JP2014093424A - Electronic component mounting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reliably eject a storage tape that causes component shortage when automatically loading the storage tape for storing a component.SOLUTION: When a storage tape CX is ejected to a tape ejection guide, the storage tape coming off from a sprocket 29 is guided through a tape guide cavity between a guide plate and a chute surface on a chute block. Thus, the subsequent storage tape can reliably push out the storage tape, which causes component shortage, to the tape ejection guide 155.

Description

  The present invention relates to an electronic component mounting apparatus including a component supply unit that supplies an electronic component stored in a storage recess of a storage tape to a component extraction position by moving the storage tape.

  For example, as disclosed in Patent Document 1 and the like, a conventional component supply unit feeds a storage tape so that an electronic component is reliably taken out. Then, a new storage tape was loaded in the component supply unit.

JP 2011-216793 A

However, when the storage tape for supplying the electronic parts is out of parts and is discharged, if it is removed from the last sprocket, it cannot be sent any further. Then, when a new tape that is automatically loaded is sent, there is a possibility that the remaining tape may not be reliably ejected. Therefore, the present invention provides a part for automatically loading a storage tape for storing parts. The purpose is to ensure that out-of-stock storage tape can be discharged reliably.

  For this reason, the first invention has a component supply unit that intermittently moves the storage tape and supplies the electronic component stored in the storage recess of the storage tape to the component extraction position. In the electronic component mounting apparatus having a discharge guide for discharging the storage tape discharged from the component supply unit, the component supply unit picks up the component by rotating the sprocket. The storage tape engaged with the sprocket is positioned at a position, and a tip guide for guiding the storage tape sent downstream from the sprocket to the opening of the discharge guide is provided.

  According to a second aspect of the present invention, in the electronic component mounting apparatus according to the first aspect, the tip guide has a guide gap with a predetermined interval for guiding the storage tape.

  According to a third aspect of the present invention, in the electronic component mounting apparatus according to the second aspect, the tip guide is provided so as to cover the opening of the discharge guide between the front side wall and the rear side wall.

  According to the present invention, when a storage tape for storing components is automatically loaded, the storage tape that has run out of components can be reliably discharged.

It is a top view of an electronic component mounting apparatus. It is a perspective view of a storage tape. FIG. 3A shows a storage tape for large parts, and FIG. 3A shows a storage tape for small parts. It is a schematic side view of a component supply unit. It is a schematic plan view of a component supply unit. It is a top view of a tape processing unit. It is a schematic side view explaining the mechanism of a 1st component dropping apparatus. It is sectional drawing of the 1st component dropping apparatus shown in FIG. It is a schematic side view explaining the mechanism of the 2nd component dropping apparatus. It is a side view of a cutter. It is a front view of a cutter. It is a top view of a cutter. It is a bottom view of a cutter. It is a side view of the front-end | tip part of a cutter. It is an explanatory view when the edge of a cutter hits the end face of a storage tape. It is an explanatory view of the state where the cover tape is peeled off by the cutter. It is explanatory drawing when the edge of a cutter hits the part slightly below the boundary of the cover tape and carrier tape of the end surface of a storage tape. It is a figure which shows an operation panel. It is a side view which shows the downstream of the components supply unit installed in the feeder base. It is a side view which shows the downstream edge part of a components supply unit. It is a side view which shows the downstream front-end | tip part of a component supply unit in a partial cross section. It is a side view which shows the state through which a storage tape passes in a partial cross section through the downstream edge part of a components supply unit. It is sectional drawing which looked at the front-end | tip guide in the tape feed direction. It is sectional drawing which looked at the front-end | tip guide of the state which guides a paper tape and an embossing tape in the tape feed direction.

  Hereinafter, based on FIG. 1 which is a top view of the electronic component mounting apparatus 1, embodiment of this invention is described. First, a plurality of component supply devices 3A, 3B, 3C, and 3D are arranged in parallel on the front and rear portions of the electronic component mounting device 1 on the device main body 2 in four blocks.

  Each of the component supply devices 3A, 3B, 3C, and 3D includes a plurality of component supply units 5 arranged in parallel on a feeder base of a cart base that is a mounting base, and a printed circuit board having a tip on the component supply side as a substrate. When the cart base is properly attached to the apparatus main body 2, the power is supplied to the component supply unit 5 mounted on the cart base so as to face the conveyance path of P. When the connector is released and the handle is pulled, it can be moved by a caster provided on the lower surface.

  In addition, when the connection between the connectors connected to the power supply is released in order to remove the component supply unit 5 from the feeder base, the power supply to the component supply unit 5 is cut off, and this cut-off state is not illustrated. The control device can detect this, and conversely, when the component supply unit 5 is inserted and attached to the feeder base and the connectors are connected to each other, power is supplied to the component supply unit 5 and this supply state is determined. The control device can detect this.

  Each of the component supply devices 3A, 3B, 3C, and 3D is disposed such that the tip on the component supply side faces the component suction / extraction position PU that is the component extraction region of the mounting head 6.

  Between the front-side component supply devices 3B and 3D and the rear-side component supply devices 3A and 3C, a supply conveyor and a first positioning unit constituting the substrate transfer device 8 that transfers the printed circuit board P as a substrate An intermediate conveyor, a second positioning portion, and a discharge conveyor are provided.

  The supply conveyor conveys the printed circuit board P received from the upstream to the first positioning unit, and after mounting electronic components on the substrate P positioned by a positioning mechanism (not shown) in each positioning unit, conveys it to the intermediate conveyor, After the printed circuit board P received from the intermediate conveyor is positioned by the positioning mechanism in the second positioning portion and the electronic component is mounted, it is transported to the discharge conveyor and then transported to the downstream device.

  Each beam 10 that moves along the guide rail 9 by the Y-axis drive motor 11 in the Y direction is provided with a mounting head 6 that is moved by the X-axis drive motor 13 in the longitudinal direction, that is, in the X direction. Is provided with a suction nozzle 7 which is a plurality of component take-out tools. The mounting head 6 is equipped with a vertical axis drive motor 14 for moving the suction nozzle 7 up and down, and a θ-axis drive motor 15 for rotating around the vertical axis. Therefore, the suction nozzle 7 of the mounting head 6 can move in the X direction and the Y direction, can rotate about the vertical axis, and can move up and down.

  Reference numeral 4 denotes a substrate recognition camera for recognizing the position of the printed circuit board P, which is fixed to the mounting head 6 and images a positioning mark attached to the printed circuit board P. Reference numeral 12 denotes a component recognition camera that captures an image of the electronic component in order to recognize the position of the electronic component with respect to the suction nozzle 7 in terms of the XY direction and the rotation angle.

