JP2019197929A - Component holding device, and suction nozzle determination method - Google Patents

Abstract

To hold component of various attitudes by means of a component holding tool.SOLUTION: A component holding device for holding multiple one kind components scattered in a component support part by means of a suction nozzle includes an attitude determination part for determining the attitude by the surface of one kind component directing upward, on the basis of imaging data of one kind component scattered in the component support part and captured by one imaging device from above, and a memory device for storing the multiple attitudes of one kind component, and suction nozzles of specific nozzle diameters for the multiple attitudes, in association. In order to hold one component, out of the multiple one kind components scattered in the component support part, in the component holding device, the attitude determination part determines the attitude of one component from the imaging data, and selects a suction nozzle of specific nozzle diameter for holding one component, out of suction nozzles of different nozzle diameters stored in the memory device.SELECTED DRAWING: Figure 11

Description

  The present invention relates to a component holding device that holds one component among a plurality of types of components scattered in a component support section.

  There is a component holding device that holds one component among a plurality of components scattered in a component support section. The following patent document describes a technique for gripping parts scattered on a part support part with a robot hand.

JP 2014-161965 A

  According to the technique described in the above-mentioned patent document, the scattered parts can be held to some extent by the parts holder. However, since a plurality of components are scattered in various postures on the component support portion, there is a possibility that only one component support tool can hold a component in a predetermined posture. This invention is made | formed in view of such a situation, and makes it a subject to hold | maintain the components of various attitude | positions with a component holder.

  In order to solve the above-described problem, the present specification provides a component holding device that holds a plurality of types of components scattered in a component support portion by a suction nozzle, and the one of the components scattered in the component support portion. A posture determination unit that determines a posture from a surface facing upward of the one type of component based on imaging data obtained by imaging one type of component from above, and a plurality of the one type of component And a storage device that associates and stores suction nozzles having specific nozzle diameters for each of the plurality of postures, and the component holding devices are scattered in the component support portions. In order to hold one of the types of components, the posture determination unit determines the posture of the one component from the imaging data, and absorbs different nozzle diameters stored in the storage device. From among the nozzles, discloses a component holding device and selects the suction nozzle of a particular nozzle diameter for holding said one component. Further, the present specification provides a method for determining a suction nozzle provided in a component holding device for holding one component among a plurality of types of components scattered in a component support portion, A specific nozzle diameter is obtained for each of the one type of scattered parts captured by a single two-dimensional imaging device from above and the orientation of the one type of parts in the imaging data. Using the association data associated with the suction nozzle, a posture of the one component is determined from the imaging data, and a specific posture associated with the determined posture of the one component in the association data A suction nozzle determination method for selectively determining a suction nozzle having a nozzle diameter as a suction nozzle held by the component holding device is disclosed.

  In the component holding device and the suction nozzle determination method according to the present invention, the posture of one type of component based on imaging data obtained by imaging one type of component scattered on the component support unit from above by one imaging device. Is judged. Further, a plurality of postures of one kind of component and a suction nozzle having a specific nozzle diameter are stored in association with each of the plurality of postures. Accordingly, the component holding device selects a suction nozzle having a specific nozzle diameter in order to hold one component among the scattered components. This makes it possible to hold the scattered components in various postures by the suction nozzle that is one of the component holders.

It is a perspective view which shows a component mounting machine. It is a perspective view which shows the component mounting apparatus of a component mounting machine. It is a perspective view which shows a bulk parts supply apparatus. It is a perspective view which shows a components supply unit. It is a perspective view which shows the components supply unit of the state which the components collection container raised to the raise end position. It is a perspective view which shows a component holding head. It is a figure which shows the component receiving member of the state in which the lead component was accommodated. It is a block diagram which shows the control apparatus of a component mounting machine. It is a perspective view which shows a component scattered state implementation | achievement apparatus. It is a figure which shows the component support member of the state by which the some lead component was scattered. It is a figure which shows notionally the relationship between the image of a lead component of various attitude | positions, a component holder, a moving speed, and suction time. It is a perspective view showing a component scattered state realization device and a component return device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as modes for carrying out the present invention.

<Configuration of component mounter>
FIG. 1 shows a component mounter 10. The component mounter 10 is a device for performing a component mounting operation on the circuit substrate 12. The component mounting machine 10 includes an apparatus main body 20, a base material conveyance holding device 22, a component mounting device 24, imaging devices 26 and 28, a component supply device 30, a loose component supply device 32, and a control device (see FIG. 8) 34. Yes. The circuit substrate 12 includes a circuit board, a three-dimensional structure substrate, and the like, and the circuit board includes a printed wiring board and a printed circuit board.

