JP3774403B2 - Element transfer sorting device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an apparatus for inspecting chips supplied to a supply position while being conveyed by a conveying means, and separating and storing them in a storage unit according to the inspection result.
[0002]
[Prior art]
Conventionally, chip quality inspection is performed by an inspection device provided in the vicinity of a chip conveyance path while conveying chips such as chip component type LEDs, which are elements, and sorting is performed according to inspection results. Yes. As an apparatus used for such a sorting operation, a conveyance sorting apparatus shown in FIG. 7 can be exemplified.
[0003]
The conveying and separating apparatus conveys the chips t continuously supplied in a state of being arranged on the linear conveying path 6 to below the suction holding disk 71 that rotates intermittently in the direction of arrow YD in FIG. Suction nozzles 711 are provided on the peripheral edge of the suction holding disk 71 at predetermined intervals, and the chips supplied to the lower part of the suction holding disk 71 are sucked and held one by one by the suction nozzle 711 from above the transport path 6. It is picked up and transported, and supplied to a transfer transport disc 72 that rotates intermittently in the direction of arrow YE in FIG.
[0004]
On the peripheral edge of the transfer conveyance disk 72, there are provided clamping parts 722 for holding the chip t at a predetermined interval, and the surface on which the LED of the chip t supplied to the transfer conveyance disk 72 is provided. It is nipped by the front end nail claw 722 </ b> A of the nipping portion 722 and conveyed so that the posture is directed to the outside of the transfer conveyance disk 72.
[0005]
An inspection device 73 for inspecting the quality of the chip t is provided outside the transfer transport disk 72. The chip t transported by the transport transport disk 72 is subjected to quality inspection by the inspection device 73. After being made, it is supplied to a separation disk 74 that rotates intermittently in the direction of arrow YF in FIG. The separation disk 74 is provided with holding holes 741 at the peripheral edge thereof at a predetermined interval, and when the chip t supplied to the separation disk 74 is conveyed to a position close to the upper side of the holding hole 741, a transfer conveyance disk. 72 is held by the front end clamping claws 722 </ b> A of the clamping unit 722, falls into the holding hole 741, and is conveyed by the separation disk 74.
[0006]
In this way, the chip t conveyed by the separation disk 74 is positioned above the collection hole 75 corresponding to the inspection result among the plurality of collection holes 75 provided below the conveyance path by the separation disk 74. The bottom surface of the recovery hole 75 is opened and falls into the recovery hole 75 from the holding hole 741. The chip t that has fallen into the collection hole 75 is collected in a storage unit (not shown) that communicates with the collection hole 75.
[0007]
Here, in this conventional transport sorting apparatus, as shown in FIGS. 8A and 8B, the chip t transported on the transport path 6 has its bottom surface (surface having a large area) facing downward. In the state of being placed on the transport path 6, the transport path 6 is moved toward the front end side of the transport path 6 by the vibration of the transport path 6. Then, the tip t moved to the lower side of the suction nozzle 711 of the suction holding disk 71 is sucked and held by the suction nozzle 711 descending from the upper side of the transport path 6 and taken up from the upper side of the transport path 6. It has become. In this case, as shown in FIGS. 8A and 8B, the chip t is formed so that both sides are thin and the both sides thin part t1 faces the front-rear direction. Move up.
[0008]
For this reason, as shown in FIGS. 8A and 8B, the chip t placed on the transport path 6 may be in a state where the thin portions t1 on both sides overlap each other as shown in FIGS. is there. In such a state, the subsequent chip t that has run on the thin part t1 of the target chip t to be sucked and held becomes an obstacle, and the target chip t is sucked and held by the suction nozzle 711 from above the chip t and conveyed. Cannot be picked up from the road 6. And such a situation is not limited to the chip t having a thin portion t1 on both sides as shown in FIGS. 8 (a) and 8 (b), and even a chip simply formed in a square plate shape, In the state in which the burrs generated at the time of manufacture protrude outward from both sides, there are cases where the subsequent chip t rides on the burrs of the target chip t and the suction holding by the suction nozzle 711 cannot be performed well.
[0009]
Further, in this chip transport sorting apparatus, chips having LEDs provided on the upper surface may be sorted. In such a case, in this chip transport sorting apparatus, the top surface of the chip t is inspected by the inspection device 73 during quality inspection. Need to turn to the side. However, in this chip transport sorting apparatus, since the upper surface of the chip t is sucked and held by the suction nozzle 711, the chip t held by the transfer transport disk 72 faces the upper surface outward of the transport transport disk 72. In order to be in a state, it is necessary to change the chip t before the quality inspection, and accordingly, the configuration of the apparatus becomes complicated, and the apparatus becomes large.