  The storage tape CX will be described with reference to FIG. 2 which is a perspective view of the storage tape CX. In this storage tape CX, an electronic component D is stored in a storage recess Cb which is an electronic component storage recess formed at predetermined intervals on the carrier tape Ca, and the cover tape Cc is covered with the carrier tape so as to cover the storage recess Cb. Bonded on Ca. The carrier tape Ca has feed holes Cd formed at predetermined intervals.

  Further, as shown in FIG. 3, the adhesive portion Ce of the cover tape Cc (the portion where the cover tape Cc is bonded (fused) and fixed to the left and right of the storage recess Cb) depends on the size of the electronic component to be loaded. Its position is different. That is, the storage tape CX shown in FIGS. 3A (the left part of FIG. 3) and (A) (the right part of FIG. 3) is a paper tape having a width of 8 mm, but FIG. The large component storage tape CX has a large storage recess Cb, so that the adhesive portion Ce applied along the direction of travel is located on the outer side, and FIG. 3 (a) shows the small component storage tape CX. And since the said storage recessed part Cb is also small, the adhesion part Ce is also located inside.

  Next, based on FIG. 4 which is a schematic side view of the component supply unit 5 and FIG. 5 which is a schematic plan view of the component supply unit 5, the configuration of the component supply unit 5 arranged in parallel on the feeder base will be simply described. Explained. First, the component supply unit 5 introduces a storage tape CX wound around a storage tape reel (not shown) rotatably mounted on the component supply devices 3A, 3B, 3C, and 3D through a guide passage. (Tape introduction part).

  This tape introduction mechanism is a tape introduction drive source that is provided at the intermediate portion between a DC motor 17 that is an introduction motor provided with a gear 18 on its output shaft 16 and a rotary shaft 20 provided with a gear 19 that meshes with the gear 18. A worm wheel 22 that meshes with the provided worm gear 21 and a feed hole Cb formed on the storage tape CX pressed by the tape pressing member 24 from above is engaged with a tape feed tooth formed on the outer peripheral portion of the storage tape CX. The first sprocket 23 is configured to transmit. A first detection sensor 25 is a sensor for detecting the storage tape CX introduced into the component supply unit 5. The tape pressing member 24 is rotatable and includes a roller 24A that supports the storage tape CX.

  Reference numeral 27 denotes a second sprocket, and the second splot 27 is responsible for supplying the storage tape CX to the tape processing unit 28 described later. Reference numeral 29 denotes a third sprocket for moving the storage tape CX forward so as to cut open the cover tape Cc of the storage tape CX by a cutter 30 provided in the tape processing unit 28.

  Hereinafter, the cutter 30 will be described in detail with reference to FIGS.

That is, the bottom surface 1 is formed with a blade portion 101 at the tip portion of the cutter 30, and the blade portion 101 is directed from the upstream side in the feeding direction of the storage tape toward the downstream side, and obliquely upward from the lower part of the tip. It is formed toward. Further, the blade portion 101 is formed so as to gradually become thicker from the tip, and the tip portion of the blade portion 101 is subjected to C chamfering processing on the upper and lower sides with respect to the shape before processing indicated by broken lines 112 and 113 in FIG. Yes.
03, a trapezoidal bottom C chamfered surface (hereinafter referred to as a bottom surface) 104 is formed upward toward the tip of the blade, and the bottom surface 104 is indicated by a broken line on the bottom surface as shown in FIG. The extension line 112 has a C-chamfered shape. In addition, an isosceles triangular upper C chamfering surface (hereinafter referred to as an upper processing surface) 105 is formed on the upper portion of the tip portion downward toward the tip of the blade. That is, the upper processing surface 105 illustrated in FIG. 11 and the like is a square blade portion 102 in which a flat blade and a sharp blade on the upper side are formed in a square shape. The processing surface 105 has a shape formed by chamfering an extension line 11 3 indicated by a broken line of the square blade portion 102 as shown in FIG.

  The tip of the cutter 30 is formed with a small dimension 106 that is horizontal in a direction orthogonal to the longitudinal direction (feeding direction of the storage tape).

  The shape of the edge 106 may be a shape of a horizontal sharp blade, but may be a so-called R shape in which a vertical cross section in the cutter longitudinal direction is rounded, and the R diameter may be small.

  4 is a servo motor. A belt 35 is stretched between a pulley provided on the output shaft 33 and a pulley provided on the rotary shaft 34, and when the servo motor 32 rotates forward, The rotating shaft 34 rotates via the output shaft 33 and the belt 35.

  Therefore, when the rotating shaft 34 rotates intermittently, the second sprocket 27 and the third sprocket 29 provided with the worm wheels 39 and 40 meshing with the worm gears 37 and 38 provided in the intermediate portion of the rotating shaft 34 are intermittently respectively provided. It will rotate. That is, the tape feed teeth formed on the outer peripheral portions of the second sprocket 27 and the third sprocket 29 are engaged with and engaged with the feed hole Cb formed in the storage tape CX pressed from above by the suppressor 43, and the rotation shaft 34. Is rotated, the second sprocket 27 and the third sprocket 29 are rotated, and the storage tape CX can be intermittently fed.

  A second detection sensor 44 is a sensor for detecting the introduced storage tape CX. When the storage tape CX is loaded into the component supply unit 5, when the feed hole Cd of the storage tape CX is fitted from the first sprocket 23 to each tape feed dog of the second sprocket 27 (transfer due to speed difference). In order to ascertain the position of the end of the storage tape CX with certainty, the play loss of the second sprocket 27 and the third sprocket 29 is considered. The second detection sensor 44 is arranged to control so as to decelerate and stop when the leading end of the storage tape CX is detected.

  In addition, since the space | interval of the 1st sprocket 23 and the 2nd sprocket 27 is large, the fitting operation | movement of the tape feed dog of both the sprockets 23 and 27 will be influenced by the accumulated pitch error of each feed hole Cd of the storage tape CX. Therefore, the rotation speed of the first sprocket 23 is set to a low-speed rotation that is slightly slower than the rotation speed of the second sprocket 27. Further, in order to reduce the deformation of the feed hole Cd that affects the feed position accuracy of the storage tape CX, the tape feed tooth shape of the first sprocket 23 is a round tooth shape, and the feed hole Cd is in the initial state. The second sprocket 27 and the third sprocket 29 can be carried forward without being deformed.