  The apparatus main body 20 includes a frame portion 40 and a beam portion 42 that is overlaid on the frame portion 40. The substrate conveyance holding device 22 is disposed in the center of the frame portion 40 in the front-rear direction, and includes a conveyance device 50 and a clamp device 52. The conveyance device 50 is a device that conveys the circuit substrate 12, and the clamp device 52 is a device that holds the circuit substrate 12. Thereby, the base material transport and holding device 22 transports the circuit base material 12 and holds the circuit base material 12 fixedly at a predetermined position. In the following description, the conveyance direction of the circuit substrate 12 is referred to as an X direction, a horizontal direction perpendicular to the direction is referred to as a Y direction, and a vertical direction is referred to as a Z direction. That is, the width direction of the component mounting machine 10 is the X direction, and the front-rear direction is the Y direction.

  The component mounting device 24 is disposed in the beam portion 42 and includes two work heads 60 and 62 and a work head moving device 64. Each work head 60, 62 has a component holder 66 (see FIG. 2) 66 such as a chuck and a suction nozzle, and holds the component by the component holder 66. The work head moving device 64 includes an X direction moving device 68, a Y direction moving device 70, and a Z direction moving device 72. Then, the two working heads 60 and 62 are integrally moved to arbitrary positions on the frame portion 40 by the X-direction moving device 68 and the Y-direction moving device 70. Further, as shown in FIG. 2, each work head 60, 62 is detachably attached to the sliders 74, 76, and the Z-direction moving device 72 individually moves the sliders 74, 76 in the vertical direction. That is, the work heads 60 and 62 are individually moved in the vertical direction by the Z-direction moving device 72.

  The imaging device 26 is attached to the slider 74 in a state of facing downward, and is moved together with the work head 60 in the X direction, the Y direction, and the Z direction. Thereby, the imaging device 26 images an arbitrary position on the frame unit 40. As shown in FIG. 1, the imaging device 28 is disposed between the base material conveyance holding device 22 and the component supply device 30 on the frame portion 40 so as to face upward. Thereby, the imaging device 28 images the components held by the component holder 66 of the work heads 60 and 62.

  The component supply device 30 is disposed at one end of the frame portion 40 in the front-rear direction. The component supply device 30 includes a tray-type component supply device 78 and a feeder-type component supply device (not shown). The tray-type component supply device 78 is a device that supplies components placed on the tray. The feeder-type component supply device is a device that supplies components using a tape feeder (not shown) and a stick feeder (not shown).

  The bulk component supply device 32 is disposed at the other end of the frame portion 40 in the front-rear direction. The separated component supply device 32 is a device for aligning a plurality of components scattered in a separated state and supplying the components in an aligned state. That is, it is an apparatus that aligns a plurality of components in an arbitrary posture into a predetermined posture and supplies the components in a predetermined posture. Below, the structure of the component supply apparatus 32 is demonstrated in detail. Note that examples of the components supplied by the component supply device 30 and the bulk component supply device 32 include electronic circuit components, solar cell components, and power module components. Electronic circuit components include components having leads and components not having leads.

  As shown in FIG. 3, the bulk component supply device 32 includes a main body 80, a component supply unit 82, an imaging device 84, and a component delivery device 86.

(A) Component supply unit The component supply unit 82 includes a component supplier 88, a component scattered state realization device 90, and a component return device 92, and the component supplier 88, the component scattered state realization device 90, and the component return device 92. Are integrally configured. The component supply unit 82 is detachably assembled to the base 96 of the main body 80. In the bulk component supply device 32, five component supply units 82 are arranged in a line in the X direction.

(I) Component supplier The component supplier 88 includes a component container 100, a housing 102, and a grip 104 as shown in FIG. The component container 100 has a generally rectangular parallelepiped shape, and an upper surface and a front surface are open. The bottom surface of the component container 100 is an inclined surface 116, which is inclined toward the front surface where the component container 100 is opened.

  The housing 102 has a pair of side walls 120, and the component container 100 is slidably held between the pair of side walls 120. An inclined plate 152 is fixedly disposed between the pair of side walls 120 so as to be positioned in front of the lower end portion of the front surface of the component container 100. The inclined plate 152 is inclined so as to descend toward the front.

  The grip 104 is disposed at an end on the rear side of the housing 102, and includes a fixed grip member 170 and a movable grip member 172. The movable gripping member 172 can be moved toward and away from the fixed gripping member 170. The movable gripping member 172 is connected to the rear surface of the component container 100 by a connecting arm (not shown). As a result, when the grip 104 is gripped, the movable gripping member 172 approaches and separates from the fixed gripping member 170, and the component container 100 swings between the pair of side walls 120.

  The component supplier 88 is disposed between a pair of side frame portions 190 assembled to the base 96 and is detachable from the base 96. A lock mechanism (not shown) is provided at the lower end of the movable grip member 172 of the grip 104, and the lock mechanism is released when the grip 104 is gripped. That is, when the operator holds the grip 104 of the component supplier 88 and lifts the component supplier 88, the component supplier 88 is removed from between the pair of side frame portions 190.

