JP7198973B2 - Parts feeder - Google Patents

Description

The present invention relates to a component supply device that supplies components to a component mounting device.

2. Description of the Related Art As a component supply device that supplies components to a component mounting device, a tape feeder is often used that positions components at a component pick-up position by a component mounting mechanism by pitch-feeding a carrier tape containing components. A cover tape is affixed to the upper surface of the carrier tape to seal the recessed part containing the component. In the tape feeder, the cover tape is peeled off at the upstream side of the component pick-up position in the tape feeding direction to expose the component. A tape peeling mechanism is provided to allow the tape to be removed.

As a configuration of a tape peeling mechanism that automatically peels off the cover tape, there is known a configuration in which the cover tape is sandwiched between a pair of feed rollers and the tape is fed in the peeling direction (see, for example, Patent Document 1). . In the prior art shown in this patent document example, an automatic tape peeling mechanism is provided on the upstream side of a pick-up position where parts are picked up by suction using a vacuum nozzle, and the peeled cover tape is transported to a cover tape collection container by a pair of feed rollers. The sending configuration is described.

Japanese Patent Publication No. 2005-539370

However, the configuration in which the peeled cover tape is sent to the cover tape collecting container by the pair of sending rollers as in the prior art described above has the following problems. That is, in the tape peeling of the above configuration, the carrier tape is conveyed in a state in which the cover tape attached to the tip thereof has been peeled in advance by a predetermined length. As a result, the pair of rollers can grip the previously peeled portion of the cover tape, and the drive of the rollers automatically peels the cover tape. However, the operation of sandwiching and gripping the peeled cover tape by the pair of rollers is not always reliable, and there are cases where the gripping fails. If the cover tape is not grasped, the cover tape remains stuck to the carrier tape, making it impossible to take out the component from the pocket, resulting in mounting errors. Since such mounting errors cause a decrease in production efficiency, it is required to reliably separate the cover tape from the carrier tape and suppress the occurrence of mounting errors in order to achieve high production efficiency.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a component supply device capable of reliably separating a cover tape from a carrier tape and suppressing the occurrence of mounting errors.

A component supply apparatus of the present invention conveys a carrier tape in which a plurality of pockets containing components are sealed with a cover tape, and supplies the components to a component mounting apparatus, wherein the cover A pair of rollers for peeling the cover tape from the carrier tape by pinching and pulling the tape, and a first cover provided with a peeling part for holding the carrier tape and peeling the cover tape are provided.

A component supply apparatus of the present invention conveys a carrier tape in which a plurality of pockets containing components are sealed with a cover tape, and supplies the components to a component mounting apparatus, wherein the carrier a conveying path along which a tape is conveyed; a first peeling path having a pair of rollers for pinching the cover tape at the tip of the carrier tape and peeling the cover tape from the carrier tape; and the conveying path. a cover provided with a peeling portion for holding down the carrier tape and peeling the cover tape from the carrier tape at an end portion of the carrier tape in the conveying direction; a second stripping path having a path leading to the rollers of the

According to the present invention, it is possible to reliably separate the cover tape from the carrier tape and suppress the occurrence of mounting errors.

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing of the whole structure of the component supply apparatus of one embodiment of this invention Explanatory drawing of the tape conveying part of the component supply apparatus of one embodiment of the present invention BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view of a main part of a component supply device according to an embodiment of the present invention; FIG. 2 is a configuration explanatory diagram of an opening/closing cover of a component supply device according to an embodiment of the present invention; Explanatory drawing of the closed state of the opening/closing cover in the component feeding device according to the embodiment of the present invention. FIG. 2 is a cross-sectional view of a peeling roller and a tape pressing member in a component feeding device according to an embodiment of the present invention; FIG. 2 is a functional explanatory diagram of a peeling roller and a tape pressing member in the component supply device according to one embodiment of the present invention; FIG. 3 is an explanatory diagram of automatic peeling of the cover tape by the peeling roller in the component supply device according to the embodiment of the present invention; Explanatory drawing of cover tape peeling at the first peeling position in the component supply device according to the embodiment of the present invention. Explanatory drawing of cover tape peeling at the second peeling position in the component supply device according to the embodiment of the present invention. Explanatory drawing of cover tape peeling at the second peeling position in the component supply device according to the embodiment of the present invention. FIG. 2 is an explanatory view of the configuration of the positioning portion of the opening/closing cover holding portion of the component feeding device according to the embodiment of the present invention; Explanatory drawing of the open state of the open/close cover of the component supply device according to the embodiment of the present invention. FIG. 2 is an explanatory diagram of gear backlash adjustment in the component feeding device according to one embodiment of the present invention; FIG. 2 is a configuration and functional explanatory diagram of a position adjustment tool used for gear backlash adjustment in a component supply device according to an embodiment of the present invention; FIG. 4 is an explanatory diagram of gear backlash adjustment using a position adjustment tool in the component supply device according to the embodiment of the present invention;

Embodiments of the present invention will now be described with reference to the drawings. First, referring to FIG. 1, the overall configuration of a tape feeder 1, which is a component supply device according to this embodiment, will be described. In FIG. 1, a tape feeder 1 has a function of supplying components to a component mounting apparatus (not shown).

The supply of components by the tape feeder 1 is carried out using a carrier tape 20 having a plurality of pockets 20b (see FIG. 6) containing components P (see FIG. 3) and having cover tapes 20a attached to seal the pockets 20b. It is done by transporting. The carrier tape 20 is conveyed by rotating a sprocket provided with an engaging pin (see the engaging pin 7a shown in FIG. 3) that engages with a feed hole 20c (see FIG. 6) formed in the carrier tape 20. be.