  Further, the second sprocket 27 and the third sprocket 29 are arranged as close as possible so that the span is not affected by the accumulated pitch error, and the acceleration / deceleration control, speed control, and torque control required in the tape processing sequence can be performed. As described above, the servo motor 32 is employed and the operation is performed by the same drive source.

  Reference numeral 50 denotes a guide chute fixed to the main body 5A of the component supply unit by, for example, a fixing bolt (not shown). The storage tape CX is always pressed against the guide chute 50 from above to feed the storage tape CX. The suppressor 43 acts so that the feed hole Cd of the storage tape CX does not come off from the tape feed teeth of the second sprocket 27 and the third sprocket 29 so as not to move up and down, and the urging force of the suppressor 43 causes the tape processing unit. 28 presses the storage tape CX from above.

Reference numeral 53 denotes a leading end guide for guiding and discharging the storage tape CX sent by the third sprocket 29, and is provided on the leading end side of the component supply unit 5 (see FIG. 4).
The structure for discharging the storage tape CX of the tip guide 53 will be described in detail with reference to FIGS. The storage tape CX discharged through the front end guide 53 drops and passes through the tape discharge guide 155 provided in the apparatus main body 2 of the electronic component mounting apparatus 1 and is guided and guided to the cutter apparatus 160. The tape discharge guide 155 is a hollow box, the cutter device 160 side provided in the apparatus main body 2 is opened, and the storage tape CX is dropped to the cutter device 160 from the opening, and the upper opening 161 is formed at the upper part. Is opened so that the tip guide 53 can enter.
The tape discharge guide 155 includes a front side wall 162 on the component supply unit 5 side and a back side wall 163 on the opposite side. The front side wall 162 and the back side wall 163 extend across the plurality of component supply units 5 in a direction perpendicular to the paper surface of FIG. That is, it extends over the entire region of the component supply device 3A, etc., and both ends of the front side wall 162 and the back side wall 163 are further connected by side walls, and the tape discharge guide 155 has a rectangular box shape with a horizontal cross section. Yes.

  The cutter device 160 cuts the storage tape CX in a horizontal direction, that is, a direction perpendicular to the longitudinal direction of the tape that hangs down, and cuts the storage tape CX that has been dropped at a predetermined timing into a short length.

  As shown in FIGS. 20 to 24, the tip guide 53 includes a chute block 164 and a guide plate 165 attached so as to cover the chute block 164 from above and from the side, and the guide is placed on the chute surface 166 above the chute block 164. A tape guide gap 167 is formed between the plate 165. A relief groove 168 is formed below the tape guide gap 167 through which a component storage portion of the embossed tape (for example, below the right chute in FIG. 24) can pass. In addition, a partition wall 169 protrudes from the upper center of the chute block 164 and guides the two storage tapes CX so as not to approach the other party when passing through the chute surface 166 in parallel. The component supply unit 5 is configured to send two storage tapes CX individually in parallel, and includes the third sprocket 29, the servo motor 32, the first sprocket 23, the DC motor 17 and the like shown in FIG. Two sets of storage mechanisms for the storage tape CX are formed on the same main body.

The tip guide 53 is attached to the component supply unit 5 so that the storage tape CX can move on the chute surface in which the chute surface 166 communicates with the guide chute 50 upstream from the chute surface and is connected without a step. The suppressor 43 that moves up and down with respect to the guide chute 50 is provided with a top plate 171 in the entire tape feed direction so that the end surface of the protruding portion of the tip faces the upper surface of the guide plate 165 of the tip guide 53. The chute side plate 172 is fixed to the main body of the component supply unit 5 in which the guide chute 50 is formed so as to cover the side of the chute surface so that the storage tape CX does not protrude.
The chute surface 166 and the guide plate 165 in the distal end guide 53 are inclined downward in the right direction in FIG. 20, and the storage tape CX to be guided is changed downward while the inclination angle changes in the middle. The distance between the chute surface 166 and the upper surface of the guide plate 165 (the distance between the tape guide gaps 167) is almost uniform both in the tape traveling direction and in the width direction perpendicular thereto, and is about 1.2 to 1.5 mm. An interval is desirable. The component supply unit 5 of the present embodiment is configured to feed a storage tape CX having a width of 8 mm, and is a so-called so-called carrier tape made of paper (portion where the cover tape is pasted and where the component is stored). In the case of a paper tape storage tape CX (for example, the one shown on the left chute surface 166 in FIG. 24), the maximum thickness may be about 1.1 mm, and this tape is pushed from behind to the next storage tape CX. In this case, the interval is such that the new storage tape CX from behind and the storage tape CX out of components that are ejected do not overlap. The thickness above the chute surface 166 of the embossed tape is even thinner than this, and does not resist passage through.

  The lower end of the front end guide 53, that is, the position of the outlet of the storage tape CX is set to a distance that is not close to the upper end of the front side wall 162 of the tape discharge guide 155. If the gap between the front side wall 162 and the front end guide 53 is large, the upper end portion of the storage tape CX may come out to the front side and may be caught, but this is to prevent this. The component supply unit 5 has a mounting rail 174 formed in a lower portion thereof mounted on and fixed to a guide guide 176 of a feeder base 175 provided in the component supply device 3A and the like by sliding horizontally. The supply devices 3A, 3B, 3C, and 3D are attached so as to have a constant height with respect to the height of the device main body, and the feeder base 175 has a predetermined height with respect to the tape discharge guide 155. The position of the tip guide 53 can be determined and fixed with respect to the supply unit so that it does not hit the front side wall 162 when the component supply unit 5 is attached. In this way, the outlet side (the right side in FIG. 20) of the tape guide gap 167 is in a position where it enters the tape discharge guide 155 below the upper end of the back side wall 163. Further, the outlet of the tape guide gap 167 is set in the immediate vicinity of the back side wall 163, the position where the storage tape CX goes out from the front end guide 53 is a position close to the back side wall 163, and the upper opening 161 is the width of the component supply unit 5. In this case, the tip guide 155 is covered between the front side wall 162 and the back side wall 163. Accordingly, the storage tape CX is reliably discharged into the tape discharge guide 155 without staying at the entrance of the opening 161. When the outlet of the tape guide gap 167 is close to the back side wall 163, the storage tape CX does not bend in the tape guide gap 167, so that the resistance does not increase against the guide plate 165 by bending. It is preferable that the outlet of the tape guide gap 167 be positioned on the back side from the center of the front side wall 162 and the back side wall 163. In this way, the storage tape CX guided from the tip guide 53 can be surely discharged into the tape discharge guide 155, and then dropped and cut by the cutting device 160. The tape discharge guide 155 needs to discharge not only the 8 mm tape component supply unit 5 for supplying relatively small components but also the tape fed from the component supply unit 5 for handling relatively large components, so that the front side wall 162 is discharged. The distance between the upper side wall 163 and the back side wall 163 is set to a certain size, and a distance that also has a width (including the vertical direction) of the upper opening 161 is required. Further, the tape discharge guide 155 and the cutter device 160 may be provided in the component supply devices 3A and 3B.