(Ii) Component scattered state realization device The component scattered state realization device 90 includes a component support member 220, a component support member moving device 222, and a feeder vibration device 224. The component support member 220 has a generally longitudinal plate shape and is disposed so as to extend forward from below the inclined plate 152 of the component feeder 88. Side wall portions 228 are formed on both side edges in the longitudinal direction of the component support member 220.

  The component support member moving device 222 is a device that moves the component support member 220 in the front-rear direction by driving an electromagnetic motor (see FIG. 8) 223. As a result, the component support member 220 moves in the front-rear direction slightly below the lower end of the inclined plate 152 of the component supplier 88 with the upper surface of the component support member 220 being horizontal.

  The feeder vibration device 224 includes a cam member 240, a cam follower 242, and a stopper 244. The cam member 240 has a plate shape and is fixed to the outer side surface of the side wall portion 228 so as to extend in the front-rear direction. At the upper end of the cam member 240, a plurality of teeth 245 are formed at equal intervals in the front-rear direction. The cam follower 242 includes a lever 252 and a roller 254. The lever 252 is disposed at the lower end portion of the side wall 120 of the component supplier 88 and can swing around the upper end portion. The roller 254 is rotatably held at the lower end portion of the lever 252. The lever 252 is urged in the forward direction by the elastic force of a coil spring (not shown). The stopper 244 is provided in a protruding shape on the side wall 120, and a lever 252 biased by the elastic force of the coil spring is in contact with the stopper 244.

(Iii) Component Return Device The component return device 92 includes a container lifting device 260 and a component collection container 262 as shown in FIG. The container elevating device 260 includes an air cylinder 266 and an elevating member 268, and the elevating member 268 moves up and down by the operation of the air cylinder 266. The air cylinder 266 is fixed to the front end of the component support member 220. Thus, the air cylinder 266 moves in the front-rear direction together with the component support member 220 by the operation of the component support member moving device 222.

  The component collection container 262 is disposed on the upper surface of the elevating member 268 and moves up and down by the operation of the air cylinder 266. The component collection container 262 has a box shape with an open top surface, and is rotatably held on the top surface of the elevating member 268. As shown in FIG. 4, a protruding pin 272 is disposed at the rear end of the component collection container 262. The protruding pin 272 protrudes outward on the side of the component collection container 262. Further, an engagement block 274 is fixed inside the upper end portion on the front side of the side frame portion 190. As shown in FIG. 5, when the component collection container 262 is raised to the rising end position by the operation of the air cylinder 266, the protruding pin 272 is engaged with the engagement block 274. Thereby, the parts collection container 262 rotates.

(B) Imaging Device As shown in FIG. 3, the imaging device 84 includes a camera 290 and a camera moving device 292. The camera moving device 292 includes a guide rail 296 and a slider 298. The guide rail 296 is fixed to the main body 80 so as to extend in the width direction of the loose component supply device 32 above the component supplier 88. The slider 298 is slidably attached to the guide rail 296, and slides to an arbitrary position by the operation of the electromagnetic motor (see FIG. 8) 299. The camera 290 is attached to the slider 298 so as to face downward.

(C) Component Delivery Device The component delivery device 86 includes a component holding head moving device 300, a component holding head 302, and two shuttle devices 304, as shown in FIG.

  The component holding head moving device 300 includes an X direction moving device 310, a Y direction moving device 312, and a Z direction moving device 314. The Y-direction moving device 312 has a Y slider 316 disposed above the component supply unit 82 so as to extend in the X direction. The Y slider 316 is driven by an electromagnetic motor (see FIG. 8) 319. , Move to any position in the Y direction. The X-direction moving device 310 has an X-slider 320 disposed on the side surface of the Y-slider 316. The X-slider 320 is moved to an arbitrary position in the X-direction by driving an electromagnetic motor (see FIG. 8) 321. Moving. The Z-direction moving device 314 has a Z-slider 322 disposed on the side surface of the X-slider 320. The Z-slider 322 is moved to an arbitrary position in the Z-direction by driving an electromagnetic motor (see FIG. 8) 323. Moving.

  As shown in FIG. 6, the component holding head 302 includes a head main body 330, a component holder 332, a holder turning device 334, and a holder rotating device 335. The head body 330 is formed integrally with the Z slider 322. The component holder 332 holds components and is detachably attached to the lower end portion of the holder 340. The holder 340 can be bent at the support shaft 344, and the holder 340 is bent 90 degrees upward by the operation of the holder turning device 334. As a result, the component holder 332 attached to the lower end of the holder 340 turns 90 degrees and is positioned at the turning position. That is, the component holder 332 turns between the non-turning position and the turning position by the operation of the holder turning device 334. Further, the holder rotating device 335 rotates the component holder 332 around its axis.

  As shown in FIG. 3, a holder station 350 is disposed on the upper surface of the base 96. A plurality of component holders 332 are stored in the holder station 350, the component holder 332 mounted on the holder 340 of the component holding head 302, and the component holder 332 stored in the holder station 350. Are exchanged by operation of the holder station 350 and the component holding head moving device 300. The holder station 350 stores, as the component holder 332, a suction nozzle that sucks and holds the component by air suction and a chuck that holds the component by a pair of claws. Further, there are a plurality of types of suction nozzles stored in the holder station 350 having different nozzle diameters.

