved together with the moving base body 13a as shown in FIG. (1) When the probe 6p is raised as shown in (a), the cleaning body support portion 13b rises as it is and is attached to the cleaning body base 25 as shown in FIG. The 2nd cleaning means 26 (for example, cleaning brush) which contacts is in contact with the front-end | tip part of the probe row | line which consists of several probe 6p. In this state, when the movable base body 13a is reciprocated linearly along the slide shaft 21 via the slide grip 23 (not shown), the cleaning brush, for example, the second cleaning means 24 contacts the tip of the probe 6p. The probe 6p is cleaned by removing dust attached to the tip of the probe 6p, sealing agent wrinkles, and the like.

  FIG. 19 (2) shows a case where the tip of the probe row composed of the plurality of probes 6 p is inclined relative to the second cleaning means 26 by an angle γ. Even in such a case, the fine adjustment screw 17 is rotated in a state where the second cleaning means 26 is positioned below the probe row, so that the cleaning body support portion 13b is moved to the position shown in FIGS. When the probe 6p is raised as shown in FIG. 2, the second cleaning means 26 attached to the cleaning body base 25 first comes into contact with the tip of the probe 6p in the vicinity of the left end in the figure. Since the portion 13b is swingable about the axis (swing shaft) of the mounting screw 35, it naturally rotates and has an inclination that follows the inclination γ of the probe array, as shown in FIGS. 19 (2) and 19 (b). In addition, the entire second cleaning means 26 is in uniform contact with the tip of the probe row composed of the plurality of probes 6p.

  In this state, when the movable base body 13a is reciprocated linearly along the slide shaft 21, for example, the cleaning brush as the second cleaning means 26 moves while contacting the tip of the probe 6p, and the probe 6p The probe 6p is cleaned by removing dust adhering to the tip of the nozzle or the sealant wrinkles. As described above, since the cleaning body support portion 13b is swingable about the swing shaft, even when the distal end portion of the probe row is inclined relative to the second cleaning means 26, the first (2) The tip portions of all the probes 6p constituting the probe row can be evenly cleaned without the cleaning means 26 hitting the tip portions of the probe row. The same applies when the tip of the probe row is inclined in the direction opposite to that shown in FIG.

  As described above, the probe cleaning unit of the present invention is used by being attached to a panel inspection apparatus, and the probe can be cleaned in units of the probe assembly while the probe assembly is attached to the probe unit. Since the panel inspection apparatus provided with the probe cleaning unit of the present invention can easily clean the probe in units of probe assemblies, the probe is always brought into contact with the electrode of the display panel in a good state. It is possible to perform the inspection. Moreover, if the probe cleaning unit of the present invention is used, the probe cleaning unit of the present invention is attached to the probe unit of the panel inspection apparatus so as to be movable between positions corresponding to the probe assemblies, and cleaning is required. The probe cleaning unit of the present invention is moved to a position corresponding to the probe assembly to which the probe is attached, and the moving base is reciprocated with respect to the probe tip at that position. The tip of the probe can be cleaned.

  As described above, according to the present invention, since the probe can be cleaned with a simple operation while the probe assembly is still attached to the probe unit, the stop time of the panel inspection apparatus accompanying the cleaning of the probe Can be minimized, and the display panel can be inspected efficiently. In addition, according to the present invention, the probe that needs to be cleaned can be cleaned in units of the probe assembly to which the probe is attached. Therefore, even a clean probe that does not require cleaning is polished. It is possible to minimize the possibility of being done. Therefore, the present invention has great industrial applicability in the industrial field related to the manufacture of various display panels including liquid crystal panels.