  Further, a first component dropping device 91 according to the present application is provided on the downstream side (left side in FIG. 4) of the tape pressing member 24 in the tape feeding direction (the direction from the right side to the left side in FIG. 4). Yes.

  Hereinafter, the first component dropping device 91 will be described with reference to FIGS.

  92 and 93 are a pair of support plates attached to both sides of the guide chute 50 with screws, 94 is a support shaft provided on the upper portions of the support plates 92 and 93, and 95 is supported by the support shaft 94 penetrating therethrough. This is a roller support plate that is rotatably supported with respect to the shaft 94. The roller support plate 95 is provided obliquely downward from the support shaft 94 in the moving direction of the storage tape CX (the direction from right to left in FIG. 7). Reference numerals 96 and 97 denote a first collar and a second collar as spacers that define the distance between the support plate 92 and the support plate 93 and the roller support plate 95. With these first and second collars 96 and 97, the distance between the roller support plate 95 and the support plate 03 is perpendicular to the transport direction of the storage tape CX supported on the upper surface 50A of the chute 50 (the tape width). Direction) is substantially equal to the size of the storage recess Cb. In FIG. 7, the storage recess Cb formed in the storage tape CX with an interval in the tape feed direction and the electronic component D stored in the storage recess are stored in the storage recess Cb positioned below the roller 120 and Only the electronic component D is shown, and the upstream and downstream storage recesses Cb and the electronic component D are not shown.

  Reference numeral 98 denotes a roller support shaft provided at a lower portion of the roller support plate 95, and a roller 120 is rotatably provided at a distal end portion 99 provided at the distal end of the roller support shaft 98. The roller 120 is sandwiched between an annular inner diameter portion 122 into which the tip end portion 99 is inserted, an annular outer diameter portion 123 provided outside the inner diameter portion 122 with a space therebetween, and the outer diameter portion 123 and the inner diameter portion 122. And a plurality of balls 124. The outer diameter portion 123 is formed with a flange 126 that protrudes in the diametrical direction of the outer diameter portion from the outer peripheral surface 125 that is the periphery of the outer diameter portion 123 so as to face the storage recess Cb. Moreover, the width | variety of the direction orthogonal to the feed direction of the storage tape CX of the collar 126 is smaller than the width | variety of the storage recessed part Cb. The entire roller 120 may be formed to have the same width (thickness) as that of the flange 126.

  Reference numeral 127 denotes a third collar through which the roller support shaft 98 penetrates. The third collar restricts the roller 120 from approaching the roller support plate 95. Reference numeral 128 denotes, for example, a torsion spring that is provided on the support shaft 94 and applies a force in the direction of arrow A shown in FIG. A torsion spring (hereinafter referred to as a spring) 128 includes a central portion 130 wound around the first collar 96, one end portion 131 that extends from the central portion 130 to one side and has a slightly bent tip portion, and a central portion. 110 and the other end portion 132 that extends from 110 to the other end and is bent at a right angle in the direction along the support shaft 94. The one end 131 is supported by a first support piece 133 formed by bending a part of the upper portion of the support plate 92 at, for example, a right angle inside, and the other end 132 is formed on the roller support plate 95. A rotational force is applied to the roller support plate 95 so as to rotate in the direction indicated by the arrow A by a spring 128.

  Accordingly, the lower end of the flange 126 presses the upper surface of the storage tape CX that has moved on the chute 50, that is, the cover tape Cc from above.

  Similarly to the first support piece 133, 134 is a second support piece formed by bending a part of the upper part of the support plate 92 at, for example, a right angle inside, and the storage tape CX is placed under the roller 120. When there is no roller, the roller support plate 95 is rotated in the direction indicated by the arrow A by the spring 97, but when the lower end of the roller 120 is positioned slightly below the upper surface 50 </ b> A of the chute 50, the upper edge 95 </ b> B of the rotor support plate 95. Hits the second support piece 134 and further rotation of the roller support plate 95 is restricted. As a result, when the storage tape is not on the chute 50, the roller 120 is held in a state where its lower end is slightly below the upper surface of the chute 50.

  A concave portion 135 that is recessed upstream is formed at the upstream end of the support plates 92 and 93 in the tape feeding direction. Then, each pin 136 protruding from the left and right side walls of the component presser 24 enters the recess 135, and the pin 136 is stopped by the recess 135.

  A tape guide piece 150 is provided on the downstream side of the roller 120. The tape guide piece 150 includes a guide piece 152 that is inclined downward in the tape moving direction from the tape inlet 151, and a pressing piece 153 that is bent at the lower end of the guide piece 152 and extends horizontally downstream. The storage tape CX that has passed through 120 is guided by the guide piece 152, pressed by the pressing piece 153, and sent downstream.

  Further, as shown in FIG. 4, the storage tape CX between the first component dropping device 91 and the cutter 30 on the downstream side in the feeding direction of the storage tape from the handle 46 provided in the component supply unit 5. A second component dropping device 141 according to the present application is provided in the middle of the movement path.

  Hereinafter, the second component dropping device 141 will be described.

  The mechanism of the second component dropping device 141 is different from that of the first component dropping device 91 in that the pair of support plates 142 and 143 attached to both sides of the guide chute 50 with screws or the like is different from the first component dropping device 91. This is the same, and will be described based on FIG. 8 and FIG. 9 used to describe the first component dropping device 91. Moreover, in FIG. 9, the same code | symbol is attached | subjected to the thing and mechanism similar to the 1st component dropping apparatus 91. FIG.

Between the support plate 142 and the support plate 143, similarly to the first component dropping device 91,
A support shaft 94 is provided, and a roller support plate 95 is rotatably supported on the support shaft 94. The roller support plate 95 is provided on the support shaft 94 so as to move obliquely downward in the moving direction of the storage tape CX (the direction from right to left in FIG. 7). Due to the first and second collars 96 and 97 serving as spacers that define the distance between the support plate 92 and the support plate 93 and the roller support plate 95, the distance between the roller support plate 95 and the support plate 03 can be set to the storage tape CX. Is substantially equal to the size of the storage recess Cb in a direction (tape width direction) orthogonal to the transport direction.