  Further, as shown in FIG. 3, each of the two shuttle devices 304 includes a component carrier 388 and a component carrier moving device 390, and is fixed to the main body 80 side by side in front of the component supply unit 82. Has been. Five component receiving members 392 are mounted on the component carrier 388 in a row in the horizontal direction, and the components are placed on each component receiving member 392.

  Specifically, as shown in FIG. 7, the component supplied by the bulk component supply device 32 is an electronic circuit component (hereinafter, may be abbreviated as “lead component”) 410 having a lead. The block-shaped component main body 412 and two leads 414 protruding from the bottom surface of the component main body 412 are configured. The component receiving member 392 is formed with a component receiving recess 416. The component receiving recess 416 is a stepped recess, and includes a main body receiving recess 418 that opens to the top surface of the component receiving member 392 and a lead receiving recess 420 that opens to the bottom surface of the main body receiving recess 418. Yes. The lead component 410 is inserted into the component receiving recess 416 with the lead 414 facing downward. As a result, the lead 414 is inserted into the lead receiving recess 420 and the lead component 410 is placed inside the component receiving recess 416 with the component main body 412 inserted into the main body receiving recess 418.

  Further, as shown in FIG. 3, the component carrier moving device 390 is a plate-like longitudinal member, and is disposed on the front side of the component supply unit 82 so as to extend in the front-rear direction. A component carrier 388 is slidably disposed in the front-rear direction on the upper surface of the component carrier moving device 390, and is slid to an arbitrary position in the front-rear direction by driving an electromagnetic motor (see FIG. 8) 430. When the component carrier 388 slides in a direction approaching the component supply unit 82, the component carrier 388 slides to a component receiving position located within the movement range of the component holding head 302 by the component holding head moving device 300. On the other hand, when the component carrier 388 slides in the direction away from the component supply unit 82, the component carrier 388 slides to the component supply position located within the movement range of the work heads 60 and 62 by the work head moving device 64.

  Further, as shown in FIG. 8, the control device 34 includes an overall control device 450, a plurality of individual control devices (only one is shown in the figure) 452, an image processing device 454, and a storage device 456. Including. The overall control device 450 is configured mainly by a computer, and is connected to the base material conveyance holding device 22, the component mounting device 24, the imaging device 26, the imaging device 28, the component supply device 30, and the loose component supply device 32. ing. Thereby, the overall control device 450 controls the base material conveyance holding device 22, the component mounting device 24, the imaging device 26, the imaging device 28, the component supply device 30, and the loose component supply device 32 in an integrated manner. The plurality of individual control devices 452 are configured mainly by a computer, and are provided in the base material conveyance holding device 22, the component mounting device 24, the imaging device 26, the imaging device 28, the component supply device 30, and the bulk component supply device 32. (In the figure, only the individual control device 452 corresponding to the bulk component supply device 32 is shown). The individual control device 452 of the bulk component supply device 32 is connected to a component scattered state realization device 90, a component return device 92, a camera moving device 292, a component holding head moving device 300, a component holding head 302, and a shuttle device 304. Thereby, the individual control device 452 of the bulk component supply device 32 controls the component scattered state realization device 90, the component return device 92, the camera moving device 292, the component holding head moving device 300, the component holding head 302, and the shuttle device 304. . In addition, the image processing device 454 is connected to the imaging device 84 and processes imaging data captured by the imaging device 84. The image processing device 454 is connected to the individual control device 452 of the bulk component supply device 32. As a result, the individual control device 452 of the bulk component supply device 32 acquires the imaging data captured by the imaging device 84. The storage device 456 stores various data and is connected to the individual control device 452. As a result, the individual control device 452 acquires various data from the storage device 456.

<Operation of component mounter>
In the component mounting machine 10, the component mounting operation is performed on the circuit substrate 12 held by the substrate conveyance holding device 22 with the above-described configuration. Specifically, the circuit substrate 12 is transported to the work position, and is fixedly held by the clamp device 52 at that position. Next, the imaging device 26 moves above the circuit substrate 12 and images the circuit substrate 12. Thereby, the information regarding the error of the holding position of the circuit base material 12 is obtained. In addition, the component supply device 30 or the bulk component supply device 32 supplies components at a predetermined supply position. It should be noted that the supply of components by the bulk component supply device 32 will be described in detail later. Then, one of the work heads 60 and 62 moves above the component supply position, and the component holder 66 holds the component. Subsequently, the work heads 60 and 62 holding the components move above the imaging device 28, and the components held by the component holder 66 are imaged by the imaging device 28. As a result, information on the error of the component holding position can be obtained. Then, the work heads 60 and 62 holding the components move above the circuit substrate 12 and correct the held components for errors in the holding position of the circuit substrate 12, errors in the holding position of the components, and the like. And mounted on the circuit substrate 12.