[0010]
Further, when the tip t sucked and held by the suction nozzle 711 is supplied between the tip clamping claws 722A of the clamping part 722 of the transfer conveyance disk 72, the suction by the suction nozzle 711 is released by blowing compressed air. However, there is a problem that the chip t is adhered to the outer peripheral edge portion of the suction nozzle 711 due to static electricity and the supply operation cannot be performed well.
[0011]
The storage section generally includes a plurality of storage containers for storing chips t and a main body section that stores each storage container so that it can be inserted and removed from its front end surface. The plurality of storage containers are removed from the main body section. Later, when returning to the main body, since the size of the chip t is small, there is a possibility that the storage container cannot be distinguished, and the storage container may be returned to a position different from the position where it should originally be stored.
[0012]
As described above, in the conventional chip transport sorting apparatus, the sorting work of elements such as chips cannot be performed well.
[0013]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an element transport separation apparatus that can perform element separation work well.
[0014]
[Means for Solving the Problems]
  To solve the above problems, the present invention.Pertaining toThe element transport separation deviceVibrating the conveying path on which the element is placed,ElementConcernedOn the transport pathWhile aligning the postureSupply means for moving and supplying, conveying means for sucking and holding the elements on the conveying path of the supplying means by holding means from above the conveying path, and inspection for inspecting the elements conveyed by the conveying means An apparatus, a suction release means for releasing the suction by the holding means, and a storage portion for separately storing the elements released by the suction means by the suction release means according to the inspection result by the inspection apparatus. An element transport sorting device comprising the supply means,The element is moved on the transport path by vibration.Supplying to a suction position for suction holding by the holding means,,in frontTransport in a state where the surface of the recording element is placed on the transport path with the surface being vertical.The holding means is configured to suck and hold a side surface orthogonal to a surface having a large area of the element.
[0015]
The element transport separation device moves an element on a transport path by a supply unit and supplies the element to a predetermined supply position. The element supplied to the supply position is sucked and held by a holding unit from above the transport path by a transport unit. After the elements are conveyed and inspected by the conveying means by the inspection device, the suction by the holding means is released by the suction releasing means, and sorted according to the inspection result and stored in the storage unit. The supply means vibrates the conveyance path on which the element is placed, moves the element on the conveyance path, and supplies the element to the suction position by the holding means.
[0016]
In this case, in the element transport separation apparatus, the supply unit is configured to transport the element in a state where the element is placed on the transport path with a surface having a large area of the element being vertical. For this reason, according to this element transport separation device, even if the thin portions on both sides of the elements placed on the transport path overlap each other due to the vibration of the transport path, the holding means sucks and holds the object. Since the upper part of the element is in an open state, when the element is sucked by the holding means descending from the upper part of the element and taken up from the transport path, the subsequent element that has been on the target element to be sucked and held The element can be accurately supplied to the holding means without obstructing the operation of picking up the target element. In addition, when sorting elements with LEDs on the top surface, it can be transported by the transport means with the top surface of the element open, so that it is possible to inspect the quality of the LEDs without changing the orientation of the elements, and for sorting work. This saves time and effort.
[0017]
In the element transport separation device, the frontThe suction release means includes: jetting means for injecting air to an element that has been transported by the transporting means and is located in the vicinity of the recovery port for recovering the element in the storage portion; and the element in the recovery port. Suction means for sucking into,It was set as the structure provided with.
[0018]
Similarly to the above-described element transport separation apparatus, this element transport separation apparatus inspects the element supplied by the supply means with the inspection apparatus while being transported by the transport means while being sucked and held by the holding means, and the suction release means. The suction by the holding means is released, sorted according to the inspection result, and stored in the storage section. The suction release means is transported by the transport means and is used for collecting elements in the storage section. The apparatus includes an ejection unit that ejects air to an element located in the vicinity of the recovery port, and a suction unit that sucks the element into the recovery port.
[0019]
For this reason, according to this element transport separation apparatus, the element that is transported by the transport means while being sucked and held by the holding means and is located in the vicinity of the recovery port for loading the element into the storage portion. On the other hand, by blowing air from the ejecting means and sucking the element into the collection port by the suction means, it is possible to prevent the element from adhering to the holding means and the collection port due to static electricity, and to the element held by the holding means. Compared to the case where air is simply blown, the element can be accurately introduced from the collection port into the storage portion, and the element can be efficiently collected and separated.