  A roller 120 is provided at the tip 99 of the roller support shaft 98 provided at the lower portion of the roller support plate 95. The roller 120 is sandwiched between an annular inner diameter portion 122 into which the tip end portion 99 is inserted, an annular outer diameter portion 123 provided outside the inner diameter portion 122 with a space therebetween, and the outer diameter portion 123 and the inner diameter portion 122. And a plurality of balls 124. The outer diameter portion 123 is formed with a flange 126 protruding from the outer peripheral surface 105 of the outer diameter portion 123 in the diameter direction of the outer diameter portion.

  Further, the third collar 127 through which the roller support shaft 98 penetrates restricts the roller 120 from approaching the roller support plate 95. Further, a torsion spring (hereinafter referred to as a spring) 128 that is provided on the support shaft 94 and applies a force to the roller support plate 95 in the direction of arrow A shown in FIG. A central portion 130 wound around the center portion, one end portion 131 extending from the central portion 130 to one side and slightly bent at the front end portion, and extending from the central portion 110 to the other end, the front end being perpendicular to the direction along the support shaft 94. The other end portion 132 is bent and is supported in the same manner as the first component dropping device 91. The roller support plate 95 is rotated by a spring 128 so as to rotate in the direction indicated by the arrow A. Have joined.

  Accordingly, the lower end of the flange 126 presses the upper surface of the storage tape CX that has moved on the chute 50, that is, the cover tape Cc from above.

  Reference numeral 134 denotes a second support piece formed by bending a part of the upper portion of the support plate 92 at, for example, a right angle inside. When the storage tape CX is not present under the roller 120, the roller support plate 95 is a spring 97. Is rotated in the direction indicated by the arrow A, but when the lower end of the roller 120 is positioned slightly below the upper surface 50A of the chute 50, the upper edge 95B of the rotor support plate 95 hits the second support piece 134, and the roller Further rotation of the support plate 95 is restricted. As a result, when the storage tape CX is not on the chute 50, the roller 120 is held in a state where the lower end thereof is slightly below the upper surface of the chute 50.

  Further, on the downstream side of the cutter 30 of the tape processing unit 28, a component extraction opening 65 having a larger plane area than the electronic component D is opened (see FIG. 6), and is placed in the storage recess Cb along the guide surface 64. At a component suction / extraction position PU opened wider than the width of the stored electronic component D, the suction nozzle 7 provided in the mounting head 6 causes the electronic component D in the storage recess Cb to pass through the component extraction opening 65. Can be adsorbed and removed. The storage tape CX is positioned at the component suction / extraction position PU by rotating the third sprocket 29 engaged with the storage tape CX.

  However, although the guide surfaces 64 cannot be formed in the part where the component extraction opening 65 is formed, the guide surfaces 64 are formed again on the left and right sides further downstream from the component extraction opening 65 (FIG. 6). In the meantime, the guide surface 64 will not be formed (see FIG. 14).

  An information identifying unit 66 for type identification is provided in the downstream portion 28B of the tape processing unit 28. The information identifying unit 66 includes an information identifying unit 67 for identifying the operator of the electronic component mounting apparatus 1, and an electronic identification unit 67. It is comprised from the information identification part 68 of the component mounting apparatus 1. FIG. The information identifying section 67 for identifying the worker is engraved with its type, for example, “W8S” so that the operator can visually identify the type of the tape processing unit 28. The information identification unit 68 of the electronic component mounting apparatus 1 is binarized information (bits) using four dots, that is, the type (type) of the tape processing unit 28 in which black circles are printed in the range of 0 to 15. Is attached so that it can be identified.

  As described above, the information identification unit 68 is binarized information (bits) using four dots. However, information that can be directly recognized or barcode information (one-dimensional or two-dimensional) is used. It may be attached or a recording medium such as a memory tag or a mu chip may be embedded. When these media are used, in addition to the type information of the tape processing unit 28, individual management can be performed in addition to the unique management code and information.

  The electronic component targeted by the tape processing unit 28 has a dimension in the X direction of 10.5 mm and a dimension in the Y direction of 10.0 mm.

  As shown in FIGS. 4 and 5, an operation panel 78 is provided on the upper surface of the handle 46 of the component supply unit 5. The operation panel 78 has an arrangement number (lane number) of the component supply unit 5. A lane number selection button 78A for selection, and a display that increases the lane number by 1 each time the left portion of the lane number selection button 78A is pressed and decreases the lane number by 1 each time the right portion is pressed. A section 78B, a feed button 78C, a return button 78D, and a loading button 78E are provided (see FIG. 18).

  Therefore, when the component supply unit 5 is removed from or attached to the feeder base described above, the arrangement number (lane number) of the component supply unit 5 is pressed by the lane number selection button 78A while viewing the display unit 78B. It can be selected (changed) based on this.

  Next, an operation for loading the storage tape CX into the component supply unit 5 will be described. First, the tape pressing member 24 is removed, the tip of the storage tape CX is placed on the guide passage, the tape feed dog of the first sprocket 23 is fitted into the feed hole Cb of the storage tape CX, and then the tape pressing member is placed. The member 24 is set.

  Then, when the operator presses the loading button 78E of the operation panel 78, the control device (not shown) controls the DC motor 17 if the first detection sensor 25 and the second detection sensor 44 do not detect the storage tape CX. The storage tape CX is controlled so as to be driven only for a period of time, and is sequentially moved downstream (backward) in the component supply unit 5 by the rotation of the first sprocket 23.

  With this movement, when the predetermined time has elapsed, the driving of the DC motor 17 is stopped. When the first detection sensor 25 detects the leading end of the storage tape CX, the driving of the DC motor 17 and the servo motor 32 is started.

  Hereinafter, the operation of the first component dropping device 91 accompanying the movement of the storage tape CX after the front end of the storage tape CX has passed under the tape pressing member 24 will be described.

  First, when the end of the storage tape CX does not reach the roller 120 and there is no storage tape CX under the roller 120, 95 is rotated in the direction of arrow A by the force of the spring 128. This rotation stops when the upper edge 95B of the roller support plate 95 is in contact with the second support piece 134, and further rotation of the roller support plate 95 is restricted.