<Operation of bulk parts supply device>
(A) Lead component supply by bulk component supply device In the bulk component supply device 32, the lead component 410 is thrown into the component container 100 of the component feeder 88 by the operator, and the lead component 410 thus loaded is the component. By the operation of the supply unit 82 and the component delivery device 86, the component is supplied while being placed on the component receiving member 392 of the component carrier 388. Specifically, the operator inputs the lead component 410 from the opening on the upper surface of the component container 100 of the component supplier 88. At this time, the component support member 220 is moved below the component supplier 88 by the operation of the component support member moving device 222, and the component collection container 262 is located in front of the component supplier 88.

  The lead component 410 introduced from the opening on the upper surface of the component container 100 falls on the inclined surface 116 of the component container 100 and spreads on the inclined surface 116. At this time, when the lead component 410 that has fallen on the inclined surface 116 rolls over the inclined plate 152, the lead component 410 is accommodated in the component collection container 262 located in front of the component supplier 88.

  After the lead component 410 is inserted into the component container 100, the component support member 220 is moved from below the component feeder 88 toward the front by the operation of the component support member moving device 222. At this time, when the cam member 240 reaches the cam follower 242, the roller 254 of the cam follower 242 gets over the teeth 245 of the cam member 240 as shown in FIG. The lever 252 of the cam follower 242 is biased in the forward direction by the elastic force of the coil spring, and the forward bias of the lever 252 is restricted by the stopper 244. For this reason, when the component support member 220 moves forward, the roller 254 and the teeth 245 are maintained in mesh with each other, the lever 252 does not rotate forward, and the roller 254 has the teeth 245. Get over. At this time, the component feeder 88 moves up and down as the roller 254 gets over the teeth 245. That is, in a state where the roller 254 is engaged with the teeth 245, the component support member 220 moves forward, so that the roller 254 gets over the plurality of teeth 245, and the component feeder 88 continuously vibrates in the vertical direction. .

  The lead component 410 spreading on the inclined surface 116 of the component container 100 moves forward due to the vibration of the component feeder 88 and the inclination of the inclined surface 116, and the upper surface of the component support member 220 via the inclined plate 152. To be discharged. At this time, the lead part 410 is prevented from dropping from the component support member 220 by the side wall portion 228 of the component support member 220. The lead parts 410 are scattered on the upper surface of the part support member 220 as the part support member 220 moves forward.

  When the lead component 410 is scattered on the component support member 220 from the inside of the component container 100, the lead component 410 is scattered on the component support member 220 in various postures as shown in FIG. The Specifically, the component body 412 of the lead component 410 has a generally rectangular parallelepiped shape and has six surfaces. These six surfaces are a bottom surface 500 from which the lead 414 extends, a top surface 502 on the back side of the bottom surface 500, and four side surfaces 504, 506, 508, 510. The four side surfaces 504, 506, 508, 510 have a first surface 504 having a large surface area and a large amount of unevenness, a second side surface 506 that is the back side of the first side surface 504 and has no unevenness, These are a third side surface 508 and a fourth side surface 510 on the lateral side of the first side surface 504 and the second side surface 506. The third side surface 508 and the fourth side surface 510 have substantially the same surface area, but the third side surface 508 has a larger flat area than the fourth side surface 510.

  When such lead components 410 are scattered on the component support member 220, the lead component 410 is supported on the component support member 220 in approximately six postures. Specifically, a posture in which the first side surface 504 is directed straight up (hereinafter sometimes referred to as “first posture”) and a posture in which the second side surface 506 is directed straight up (hereinafter referred to as “second posture”). ), A posture in which the third side surface 508 is directed straight up (hereinafter, may be described as “third posture”), and a posture in which the fourth side surface 510 is directed straight up (hereinafter referred to as “third posture”). , Sometimes referred to as a “fourth posture”), a posture with the bottom surface 500 facing directly upward (hereinafter, sometimes referred to as a “fifth posture”), and the first side surface 504 or the second side surface 506. The lead component 410 is supported on the component support member 220 in any one of the six postures, in which the angle is directed obliquely upward (hereinafter may be referred to as “sixth posture”). . Note that the lead component 410 in the sixth posture has the first side surface 504 or the second side surface 506 facing obliquely upward as the tip of the lead component 410 contacts the component support member 220.

  As described above, when the lead component 410 is scattered on the component support member 220 in various postures, the camera 290 of the imaging device 84 moves above the component support member 220 by the operation of the camera moving device 292. Then, the lead component 410 is imaged. Based on the image data captured by the camera 290, a lead component to be picked up (hereinafter may be abbreviated as “pickup target component”) is held by the component holder 332 of the component holding head 302. . However, the pickup target component is held by the component holder 332 according to the posture of the pickup target component on the component support member 220.