[0020]
In the element transport separation device, the frontThe storage section includes a plurality of storage containers for storing elements, and a main body section for storing each storage container so that the storage containers can be inserted and removed from the front end face thereof, and a front end face of the main body section and a front end face of the storage container The engaging portions formed so as to be engageable with each other are provided at different positions on the front end surface of each storage container so as to have a column engaging portion indicating a column and a row engaging portion indicating a row.The configuration.
[0021]
Similarly to the above-described element transport separation apparatus, this element transport separation apparatus inspects the element supplied by the supply means with the inspection apparatus while being transported by the transport means while being sucked and held by the holding means, and the suction release means. The suction by the holding means is released, sorted according to the inspection result, and stored in the storage unit. The storage unit is capable of storing a plurality of storage containers for storing elements and the storage containers from the front end surface thereof. A front end surface of the main body portion and a front end surface of the storage container, and engaging portions formed to be engageable with each other at different positions on the front end surface of each storage container. It has the structure provided so that it may have the column engaging part which shows a column, and the row engaging part which shows a row.
[0022]
According to this element transport separation device, the engaging portions formed to be engageable with each other on the front end surface of the main body portion and the front end surface of the storage container constituting the storage portion for storing the elements are provided in each storage container. Since the column engaging portion indicating the column and the row engaging portion indicating the row are provided at different positions on the front end surface, the storage container is to be stored at a position different from the original storage position of the main body. In this case, the engaging portion comes into contact with the storage container and the main body, and the entry of the storage container into the main body is restricted. For this reason, even when it takes out a some storage container from a main-body part, and accommodates in a main-body part, it can prevent a mistake in putting a storage container.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a chip conveyance sorting device according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic view of a chip transport sorting apparatus according to an embodiment of the present invention.
[0024]
The chip transport separation apparatus performs inspection of the electrical characteristics of the chip t while transporting the chip t such as a chip component type LED as an element, and separates and collects according to the inspection result, as shown in FIG. As described above, a transport unit 1 that transports the chip t and a supply unit 2 that supplies the chip t to the transport unit 1 are provided on the upper surface of the base A. A storage unit 5 for separating and storing the transferred chips t is provided.
[0025]
The supply unit 2 is for supplying randomly supplied chips t in a predetermined posture in a line and supplying the chips to the transport unit 1, and temporarily stores and stores the chips t as shown in FIG. The bowl portion 21 for aligning the chips t in a predetermined posture and the supply position for sucking and holding the tips t supplied from the bowl portion 21 by the suction nozzle 12 (see FIG. 4) of the transport section 1 are aligned in a line. And a vibration mechanism (not shown) for vibrating the bowl portion 21 and the straight portion 22 along the upper surface of the base A and along the circumferential direction of the bowl portion 21.
[0026]
The bowl portion 21 is composed of a bottomed cylindrical body formed in a shape in which a substantially circular bottom surface 21A gently descends and slopes from the central portion to the peripheral portion, from the lower edge portion to the upper edge portion of the inner peripheral wall 21B, A spiral stepped portion is provided along the circumferential direction of the inner peripheral wall 21 </ b> B, and the upper surface of the stepped portion serves as a supply passage 211 for aligning the chips t in a predetermined posture and supplying them to the linear portion 22. Yes. The bowl portion 21 is provided with a distribution restriction portion 212 for supplying only the chip t in a predetermined posture to the straight portion 22 and a posture arrangement portion (not shown).
[0027]
The distribution regulating unit 212 is formed by narrowing the width of the supply passage 211, and the chips t placed in a state of being arranged in a plurality on the supply passage 211 are dropped from the supply passage 211, thereby The chips t are arranged in a line. The distribution regulating portion 212 provided on the most downstream side of the supply passage 211 is configured by forming the supply passage 211 slightly wider than the height of the side surface of the chip t, and the upper surface or the lower surface is on the supply passage 211. The mounted chip t drops off from the supply passage 211 in the distribution regulating unit 212. In addition, the posture organizing unit detects the posture of the tip t with a posture detector (not shown) provided in the vicinity of the supply passage 211, and places the upper surface on the supply passage 211 in a state where the upper surface faces the inner peripheral wall 21 </ b> B of the bowl portion 21. Compressed air is jetted from a jet port (not shown) to the chip t placed and dropped from the supply passage 211.