  Then, the tip of the storage tape CX reaches the roller 120, hits the roller 120, the storage tape CX moves downstream, and when the tip of the storage tape CX hits the roller 120, it moves while pushing the roller 120. As a result, the roller support plate 95 rotates in the direction opposite to the arrow A via the roller 120, and when the storage tape CX reaches the lower end of the roller 120, it no longer rotates. Further, the flange 126 hits the upper surface of the cover tape Cc covering the component recess Cb, and presses the cover tape Cc slightly downward.

  Note that when the tip of the storage tape CX that has been moved by being pushed by the first sprocket 23 reaches the roller 120 and hits the roller 120, the tip of the storage tape CX becomes a roller by the rotatable roller 120. Since the storage tape CX is guided smoothly under the roller 120 and passes under the roller 120 and further downstream, the storage tape CX can be prevented from buckling on the downstream side of the first sprocket 23, and the storage tape CX can be avoided. Can be smoothly sent downstream. As the storage tape CX moves, the roller 120 rotates clockwise in FIG. 7, and the storage tape CX is smoothly fed downstream.

  Thereafter, the flange 126 presses the cover tape Cc downward through the roller support plate 95 by the force of the spring 128 at the substantially central position (see FIG. 8) of the storage recess Cb in the tape width direction. Further, since the width of the hook 126 in the direction perpendicular to the feeding direction of the storage tape CX is smaller than the width of the storage recess Cb, the lower end of the hook 126 can be positioned below the upper surface of the storage recess Cb. The cover tape covering the cover is slightly deformed downward by pressing with the flange 126. Then, when the electronic component D in the storage recess 126 that has passed under the bag 126 is attached to the upper part of the side surface in the storage recess Cb, or when it is attached to the lower surface of the cover tape Cc, the electronic component D is The cover 126 is pushed downward by the flange 126 through the cover tape Cc, and as a result, falls onto the bottom cd of the storage recess Cb. Therefore, the electronic component D can be prevented from moving downstream in a state where it is attached to the upper portion of the side surface in the storage recess Cb or a state where it is attached to the lower surface of the cover tape Cc.

  Thereafter, the storage tape CX moves further downstream while being pressed by the flange 126, and when the partition portion Ce positioned between the storage recesses Cb aligned in the moving direction of the storage tape is positioned below the roller 120, the partition portion Since Ce is harder than the cover tape Cc that covers the storage recess Cb, it does not deform downward like the cover tape Cc, and when the partition portion Ce is positioned below the flange 126, the position of the roller 120 is such that the storage recess Cb It is supported above when it is located below 126. With the movement of the storage tape CX, the storage recesses Cb and the partition portions Ce are alternately positioned under the flange 126, so that the flange 126 moves up and down with the movement of the storage tape CX and vibrates. The vibration is transmitted through the cover tape Cc covering the storage recess Cb to the electronic component attached to the upper part of the side surface in the storage recess Cb or to the electronic equipment attached to the lower surface of the cover tape Cc, and the electronic component is more reliably dropped. Can be made.

  Thus, the storage tape CX moves downstream in a state where the electronic component is falling on the bottom cd of the storage recess Cb.

  First, the storage tape CX, the tip of which has been detected by reaching the first detection sensor 25, gradually moves so as to be pushed downstream by the rotation of the first sprocket 23 driven by the DC motor 17.

  When the storage tape CX reaches the second component dropping device 141 provided downstream, as with the first component dropping device 91, an electronic component or cover attached to the upper portion of the side surface in the storage recess Cb. The electronic equipment attached to the lower surface of the tape Cc is dropped by the roller 126. That is, in FIG. 9, when the tip of the storage tape CX that has moved from right to left hits the hook 126, the roller 120 moves obliquely upward as indicated by the arrow B around the support shaft 94. . Thereafter, the storage tape CX is pressed from above by the flange 126 of the roller 120 in the same manner as the first component dropping device 91.

  Accordingly, the electronic component attached to the upper portion of the side surface in the storage recess Cb or the electronic equipment attached to the lower surface of the cover tape Cc is pressed downward by the ridge 126 through the cover tape Cc, and further, The storage recess Cb and the partition portion Ce are alternately pressed by the flange 126, and the flange 126 oscillates up and down. This vibration is transmitted to the electronic component attached to the upper portion of the side surface in the storage recess Cb or the electronic component attached to the lower surface of the cover tape Cc via the cover tape Cc covering the storage recess Cb, and the first component dropping device. Electronic components that have not dropped when passing through 91 can be reliably dropped by the second component dropping device 141.

  The storage tape CX that has passed through the second component dropping device 141 moves further downstream and reaches the tape processing unit 28. The storage tape CX moves downstream in a space below the tape processing unit 28.

  Then, the storage tape CX is moved forward by the first sprocket 23, the second sprocket 27, and the third sprocket 29.

  Then, the moving operation is continued according to a preset feed amount, and when the second detection sensor 44 detects the leading end of the storage tape CX during this movement, the driving of the DC motor 17 is stopped and the servo motor 32 is forced. Is decelerated to stop. In this case, the DC motor 17 and the servo motor 32 are abnormally stopped when the second detection sensor 44 cannot detect the leading end of the storage tape CX despite the above-described preset feed amount. .

  Subsequently, in consideration of the overrun amount of the storage tape CX when the servo motor 32 decelerates and stops as described above, the second detection sensor 44 does not detect the reverse rotation operation by the minimum pitch feed at the front end of the storage tape CX. Repeat until the end position of the storage tape CX is determined. That is, the tip position of the storage tape CX is determined by repeating the reverse rotation operation and the stop operation of the servo motor 32 with the minimum pitch.

  The first sprocket 23 is provided with a one-way clutch and does not rotate in reverse, but the return tape is small and the storage tape fitted to the feed teeth of the second sprocket 27 due to the low tooth height of the first sprocket 23. CX is slid backward by the thrust of the servo motor 32.

  The drive of the servo motor 32 is controlled so that the leading end of the storage tape CX is fed at a high speed to the position immediately before the blade of the cutter 30 by a predetermined amount of one-time feeding operation. That is, by determining the tip position of the storage tape CX, the storage tape CX is fed at a high speed according to the design dimensions up to the position immediately before the blade of the cutter 30.

  Then, the tip of the storage tape CX moves to a zone where the cover tape Cc is cut by the cutter 30, and the cover tape Cc is cut and divided. The operation at this time will be described with reference to FIGS.

  As shown in FIG. 15, when the storage tape CX is fed in the arrow direction H, the blade tip (the most advanced portion) of the cutter 30 abuts against the leading end surface 111 of the storage tape CX.