DESCRIPTION OF SYMBOLS 1 Panel inspection apparatus 2 Inspection part 3 Loader part 4 Display panel 5 Probe unit 6 Probe assembly 7 Alignment camera 8 Monitor screen 9 Control apparatus 10 Probe cleaning unit 11 Arm part 12 Main body part 13 Moving base 13a Moving base main body 13b Cleaning body support Part 14 Cleaning means switching part 15 Switching lever 16 Positioning shaft 17 Fine adjustment screw 18 Connection shaft 19 Guide shaft 20 Fall prevention pin 21 Slide shaft 22 Tension spring 23 Slide grip 24 First cleaning means 25 Cleaning body base 26 Second cleaning means 27 Hinge 28 Knob screw 29 Mounting screw 30 Guide block 31 Linear guide 32 Fixing screw 33 Dummy assembly 34 Mounting base 35 Mounting screw 36 Bearing 37 Rotation range limiter

Claims (12)

A probe unit including one or a plurality of probe assemblies each having a plurality of probes, and moving the probe unit relative to the inspection target panel to bring the plurality of probes into contact with the electrodes of the inspection target panel; A probe cleaning unit used in a panel inspection apparatus that inspects a panel to be inspected; the probe cleaning unit moves at least between positions corresponding to the probe assemblies with respect to the probe unit of the panel inspection apparatus An arm portion that can be attached; a main body portion attached to the arm portion; a moving base supported by the main body portion so as to reciprocate linearly; and the moving base linearly with respect to the main body portion. Means for reciprocating; and when the moving base is reciprocated linearly with respect to the main body, As the first cleaning means is mounted in contact with the tip of the probes of the probe assembly, the probe cleaning unit comprising a distance adjusting mechanism for adjusting the distance between the mobile base and the arm portion. The probe cleaning unit according to claim 1, wherein the first cleaning means is an abrasive body or a cleaning brush. A cleaning body base to which a second cleaning means is attached is attached to the moving base, and a first cleaning attached to the moving base when the moving base is reciprocated linearly with respect to the main body. A first cleaning position where the means can contact the tips of the plurality of probes of the probe assembly, and the second cleaning means attached to the cleaning body base contacts the tips of the plurality of probes of the probe assembly. The probe cleaning unit according to claim 1, further comprising a cleaning means switching mechanism that moves the moving base relative to the arm portion between the second cleaning position and the second cleaning position. The probe cleaning unit according to claim 3, wherein the second cleaning means is a cleaning brush or an abrasive. The second cleaning means attached to the cleaning body base when the cleaning body base is reciprocated linearly with respect to the main body at the second cleaning position with respect to the moving base. 5. The probe cleaning unit according to claim 3, wherein the probe cleaning unit is movably attached between a cleaning position in contact with tips of a plurality of probes of the probe assembly and a retracted position not in contact. The moving base includes a moving base main body and a cleaning body support portion, the moving base main body is supported so as to linearly reciprocate with respect to the main body portion, and the cleaning body support portion is supported with respect to the moving base main body. The probe cleaning unit according to claim 1, wherein the probe cleaning unit is supported so as to be swingable about a swing shaft parallel to a reciprocating shaft of the movable base body. The probe cleaning unit according to claim 6, wherein the cleaning body base is attached to the cleaning body support. The arm portion is detachably attached to each of the probe assemblies, and is attached to the probe unit of the panel inspection apparatus so as to be movable at least between positions corresponding to the probe assemblies. The probe cleaning unit according to any one of 1 to 7. The arm unit is attached to the probe unit via a guide mechanism that linearly guides the movement of the arm unit along the probe assembly, so that at least the probe assembly with respect to the probe unit of the panel inspection apparatus. The probe cleaning unit according to any one of claims 1 to 7, wherein the probe cleaning unit is movably attached between positions corresponding to each of the probe cleaning units. The probe cleaning unit according to any one of claims 1 to 9, wherein the arm portion is movably attached between a position corresponding to each of the probe assemblies and a position between the arm portion and a retracted position. . The panel inspection apparatus provided with the probe cleaning unit in any one of Claims 1-10. A probe unit including one or a plurality of probe assemblies each having a plurality of probes, and moving the probe unit relative to the inspection target panel to bring the plurality of probes into contact with the electrodes of the inspection target panel; A probe cleaning method in a panel inspection apparatus for inspecting a panel to be inspected, wherein a probe cleaning unit including a main body part that supports a moving base to which a cleaning means is attached is reciprocally moved linearly. When a probe is attached to the unit so that it can be moved at least between positions corresponding to each of the probe assemblies and needs to be cleaned, the probe is moved to a position corresponding to the probe assembly to which the probe is attached. The probe cleaning unit is moved, and at that position, the moving base is probed. By reciprocating relative to the end, the probe cleaning method in panel inspection apparatus for cleaning the probe tip.

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