[0028]
The straight portion 22 has a base end portion 22A connected to the upper end portion of the bowl portion 21, and is formed so as to be gently inclined downward from the base end portion 22A side to the tip end portion 22B side. As shown in a cross section in FIG. 3, the straight portion 22 is provided with a transport passage 221 for moving the chip t therein. A stopper 222 for stopping the movement of the chip t that has been transported to the front end of the transport path 221 is attached to the front end of the linear portion 22 so as to cover the front end of the transport path 221. The straight portion 22 has an open top surface at the tip 22B, the conveyance passage 221 is exposed to the outside, and the suction nozzle 12 provided on the conveyance rotation base 11 (FIG. 3) of the conveyance unit 1 to be described later is It can enter into the conveyance path 221 and serves as a component supply device for the suction nozzle 12.
[0029]
The conveyance path 221 is formed so that the width thereof is slightly wider than the thickness of the chip t, and the height is set to be slightly higher than the width of the chip t. The transport passage 221 has a base end portion 22A communicating with the upper end limit of the supply passage 211 of the bowl portion 21, and a distal end portion 22B of the suction nozzle 12 accompanying the rotation operation of the transport rotation base 11 of the transport portion 1 described later. It extends to the lower part of the movement path.
[0030]
The supply unit 2 composed of the bowl unit 21 and the straight line unit 22 vibrates the bowl unit 21 with a vibration mechanism (not shown), and the chip t supplied to the bowl unit 21 by this vibration is indicated by an arrow in FIG. As shown, the bottom surface 21A of the bowl portion 21 is moved from the central portion to the peripheral portion, and the supply passage 211 provided in the inner peripheral wall 21B of the bowl portion 21 is further moved from the lower edge portion to the upper edge of the inner peripheral wall 21B of the bowl portion 21. Move over the part. Then, in the flow regulating unit 212 and the posture arranging unit (not shown), only the chip t with the upper surface facing the center side of the bowl portion 21 and the side surface placed on the supply passage 211 is placed in the transport passage 221 of the linear portion 22. As shown in FIG. 3, the conveyance path 221 of the linear portion 22 is moved from the proximal end side to the distal end side and supplied to the component supply position at the distal end of the conveyance path 221.
[0031]
The transport unit 1 is for transporting the chip t supplied from the supply unit 2, and as shown in FIG. 4, a disk-shaped transport rotary base 11 and a suction nozzle 12 provided on the transport rotary base 11. And a drive mechanism (not shown) for intermittently rotating the conveyance rotation base 11 along the upper surface of the base A while moving it up and down relative to the upper surface of the base A, and a negative pressure supply (not shown) for performing suction by the suction nozzle 12 Source.
[0032]
The transport rotation base 11 is supported above the upper end surface of the base A so as to be movable up and down with respect to the upper end surface of the base A and to be rotatable along the upper end surface of the base A. By the non-driving mechanism, it moves up and down while intermittently rotating in the direction of the arrow YA in FIG. 4, and when it is positioned at the lower limit, the operation in the direction of the arrow YA is temporarily stopped.
[0033]
The suction nozzle 12 is for sucking and holding the chip t supplied from the supply unit 2, and is provided at a predetermined interval on the peripheral edge of the transport rotation base 11. The suction nozzle 12 is provided with a distal end projecting from the lower surface of the transport rotating base 11 to the lower side of the transport rotating base 11, and a base end projecting from the upper surface of the transport rotating base 11 to the upper side of the transport rotating base 11. The other end of the tube having one end connected to a negative pressure supply source (not shown) provided in the table A is connected, and the tip t can be sucked and held at the tip by the negative pressure of the negative pressure supply source (not shown). It is like that.
[0034]
The transport unit 1 configured as described above is moved up and down with respect to the upper surface of the base A by a drive mechanism (not shown) while the transport rotating base 11 is intermittently rotated along the upper surface of the base A in the direction of the arrow YA in FIG. The tip of the suction nozzle 12 descending from above the linear portion 22 is conveyed by the linear portion 22 as shown by the arrow YB in FIG. It enters the passage 221. Then, once the conveyance rotation base 11 is located at the lower limit and the operation is stopped, the suction nozzle 12 is located close to the top of the chip t located at the component supply position, and is caused by the negative pressure of a negative pressure supply source (not shown). The tip t is sucked and held by the suction nozzle 12. From this state, when the transport rotation base 11 resumes its operation, the suction nozzle 12 rises above the component supply position as shown by the arrow YC in FIG. 221 is picked up from above and conveyed in the direction of arrow YA in FIG.