  FIG. 15 shows a state in which the edge 106 at the blade tip of the cutter 30 abuts on a substantially boundary portion 110 between the cover tape Cc and the carrier tape Ca. When the storage tape CX further moves in the arrow direction H from the state of FIG. 15, the edge 106 divides the substantially boundary portion 110 between the cover tape Cc and the carrier tape Ca vertically, and the bottom processing surface 104 is the carrier tape. The cutter 30 abuts on the corner of the end face of Ca and rides on the upper surface of the carrier tape Ca. When the cutter 30 rides on the upper surface of the carrier tape Ca, the cutter 30 is raised by the height difference between the edge 106 and the bottom surface 103, and the tape processing unit 28 is also raised accordingly. As a result, the tape processing unit A slight gap is formed between the lower surface of the portion upstream of the cutter 30 at 28 and the storage tape CX. Further, the tape processing unit 28 is inclined around the component extraction opening 65 of the downstream portion 28B of the tape processing unit 28 downstream of the cutter 30, so that there is almost no gap between the lower surface of the downstream portion 28B and the carrier tape Ca. The carrier tape Ca is pressed from above by the tape processing unit 28.

  Further, the cover tape Cc of the storage tape CX that has reached the cutter 30 moves obliquely upward on the upper processing surface 105 without being cut, and the state shown in FIG. 16 is obtained.

  That is, since the cutter 30 is pressed downward by the spring together with the suppressor 43, it rises against this pressing force and rides on the upper surface of the carrier tape Ca. At this time, the end edge 106 comes into contact with the center portion in the width direction orthogonal to the feed direction H of the cover tape Cc. However, since the end edge 106 has a slight dimension in the horizontal direction and is linear, It can be avoided that 106 breaks through and cuts the cover tape Cc. As a result, the edge 106 and the upper processing surface 105 move relative to the storage tape CX while pushing up the cover tape Cc. The left end portion of the cover tape Cc in FIG. 16 is not cut at least on the upper processing surface 105 but is further raised from the upper end of the upper processing surface 105 and is cut when reaching the upper portion of the square blade 102 to some extent. .

  The cover tape Cc of FIG. 16 shows a state where it remains on the cutter blade 101 without being cut, and is not shown in FIG. That is, since the cover tape Cc is bonded to the carrier tape Ca on both sides of the storage recess, the tension increases each time the height lifted by the cutter blade 20a increases. A portion of the cover tape Cc where a predetermined or higher tension is applied to the square blade 102 is cut and divided by the square blade 102.

  FIG. 15 shows a case where the height of the edge 106 at the tip of the cutter 30 is the boundary between the cover tape Cc and the carrier tape Ca, and the edge 106 hits the leading end surface 11 of the storage tape CX at this boundary. Depending on the type of CX, the thickness of the cover tape Cc may differ. The cutter 30 is attached to the tape processing unit 28 pressed downward, and until the edge 106 of the storage tape CX moved from the upstream contacts the cutter 30, the position where the cutter contacts (the edge of the cutter) ) On the upstream side, the storage tape CX is pressed downward by the tape processing unit 28, and there is almost no gap between the storage tape CX and the tape processing unit 28. For this reason, the heights of the upper surfaces of the cutter 30 and the storage tape CX are always kept in a fixed positional relationship.

  Thus, for example, as shown in FIG. 15, the edge 106 of the blade of the cutter 30 abuts on the same height position of the leading end surface 11 of the storage tape CX. Therefore, when the cover tape Cc is thinner than FIG. 15, as shown in FIG. 17, the end of the cutter blade 101 is located slightly below the boundary portion (interlayer) 110 between the cover tape Cc and the carrier tape Ca. The edge 106 hits the end surface of the carrier tape Ca.

  In this case, since the carrier tape Ca is somewhat rigid and the cover tape Cc is not rigid, the bottom processed surface 104 is pressed against the inside of the corner of the carrier tape Ca by the movement of the storage tape CX in the direction of arrow H. The cutter 30 receives an upward force that is greater than the downward force. Accordingly, the cutter 30 moves up to a position where the bottom surface 103 rides on the upper surface of the carrier tape Ca while the edge 106 of the blade portion 101 scrapes the carrier tape Ca upward.

  Similarly, when the storage tape CX is an embossed tape in which the storage recess of the electronic component protrudes downward and the storage recess of the carrier tape is covered with the cover tape, the storage tape CX is moved by the movement of the storage tape in the downstream direction. When the bottom processing surface of is pressed against the inside of the corner portion of the carrier tape, the cutter receives an upward force larger than the downward force. Therefore, the cutter 30 moves up to a position where the bottom surface 103 rides on the upper surface of the carrier tape Ca while the edge 106 of the blade portion 101 scrapes the carrier tape Ca upward or bends it downward.

  In this ascending process, the upper processing surface 105 (or further the square blade portion 102) above the carrier tape Ca lifts the cover tape Cc as shown in FIG. The part 102 cuts the cover tape Cc as described above.

  As described above, since the bottom surface processing surface 104 is formed, the edge 106 of the cutter blade portion 101 remains stuck in the middle of the end surface of the carrier tape Ca even if the cover tape Cc has some variation in thickness. Thus, it is possible to prevent the cover tape Cc from buckling and becoming unable to cut the cover tape Cc, or the blade tip from being chipped.

  Even when the edge 106 that is the cutting edge of the cutter 30 hits the leading end surface 11 of the storage tape CX at a position slightly above the boundary between the cover tape Cc and the carrier tape Ca, the lower side of the end surface of the cover tape Cc The cover tape Cc can escape upward and the blade tip can enter underneath. Therefore, the cutter 30 may be provided in the tape processing unit 28 so that the position at which the edge 106 of the cutter 30 having the bottom surface processing surface 104 hits the storage tape CX is the height position at the approximate center of the variation allowable range. desirable.

  Further, in the storage tape CX, as shown in FIGS. 15 to 17, it is preferable not to store the electronic component D in the leading storage recess Cb.

  By doing in this way, when the edge 106 of the cutter 30 hits the leading end surface 111 of the storage tape CX, enters between the cover tape Cc and the carrier tape Ca from the end surface, and cuts open, in particular, the cutter 30 has a boundary portion. Also when it hits the part below 110, it can avoid that the cutter 30 hits an electronic component.

  Then, a pitch feed operation is performed a predetermined number of times to cue the position of the storage recess Cb that is second from the front end of the storage tape CX and stores the electronic component into the component extraction opening 65. A pitch feed operation is performed to send the electronic component to the component take-out opening 65.