  Specifically, the posture of the component and the position of the component are calculated for each of a plurality of components scattered on the component support member 220 based on the imaging data of the camera 290. Then, only the lead component 410 whose calculated component posture is the first to fourth postures is specified as the pickup target component. This is because, in the lead component 410 in the fifth posture, the lead 414 extends upward, and the lead component 410 in that posture cannot be held by the component holder 332. In addition, in the lead component 410 in the sixth posture, the component main body 412 is inclined, and the lead component 410 in that posture cannot be held by the component holder 332.

  When the pickup target component is specified, the type of the component holder for holding the pickup target component is determined according to the posture of the pickup target component on the component support member 220. Specifically, as shown in FIG. 11, the storage device 456 includes image data of the lead component 410 for each of the first to fourth postures of the pickup target component, the type of the component holder, and the component holding head moving device 300. The moving speed of the component holding head 302 and the air suction time when the component holder 332 is a suction nozzle are stored in association with each other.

Specifically, the image data of the lead component 410 in the first posture in which the first side surface 504 faces directly upward, “chuck A” as the component holder 332, and the moving speed V ₁ are associated with each other, and the storage device 456 is stored. Further, the image data of the lead component 410 in the second posture with the second side surface 506 facing directly upward, the “suction nozzle A” as the component holder 332, the moving speed V _2, and the suction time T ₁ , They are stored in the storage device 456 in association with each other. Further, the image data of the lead component 410 in the third posture with the third side surface 508 facing right above, the “suction nozzle B” as the component holder 332, the moving speed V _3, and the suction time T ₂ are as follows: They are stored in the storage device 456 in association with each other. Further, the image data of the lead component 410 in the fourth posture with the fourth side surface 510 facing directly upward, the “suction nozzle C” as the component holder 332, the moving speed V _4, and the suction time T ₃ , They are stored in the storage device 456 in association with each other.

  For this reason, when the pickup target component is the lead component 410 in the first posture, the component holder 332 is determined to be “chuck A”. This is because, in the lead component 410 in the first posture, the first side surface 504 with many irregularities faces upward, and there is no flat surface that can be sucked by the suction nozzle on the first side surface 504. is there. Then, in the holder station 350, the “chuck A” is mounted on the holder 340 of the component holding head 302, and the lead component 410 in the first posture is gripped by the “chuck A”. Thereby, it is possible to appropriately hold the lead component 410 in the first posture. Note that when the pickup target component is held by the component holder 332, the component holder 332 is located at the non-rotating position.

Further, when the pickup target component is the lead component 410 in the second posture, the component holder 332 is determined as the “suction nozzle A”. “Suction nozzle A” is a suction nozzle having a relatively large nozzle diameter. This is because the lead component 410 in the second posture has no irregularities and the second side surface 506 having a large surface area faces upward, and the second side surface 506 has a large area that can be adsorbed by the adsorption nozzle A. This is because a flat surface exists. In the holder station 350, the “suction nozzle A” is mounted on the holder 340 of the component holding head 302, and the lead component 410 in the second posture is suction-held by the “suction nozzle A”. When the suction time is stored in association with the posture of the lead component 410, the lead component 410 is suctioned and held by the suction nozzle according to the suction time. That is, when the lead part 410 of the second position is held by suction by the "suction nozzle A ', the time the air is sucked from the suction nozzle is a T _1. "Suction nozzle A", as described above, since a relatively large nozzle diameter, to retain the lead component 410 ensures that the suction time T ₁ is long to some extent. As a result, the lead component 410 in the second posture can be appropriately held.

Further, when the pickup target component is the lead component 410 in the third posture, the component holder 332 is determined as the “suction nozzle B”. The nozzle diameter of “Suction nozzle B” is smaller than the nozzle diameter of “Suction nozzle A”. This is because in the lead component 410 in the third posture, the third side surface 508 having a smaller surface area than the second side surface 506 faces upward, and the flat surface having the small surface area is sucked and held by the suction nozzle B. . Then, in the holder station 350, the “suction nozzle B” is mounted on the holder 340 of the component holding head 302, and the lead component 410 in the third posture is suction-held by the “suction nozzle B”. Incidentally, when the third posture of the lead component 410 is held by suction by the "suction nozzle B", the time the air is sucked from the suction nozzle is a T _2. Since the nozzle diameter of “Suction nozzle B” is smaller than the nozzle diameter of “Suction nozzle A” as described above, the amount of air sucked by “Suction nozzle B” is larger than the amount of air sucked by “Suction nozzle A”. At least, the lead component 410 can be held. Thus, suction time T ₂ are are shorter than the suction time T _1. This makes it possible to appropriately hold the lead component 410 in the third posture and shorten the time required for suction.