[0035]
As shown in FIG. 1, an inspection device 3 for inspecting the electrical characteristics, luminous intensity, color tone, and the like of the chip t is conveyed below the conveyance rotation base 11 while being sucked and held by the suction nozzle 12. It is arranged so as to be located in the vicinity of the transport path of the chip t.
[0036]
Further, on the downstream side of the inspection apparatus 3 below the transport rotating base 11, as shown in FIG. 4, a collection unit 4 for recovering the chip t inspected by the inspection apparatus 3 is provided. 11 is provided along the movement path of the suction nozzle 12 accompanying the rotation of 11.
[0037]
  As shown in FIG. 5, the collection unit 4 is provided on the arcuate base 41 provided on the downstream side of the inspection apparatus 3 in the transfer path of the chip t by the transfer rotary base 11 and the arcuate base 41.Compressed air injection port42 and a chip recovery port 43.
[0038]
As shown in FIG. 4, the arcuate base body 41 is provided below the transport rotation base 11 along the movement path of the suction nozzle 12 accompanying the rotation operation of the transport rotation base 11. As shown in FIG. 5B, the arcuate base body 41 is formed in a substantially U-shaped cross section, and the tip of the suction nozzle 12 is the U-shaped portion when the transport rotation base 11 is positioned at the lower limit. It is configured to enter into 41A.
[0039]
The compressed air injection ports 42 are provided at predetermined intervals on the inner peripheral wall of the U-shaped portion 41A of the arcuate base 41, and compressed air supplied from an air supply source (not shown) when the suction nozzle 12 is positioned at the lower limit. Air is jetted into the U-shaped portion 41A, and the tip t sucked and held by the suction nozzle 12 is blown away toward the tip recovery port 43 side.
[0040]
The chip recovery port 43 is opened on the outer peripheral wall of the U-shaped portion 41A of the arc-shaped base 41 so as to face the compressed air injection port 42, and the U-shaped portion is caused by negative pressure from a negative pressure supply source (not shown). The inside of 41A is aspirated.
[0041]
In the collection unit 4 having such a configuration, the tip t sucked and held by the suction nozzle 12 is substantially U-shaped portion 41A of the arcuate base body 41 as shown in FIG. When the air enters and is positioned between the compressed air injection port 42 and the chip recovery port 43, the compressed air supplied from a compressed air supply source (not shown) is blown from the compressed air injection port 42 to the chip t and is not shown. The suction is performed by the negative pressure of the pressure supply source into the chip recovery port 43, the suction by the suction nozzle 12 is released, and the chip t is inserted into the chip recovery port 43.
[0042]
  As shown in FIG. 6, the storage unit 5 includes two rows of an upper storage unit 51 and a lower storage unit 52 provided on one side surface of the lower part of the base A in the vertical direction, and is a main body unit.Upper storage51 andLower storageThe storage containers 512 and 522 for storing the chips t are accommodated in the upper and lower two rows of accommodation ports 511 and 521 that open along the width direction of 52. The storage containers 512 and 522 have a grip portion on the front surface thereof.512C, 522CThe gripping part512C, 522CCan be taken in and out of the storage ports 511 and 521.
[0043]
  In the upper edge portion of the storage port 511, a column engagement convex piece 511A is provided at a position corresponding to one side of the upper edge portion of the front end surface of each storage container 512 so as to protrude into the storage port 511. Yes. Also,Receiving portA column engagement convex piece 521A is provided at a position corresponding to the other side of the upper edge portion of the front end surface of each storage container 522 in the upper edge portion of 521 so as to protrude into the storage port 521.
[0044]
The storage ports 511 and 521 are provided with row engaging convex pieces 511B and 521B at intervals similar to the widths of the storage containers 512 and 522, respectively. The row engagement convex pieces 511B and 521B are provided so as to gradually become higher in the height direction of the storage ports 511 and 521 from one end side to the other end side of the storage ports 511 and 521.
[0045]
Housed in the upper housing part 51Storage containerReference numeral 512 denotes the column engagement convex pieces 511A, 521A and the row engagement convex pieces 511B, 521B at positions corresponding to the column engagement convex pieces 511A, 521A and the row engagement convex pieces 511B, 521B, respectively. Column engagement recesses 512A, 522A and row engagement recesses 512B, 522B are provided that can be combined.