  Thus, when the pitch feeding operation of the storage tape is performed, the electronic component is stored in the first component dropping device 91 or the second component dropping device before the storage recess Cb in which the electronic component is stored reaches the cutter 30. 141, since it falls to the bottom Cd of the storage recess Cb, when the storage recess Cb in which the electronic component is stored reaches the cutter 30, it is reliably avoided that the edge 106 of the cutter 30 hits the electronic component D. As a result, the storage tape CX can smoothly pass through the cutter 30 and move to the component take-out opening 65, so that supply of electronic components can be started smoothly and stable component supply can be achieved.

As described above, when the electronic component D is supplied from the storage tape CX by the component supply unit 5, the tape pressing member 24 is slid by the operator and the pin 13
6 is removed from the recess 135. Then, by moving the tape pressing member 24 upward, the storage tape CX can be removed from below the tape pressing member 24, and the removed storage tape CX is a roller 24 </ b> A provided on the upper part of the tape pressing member 24. Hung on.

  The storage tape CX hung on the roller 24A in this way moves obliquely from below the roller 120 of the first component dropping device 91 from the roller 24A. At this time, since the storage tape CX moves below the roller 120 while swinging up and down with the movement, the roller 120 also swings up and down due to the swing of the storage tape CX. For this reason, there is a possibility that the cover tape Cc may be insufficiently pressed by the flange 126 of the roller 120, and the electronic component attached to the upper portion of the side surface in the storage recess Cb or the electronic component attached to the lower surface of the cover tape Cc. However, there is a risk that it will not be reliably dropped by the trough 126. The electronic component that has not been dropped reaches the second component dropping device 141 provided downstream by the movement of the storage tape CX. When the storage tape moves horizontally on the chute 50, the cover tape Cc is moved by the flange 126 of the roller 120. And can be reliably dropped by the vibration of the flange 126 or the like.

  In addition, after the storage tape is removed, a replenishment storage tape is inserted under the tape presser member 24, inserted to a position where the tip is engaged with the teeth of the first sprocket 23, and the tape presser member 24 is returned to the original position. The replenishment storage tape is set. In this way, by setting the storage tape for replenishment in advance in the component supply unit 5, when the supply of the component from the preceding storage tape CX is completed, the replenishment storage tape is sent and the replenishment storage tape is supplied. The supply of parts from the storage tape can be started smoothly.

  The operation when the preceding storage tape CX has run out of parts will be described.

When the end of the preceding storage tape CX passes the first detection sensor 25, the first detection sensor 25 detects the absence of the tape and stores the state of the tape end passage in the memory of the component supply unit 5. Even in that case, the part D of the storage tape CX is not out of parts, and the suction nozzle 7 provided in the apparatus main body 2 of the electronic component mounting apparatus 1 continues to take out the part D. If the nozzle 7 cannot take out the part D and the suction nozzle 7 is taken out, but the detection of no part is detected continuously for a set number of times (for example, 3 times), the controller of the apparatus main body 2 determines that the control of the apparatus main body 2 The control device makes an inquiry to the component supply unit 5 and determines that the component is out when it is notified that the component supply unit 5 stores the state of passing the tape end. Then, the control device of the apparatus main body 2 issues a command to forcibly eject the storage tape CX to the control device of the component supply unit 5.
Then, the servo motor 32 rotates at a high speed in response to the command, and the storage tape CX is transported a predetermined distance to the position where it is disengaged from the third sprocket 29. The servo motor 32 is stopped by rotating it by a predetermined distance, and the storage tape CX passes through the front end guide 53 and the tape discharge guide 155 and remains at a position where the rear end is separated from the sprocket 32.
In this state, when the loading button 78E of the operation panel 78 is pressed, the replenishing storage tape CX that has been set in advance is automatically loaded in the same manner as described above, and the leading component storage position is the tape connection of the third sprocket. Located at the part removal position just before the joint. At this time, the leading end of the replenishing storage tape CX hits and pushes the rear end of the storage tape CX that has already been discharged. Thus, as shown in FIG. 22, the storage tape CX which is pushed out by the next storage tape CX and has run out of parts passes through the suppressor 43 and the tape guide gap 167 of the tip guide 53 and falls in the tape discharge guide 155. While passing. At this time, the succeeding tape CX and the preceding tape CX do not overlap in the leading end guide 53. The subsequent tape CX advances to some extent during loading, but also advances during intermittent feeding of normal part extraction, and eventually advances to a position where the leading end exits from the outlet of the leading end guide 53. At this time, the storage tape CX that is pushed out and is pushed out is completely discharged from the front end guide 53 and falls in the tape discharge guide 155 toward the cutter device 160 without being caught by the upper opening 161 or the like.

  The subsequent loading of the storage tape CX does not depend on the operation of the operation unit 78, but after the apparatus main body 2 determines that the parts are out of stock, it instructs the forced discharge of the storage tape CX and automatically starts the loading operation. May be. Even in this case, the preceding storage tape CX remaining off the sprocket 29 can be smoothly pushed out of the tip guide 53 and discharged by the subsequent storage tape CX that has been automatically loaded.

  Although the embodiments of the present invention have been described above, various alternatives, modifications, and variations can be made by those skilled in the art based on the above description. It encompasses alternatives, modifications or variations.

DESCRIPTION OF SYMBOLS 1 Electronic component mounting apparatus 5 Component supply unit 29 3rd sprocket 43 Suppressor 53 Tip guide 155 Tape discharge guide 160 Cutter apparatus 161 Upper side opening 162 Front side wall 163 Back side wall 167 Tape guide gap D Electronic component

Claims (3)

There is a component supply unit that intermittently moves the storage tape and supplies the electronic component stored in the storage recess of the storage tape to the component extraction position, and the electronic component supplied from the component supply unit is a substrate. In the electronic component mounting apparatus provided with a discharge guide for discharging the storage tape discharged from the component supply unit,
The component supply unit positions the storage tape engaged with the sprocket at the component take-out position by rotation of the sprocket, and a leading end guide that guides the storage tape sent downstream from the sprocket to the opening of the discharge guide. An electronic component mounting apparatus comprising:   2. The electronic component mounting apparatus according to claim 1, wherein the tip guide has guide gaps with a predetermined interval for guiding the storage tape. 3. The electronic component mounting apparatus according to claim 2, wherein the tip guide is provided so as to cover an opening of the discharge guide between a front side wall and a back side wall.

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