When the pickup target component is the lead component 410 in the fourth posture, the component holder 332 is determined as the “suction nozzle C”. The nozzle diameter of “Suction nozzle C” is smaller than the nozzle diameter of “Suction nozzle B”. This is because, in the lead component 410 in the fourth posture, the fourth side surface 510 having a smaller surface area than the third side surface 508 faces upward, and the flat surface with the small surface area is sucked and held by the suction nozzle C. . In the holder station 350, the “suction nozzle C” is mounted on the holder 340 of the component holding head 302, and the lead component 410 in the fourth posture is suction-held by the “suction nozzle C”. Incidentally, when the lead part 410 of the fourth posture is held adsorbed by the "suction nozzle C", the time the air is sucked from the suction nozzle is a T _3. Since the nozzle diameter of the “suction nozzle C” is smaller than the nozzle diameter of the “suction nozzle B” as described above, the air suction amount by the “suction nozzle C” is larger than the air suction amount by the “suction nozzle B”. At least, the lead component 410 can be held. Thus, suction time T ₃ is shorter than the suction time T _2. Accordingly, it is possible to appropriately hold the lead component 410 in the fourth posture and shorten the time required for suction.

Then, after the lead component 410 is held by the component holder 332, the component holding head 302 is moved above the component carrier 388, and the moving speed of the component holding head 302 at this time holds the lead component 410. It is changed according to the type of the component holder 332 being installed. Specifically, as described above, the storage device 456 stores the posture of the lead component 410 on the component support member 220 and the moving speed of the component holding head 302 by the component holding head moving device 300 in association with each other. . Therefore, for example, the moving speed of the component holding head 302 when the lead component 410 in the first posture is held by the “chuck A” is V ₁ . That is, when the lead parts 410 "Chuck A" is held by the moving speed of the component holding head 302 is a V _1. Movement speed V ₁ is set to a relatively fast speed. This is because the “chuck A” has a structure in which a part is clamped by a pair of claws and has a strong holding force, so that even if the part holding head 302 is moved at a high speed, the lead part 410 does not easily fall off. is there.

The moving speed of the component holding head 302 at the time of lead parts 410 in the second posture is maintained by the "suction nozzle A 'is a V _2. That is, when the lead parts 410 "suction nozzle A" is held by the moving speed of the component holding head 302 is a V _2. Moving speed V ₂ is set to a slower speed than the moving speed V _1. This is because the “suction nozzle A” has a structure that sucks and holds parts by suction of air and has a weaker holding force than “chuck A”, so that the lead part 410 is prevented from falling off when the parts holding head 302 is moved. is there.

The moving speed of the component holding head 302 when the lead part 410 of the third posture is maintained by the "suction nozzle B" is a V _3. That is, when the lead parts 410 "suction nozzle B" holds, the moving speed of the component holding head 302 is a V _3. Moving speed V ₃ is set to a speed slower than the moving speed V _2. This is because the nozzle diameter of the “suction nozzle B” is smaller than the nozzle diameter of the “suction nozzle A” and its holding power is weaker than that of the “suction nozzle A”, so that the lead component 410 is prevented from falling off when the component holding head 302 is moved. It is.

The moving speed of the component holding head 302 when the lead part 410 of the fourth position is held by the "suction nozzle C", are V _4. That is, when the lead parts 410 "suction nozzle C" holds, the moving speed of the component holding head 302 is a V _4. Moving speed V ₄ is set to a speed slower than the moving speed V _3. This is because the nozzle diameter of the “suction nozzle C” is smaller than the nozzle diameter of the “suction nozzle B” and its holding power is weaker than that of the “suction nozzle B”, so that the lead component 410 is prevented from falling off when the component holding head 302 is moved. It is.

  In this way, by changing the moving speed of the component holding head 302 according to the type of the component holder 332 that holds the lead component 410, the moving speed of the component holding head 302 is prevented while preventing the lead component 410 from falling off. Can be made as soon as possible.

  When the component holder 332 that holds the lead component 410 is moved above the component carrier 388, the component carrier 388 is moved to the component receiving position by the operation of the component carrier moving device 390. Further, when the component holding head 302 moves above the component carrier 388, the component holder 332 is turned to the turning position. The component holder 332 is rotated by the operation of the holder rotating device 335 so that the lead 414 of the lead component 410 held by the component holder 332 in the turning position faces downward in the vertical direction.

  When the component holding head 302 moves above the component carrier 388, the lead component 410 with the lead 414 facing downward in the vertical direction is inserted into the component receiving member 392. As a result, as shown in FIG. 7, the lead component 410 is placed on the component receiving member 392 with the lead 414 facing downward in the vertical direction.

  When the lead component 410 is placed on the component receiving member 392, the component carrier 388 moves to the component supply position by the operation of the component carrier moving device 390. Since the component carrier 388 moved to the component supply position is located in the movement range of the work heads 60 and 62, the lead component 410 is supplied at this position in the loose component supply device 32. As described above, in the loose component supply device 32, the lead component 410 is supplied with the lead 414 facing downward and the upper surface 502 facing the bottom surface 500 to which the lead 414 is connected facing upward. Therefore, the component holder 66 of the work heads 60 and 62 can appropriately hold the lead component 410.