[0046]
Next, the sorting operation of the chip t using this chip transport sorting apparatus will be described. When sorting the chip t using the chip transport sorting device, first, the chip t is randomly supplied to the bowl portion 21. The tip t supplied to the bowl portion 21 moves around the bottom of the bowl portion 21 while moving from the center side to the peripheral portion side of the bottom surface 21A of the bowl portion 21 due to the vibration of the bowl portion 21 as indicated by an arrow in FIG. Move along the direction. A part of the tip t that has moved to the peripheral edge of the bottom surface of the bowl portion 21 enters the supply passage 211 provided in the inner peripheral wall 21B of the bowl portion 21, and the supply passage 211 is moved as shown by an arrow in FIG. It moves toward the upper edge of the bowl part 21.
[0047]
The chip t moving on the supply passage 211 is dropped from the supply passage 211 in the distribution regulating portion 212 and arranged side by side in the width direction of the supply passage 211, and further provided on the most downstream side of the supply passage 211. In the flow regulating unit 212, the upper and lower surfaces and the front and rear surfaces placed on the supply passage 211 drop off from the supply passage 211, and the upper surface facing the peripheral edge side of the bowl portion 21 is not shown in the posture organizing unit. A transfer passage that is dropped from the supply passage 211 and communicates with the supply passage 211 only when the upper surface (surface having a large area) faces the central portion of the bowl portion 21 and the side surface is placed on the supply passage 211. Enter 221.
[0048]
As shown in FIG. 3, the chip t that has entered the conveyance path 221 is placed on the conveyance path 221 with one side surface (surface having a large area) in the width direction vertical, and the base end side of the conveyance path 221. A component supply position for moving on the transport path 221 from the base end side to the front end side of the transport path 221 by the vibration of the transport path 221 in a state of being aligned in a line from the leading end side to the leading end side, and sucking the chip t by the suction nozzle 12 When the leading end of the transport path 221 is reached, the stopper 222 stops the movement.
[0049]
Above the component supply position, the transport rotary base 11 moves up and down while intermittently rotating, and from above the transport path 221 as indicated by an arrow YB in FIG. The tip t that has been transported to the component supply position is sucked and held at the tip of the suction nozzle 12 that has been lowered. Then, the suction nozzle 12 that sucks and holds the chip t rises above the transport passage 221 as indicated by an arrow YC in FIG.
[0050]
In this case, as shown in FIG. 3, the thin portions t1 on both sides of the chip t placed on the transport path 221 may overlap with each other due to the vibration of the transport path 221, but in this case also, the chip t is transported in a state where the surface of the chip t having a large area is vertical and placed on the transport path 221, so that the subsequent chip t rides on the target chip t to be sucked and held by the suction nozzle 12. Therefore, the target chip t can be picked up accurately.
[0051]
The chip t sucked and held by the suction nozzle 12 in this way is directed so that the upper surface (surface having a large area) on which the LED is provided faces the outside of the transport rotary base 11 in accordance with the rotation operation of the transport rotary base 11. In this state, it is conveyed in the direction of arrow YA in FIG. The chip t transported by the transport rotating base 11 is in the state of being close to the inspection device 3 when the transport rotating base 11 is positioned at the lower limit and temporarily stops rotating and moving up and down. The electrical characteristics and the like are inspected, and the chip t is classified according to the inspection result. The chip t that has been inspected by the inspection apparatus 3 starts to move again in the direction of the arrow YA in FIG. 4 according to the operation of the transport rotating base 11 when the transport rotating base 11 resumes the rotating operation and the raising operation. And the chip | tip t conveyed by the conveyance rotation base | substrate 11 is conveyed by the collection | recovery part 4 provided in the downstream rather than the test | inspection apparatus 3 in the conveyance path | route.
[0052]
In this case, the chip t transported by the transport rotating base 11 is sucked on the side surface by the suction nozzle 12 and is positioned close to the inspection apparatus 3 with the upper surface of the chip t provided with the LED open. Therefore, it is not necessary to change the posture of the chip t at the time of inspection by the inspection apparatus 3, and the labor for the entire sorting operation can be saved.
[0053]
In the collection unit 4, the tip t sucked and held by the suction nozzle 12 is moved into the U-shaped portion 41 </ b> A of the arcuate base 41 by the rotation and vertical movement of the transport rotation base 11 as shown in FIG. 5B. It moves while repeating the state of intruding into the state and the state of retreating above the U-shaped portion 41A. Here, in a state in which the U-shaped portion 41A of the arcuate base body 41 has entered, the tip t sucked and held by the suction nozzle 12 is formed on the U-shaped portion 41A of the arcuate base body 41 as shown in FIG. It will be in the state located between the compressed air injection port 42 provided in the inner side inner wall, and the chip | tip collection port 43 provided in the outer side inner wall of U-shaped part 41A.
[0054]
  By repeating such an operation, the chip t conveyed to the chip recovery port 43 corresponding to the inspection result is blown with the compressed air injected from the compressed air injection port 42 and sucked into the chip recovery port 43 to recover the chip. It is introduced into the mouth 43. The chip t introduced into the chip collection port 43 moves in an introduction pipe (not shown), andEach storage container 512, 522It is thrown in. By repeating such an operation for each chip t, the sorting operation of the chip t is performed.
[0055]
  in this wayChip collection portWhen the compressed air is blown from the compressed air injection port 42 to the tip t located near the tip 43 and the inside of the tip collection port 43 is sucked by a negative pressure supply source (not shown), the tip t is sucked into the suction nozzle 12 by static electricity. And the chip t can be prevented from adhering to the chip collection port 43, and the chip t can be introduced into the storage unit 5 from the chip collection port 43 more accurately than when the air is simply blown onto the chip t held by the suction nozzle 12. Thus, the separation and collection of the chip t can be performed efficiently.
[0056]
Here, the work of extracting the storage containers 512 and 522 from the storage ports 511 and 521 after the completion of the sorting work or in the middle of the sorting work is performed by gripping the grip portions 512C and 522C of the target storage containers 512 and 522, This is performed by pulling out the storage containers 512 and 522 from 511 and 521.
[0057]
  In this case, the column engagement convex pieces 511A and 521A and the row engagement convex pieces 511B and 521B provided to be able to engage with each other on the front end surfaces of the storage ports 511 and 521 and the front end surfaces of the storage containers 512 and 522, Since the column engagement recesses 512A and 522A and the row engagement recesses 512B and 522B are provided at different positions for the respective storage containers 512 and 522, the storage containers 512 and 522 are originally stored in the storage ports 511 and 521, respectively. If it is going to be accommodated in a position different from the position, the row engaging convex piece511A, 521AOr row engagement recess512A, 522AStorage container512Or containment port511When the storage containers 512 and 522 are restricted from entering the storage ports 511 and 521 and the plurality of storage containers 512 and 522 are taken out of the storage ports 511 and 521 and then stored in the storage ports 511 and 521. However, it is possible to prevent mistakes in inserting the storage containers 512 and 522.
[0058]
Note that the chip transfer sorting device of the present invention is not limited to the chip transfer sorting device of the above-described embodiment, and may be changed as appropriate without departing from the gist of the present invention. For example, in the above-described embodiment, the description has been given of the case where the substantially square plate-shaped chip t in which both side portions in the width direction are formed thin is supplied. However, the shape of the chip t to be supplied is not limited to that in the above embodiment, and for example, the chip t simply formed in a square plate shape may be used. Even in this case, if burrs are generated on both sides of the chip t when the chip t is manufactured, the subsequent chip t rides on the burrs of the target chip t, and the target chip t can be picked up from the conveyance path. There is a risk of disappearing. However, according to the chip transfer sorting apparatus of the present invention, the subsequent chip t does not ride on the target chip t, so that the chip t can be accurately picked up from the transfer path 221, and the transfer to the transfer unit 1 is possible. Parts can be supplied accurately.
[0059]
In the above-described embodiment, the supply unit 2 for supplying the chips t to the transport unit 1 is composed of the bowl portion 21 and the linear portion 22, but the chips t are arranged in a row in a predetermined posture. As long as it can be placed on the conveyance path 221 in a state, the configuration need not necessarily include the bowl portion 21, and may include only the linear portion 22.
[0060]
In the above embodiment, the column engagement convex pieces 511A and 521A and the row engagement convex pieces 511B and 521B, the column engagement concave portions 512A and 522A, and the row engagement are provided at different positions of the storage ports 511 and 521 and the storage containers 512 and 522, respectively. Although it was set as the structure provided with the joint recessed parts 512B and 522B, if it can prevent accommodating the storage containers 512 and 522 in the position different from the predetermined position of the storage ports 511 and 521, it will not be limited to this structure, for example, It is good also as a structure which provides the protrusion and recessed part of a different shape for every storage container 512,522 in the position corresponding to the storage containers 512,522 in the storage port 511,521.