(B) Collection of Lead Components In the separated component supply apparatus 32, the lead components 410 scattered on the component support member 220 can be collected. Specifically, the component support member 220 is moved downward of the component feeder 88 by the operation of the component support member moving device 222. At this time, as shown in FIG. 12, the lead component 410 on the component support member 220 is blocked by the inclined plate 152 of the component feeder 88, and the lead component 410 on the component support member 220 is inserted into the component collection container 262. It is scraped off inside.

  Next, the parts collection container 262 is raised by the operation of the container lifting device 260. At this time, as shown in FIG. 5, the protruding pin 272 disposed in the component collection container 262 engages with an engagement block 274 disposed inside the side frame portion 190. Thereby, the component collection container 262 rotates, and the lead component 410 in the component collection container 262 is returned to the inside of the component container 100.

  In the bulk component supply device 32, as described above, the lead component 410 in the first to fourth postures is picked up by the component holder 332 corresponding to the posture of the lead component. For this reason, the number of lead components 410 returned to the component container 100 can be reduced.

  Then, as described above, when the operator holds the grip 104 of the component supplier 88, the lock of the component supplier 88 is released, and when the component supplier 88 is lifted, the component supplier 88 is paired. It is removed from between the side frame parts 190 of. As a result, the lead component 410 is recovered from the component supplier 88 outside the bulk component supply device 32.

  The individual control device 452 of the component supply device 32 includes an attitude determination unit 470, a holder determination unit 472, a movement speed determination unit 474, and an index value determination unit 476, as shown in FIG. The posture determination unit 470 is a functional unit for determining the posture of the lead components 410 scattered on the component support member 220. The holder determining unit 472 is a functional unit for determining the type of component holder 332 corresponding to the posture of the lead component 410. The moving speed determination unit 474 is a functional unit for determining the moving speed of the component holding head 302 according to the posture of the lead component 410. The index value determination unit 476 is a functional unit for determining the air suction time when the lead component 410 is sucked and held by the suction nozzle as the component holder 332.

  The present invention is not limited to the above-described embodiments, and can be implemented in various modes with various modifications and improvements based on the knowledge of those skilled in the art. Specifically, for example, in the above embodiment, suction nozzles having different nozzle diameters are employed as the suction nozzles according to the posture of the lead component 410 on the component support member 220, but the shape of the nozzles is different. It is possible to employ a suction nozzle.

  In the above embodiment, the air suction time is changed according to the type of suction nozzle that sucks and holds the lead component 410. However, the index value that indicates the air suction amount can be changed. . Specifically, for example, it is possible to change the air suction amount, the suction force, and the like.

  In the above embodiment, the present invention is applied to the lead component 410 having the lead 414. However, the present invention can be applied to various types of components. Specifically, the present invention can be applied to, for example, solar cell components, power module components, electronic circuit components without leads, and the like.

  32: Bulk component supply device (component supply device) 84: Imaging device 220: Component support member (component support portion) 300: Component holding head moving device (moving device) 332: Component holder 452: Individual control device (control device) 456: Storage device 470: Posture determination unit 472: Holder determination unit 474: Movement speed determination unit 476: Index value determination unit

Claims (5)

A component holding device that holds a plurality of types of components scattered in a component support portion with a suction nozzle,
An attitude determination unit that determines an attitude from a surface facing the upper side of the one type of component based on imaging data obtained by imaging an image of the one type of component scattered on the component support unit from above. When,
A plurality of postures of the one type of component, and a storage device that associates and stores suction nozzles having a specific nozzle diameter for each of the plurality of postures;
With
In order for the component holding device to hold one component among a plurality of types of components scattered in the component support unit, the posture determination unit determines the posture of the one component from the imaging data. A component holding device that selects a suction nozzle having a specific nozzle diameter for holding the one component from suction nozzles having different nozzle diameters stored in the storage device. And a moving device for moving the suction nozzle,
By operating the moving device, the suction nozzle of the specific nozzle diameter is selectively selected from the suction nozzles of the different nozzle diameters, and the suction nozzle of the selected specific nozzle system is automatically held. The component holding device according to claim 1. The mobile device is
3. The component holding device according to claim 2, wherein when the suction nozzle holding the one component is moved, the moving speed is changed according to the nozzle diameter of the suction nozzle.   The component holding device according to any one of claims 1 to 3, wherein the imaging device is a two-dimensional imaging device. A method for determining a suction nozzle provided in a component holding device for holding one component among a plurality of types of components scattered in a component support section,
Specified for each of the one type of parts scattered on the support part and captured by one two-dimensional imaging device from above, and for each posture of the one type of parts in the imaging data And using the association data associated with the suction nozzles of the nozzle diameter, the posture of the one component is determined from the imaging data, and is associated with the determined posture of the one component in the association data. A suction nozzle determination method for alternatively determining a suction nozzle having a specific nozzle diameter as a suction nozzle held by the component holding device.

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