[0061]
【The invention's effect】
As described above, according to the element transport sorting apparatus according to claim 1 of the present invention, the element is placed on the transport path with the surface having a large area vertical, and the suction position by the holding means. Even if the thin portions on both sides of the element placed on the transport path overlap each other due to the vibration of the transport path, the upper part of the target element is in an open state. When the element is sucked by the holding means descending from above and picked up from the transport path, the element overlapping the target element does not interfere with the picking up of the target element, and the element is supplied to the holding means. Can be done accurately. In addition, when sorting elements such as chip component type LEDs with LEDs on the upper surface, since the upper surface of the element can be transported by the holding means, the quality inspection of the LEDs can be performed without changing the attitude of the elements. This eliminates the labor required for sorting.
[0062]
According to the element transport separation apparatus of the second aspect of the present invention, air is blown from the ejecting means provided in the vicinity of the element transport path by the transport means to the element sucked and held by the holding means. By sucking the element into the collection port with the suction means, it is possible to prevent the element from adhering to the holding means and the collection port due to static electricity, and the element is compared with the case where air is simply blown onto the element held by the holding means. It can be accurately introduced into the collection port, and the elements can be collected efficiently.
[0063]
According to the element conveying and separating apparatus according to the third aspect of the present invention, the front end surface of the main body portion and the front end surface of the storage container constituting the storage portion for storing the elements are formed to be able to engage with each other. Since the engaging portion is provided at a different position on the front end surface of each storage container so as to have a column engaging portion indicating a row and a row engaging portion indicating a row, the storage container is originally placed in the main body portion. When it is going to accommodate in a different position, an engaging part contact | abuts a storage container and a main-body part, and the penetration | invasion into the main-body part of a storage container is controlled. For this reason, even when a storage container is accommodated in a main-body part after taking out a several storage container from a main-body part, it can prevent a mistake in putting a storage container.
[Brief description of the drawings]
BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a diagram for explaining the outline of a chip transport sorting apparatus according to an embodiment of the present invention, where (a) is a plan view and (b) is a front view.
FIG. 2 is a perspective view showing a supply unit constituting the chip transport sorting device.
FIGS. 3A and 3B are diagrams for explaining a state in which a chip is conveyed in a linear portion constituting the supply unit.
FIG. 4 is a perspective view showing a transfer unit constituting the chip transfer sorting device.
FIGS. 5A and 5B are diagrams for explaining an operation when a chip sucked and held by a suction nozzle constituting the transport unit is collected. FIG.
FIG. 6 is a front view showing a storage unit that constitutes the chip transport sorting device;
FIG. 7 is a diagram for explaining the outline of a conventional transport sorting apparatus.
FIGS. 8A and 8B are diagrams for explaining a chip transfer state in a supply unit of a conventional transfer sorting apparatus.
[Explanation of symbols]
1 Transport section
11 Transport rotation base
12 Suction nozzle
2 Supply section
21 Bowl
22 Straight section
221 Transport path
3 Inspection equipment
4 collection department
41 Arc base
42 Compressed air injection port
43 Chip recovery port
5 storing section
51 Upper storage
511 receiving port
512 storage container
52 Lower storage
521 receiving port
522 storage container
511A, 521A row engagement convex piece
511B, 521B Line engagement convex piece
512A, 522A row engagement recess
512B, 522B Row engagement recess

Claims (3)

Element by vibrating the conveying path which is placed has a supply means for supplying the device is moved while aligning the position in the conveying path,
A conveying means for sucking and holding an element on the conveying path of the supply means by a holding means from above the conveying path;
An inspection device for inspecting an element conveyed by the conveying means;
Suction releasing means for releasing suction by the holding means;
A storage unit for storing and separating the elements released from the suction by the holding unit by the suction release unit according to the inspection result by the inspection device;
An element transport sorting device comprising:
Said supply means is moved by vibrating the element in the conveying path, there is supply to the aspirating position for aspirating held by the holding means, the conveying path area before Symbol elements of large surface as a vertical Transported while placed on the
The element transport separation device , wherein the holding means sucks and holds a side surface orthogonal to a surface having a large area of the element. Before Symbol suction release means it is conveyed by said conveying means and injection means for injecting air to the element located in the vicinity of the recovery port for recovering the element to the housing portion,
The element transport sorting device according to claim 1, further comprising: a suction unit that sucks the element into the recovery port. Before Symbol housing portion includes a plurality of container for housing the element,
A main body that accommodates each storage container so that it can be taken in and out from its front end surface, and
The front end surface of the main body portion and the front end surface of the storage container have engaging portions formed so as to be able to engage with each other at a position different from the front end surface of each storage container. 2. The element transport sorting device according to claim 1, wherein the device transport sorting device is provided so as to have a row engaging portion indicating

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