The tape feeder 1 is constructed by arranging elements described below in a main body 2 made of a plate-shaped frame. These elements are covered by side covers 2f (see FIG. 3) provided on both sides. As shown in FIG. 1, the main body 2 has a tape transport path 4 (transport path) that communicates from a tape insertion opening 4a opened at the bottom on the upstream side to a supply position 4b set near the end of the upper surface on the upstream side. ) is provided. A carrier tape 20 containing components is introduced from the tape insertion port 4a into the tape conveying path 4, conveyed to the upper surface of the main body 2 through the oblique portion provided in the middle, and reaches the supply position 4b.

Then, at the supply position 4b, the nozzle of the component mounting apparatus M (not shown) moves up and down (arrow b) to perform a component extraction operation, whereby the component P is extracted from the main body 2. FIG. The picked component P is transferred to the component mounting apparatus by the mounting head (arrow c) and mounted on the substrate to be worked. Conveyance of the carrier tape 20 in the supply of the components is performed by the tape conveying section 3 (conveying section).

The tape conveying section 3 has a motor 5 , a conveying sprocket 6 , a positioning sprocket 7 and a discharge sprocket 8 . By driving the transport sprocket 6, the positioning sprocket 7 and the discharge sprocket 8 by the motor 5 as a driving source, the carrier tape 20 inserted from the tape insertion opening 4a is transported through the tape feeder 1 and positioned at the supply position 4b. be. The carrier tape 20 after the components P have been taken out at the supply position 4b is discharged to the downstream side of the tape feeder 1 by the discharge sprocket 8 via the front cover 9 arranged on the end face of the main body 2. FIG.

That is, the tape conveying section 3 has the function of conveying the carrier tape 20 along the tape conveying path 4 by engaging the sprockets described above with the carrier tape 20 . The cover tape 20a separated from the carrier tape 20 in this tape transport process is folded back upstream and collected into the cover tape storage portion 2b provided in the main body portion 2. As shown in FIG. The engagement of the carrier tape 20 with the positioning sprocket 7 and the discharge sprocket 8 is performed by pressing the carrier tape 20 against the positioning sprocket 7 and the discharge sprocket 8 with the opening/closing cover 18 .

A convex portion 2a for connection with a component mounting apparatus is provided on the bottom surface of the main body portion 2 on the upstream side. The convex portion 2a is provided with a connector 2c, an air joint 2d and a hook 2e. is fitted to the mating side (component mounting apparatus side) to be in a connected state. At this time, the tape feeder 1 is positionally fixed to the feeder base by the hook 2e. In this connected state, it is possible to supply power and air to the tape feeder 1 from the component mounting apparatus, and to exchange signals between the component mounting apparatus and the tape feeder 1 .

A feeder control unit 10 for controlling the operation of the tape feeder 1 is incorporated in the convex portion 2a. When the tape feeder 1 is connected to the component mounting apparatus, the feeder control section 10 is electrically connected to the device control section of the component mounting apparatus through the connector 2c. As a result, an operation command from the device control section of the component mounting apparatus is transmitted to the tape feeder 1, and an operation feedback signal for the component feeding operation by the tape feeder 1 is transmitted to the component mounting apparatus.

Next, with reference to FIGS. 2 and 3, the detailed configuration of the tape conveying section 3 will be described. Note that FIG. 3 shows an AA modified cross section in FIG. In FIG. 2, a motor 5 held by a motor mounting member 5a, which is a support member, is arranged at the lower end portion on the downstream side of the main body portion 2. As shown in FIG. As shown in FIG. 3, the motor mounting member 5a is fixed to one side surface of the body portion 2. As shown in FIG. A first transmission gear 51 is meshed with a driving gear 50 coupled to the rotating shaft of the motor 5, and a second transmission gear 52 provided coaxially with the first transmission gear 51 is engaged with a third transmission gear 15 (second transmission gear 52). 5) are engaged. A shaft 52a that supports the first transmission gear 51 and the second transmission gear 52 is rotatably fitted in a bearing 52b that is fixed to the main body 2, as shown in FIG.

In FIG. 3, a shaft 15b that supports the third transmission gear 15 is rotatably fitted in a bearing 15c that is fixed to a slide member 15a that is a support member. The slide member 15a is fitted into a guide groove 43 (FIG. 14) formed in the body portion 2 and is held so as to be freely adjustable in one direction. The third transmission gear 15 includes a positioning sprocket gear 11 (first gear) coaxial with the positioning sprocket 7 for positioning the carrier tape 20, and a conveying sprocket coaxial with the conveying sprocket 6 conveying the carrier tape 20 to the positioning sprocket 7. Gear 14 (fourth gear) is engaged.

As shown in FIG. 3, the positioning sprocket gear 11 and the positioning sprocket 7 are supported by a shaft 11a, and the shaft 11a is rotatably fitted in a bearing 11b fixed to the body portion 2. As shown in FIG. The positioning sprocket gear 11 is meshed with a fourth transmission gear 13 (third gear) for transmitting torque to a discharge sprocket gear 12 (second gear) coaxial with the discharge sprocket 8 for discharging the carrier tape 20. there is Further, the conveying sprocket gear 14 transmits torque to a peeling roller gear 16 (sixth gear) for driving a tape peeling mechanism 21 (see FIG. 5) that feeds the cover tape 20a peeled from the carrier tape 20. The fifth transmission gear 17 (seventh gear) is engaged.

In the above configuration, by driving the motor 5 to generate torque, the torque is transmitted to the positioning sprocket gear 11, the discharge sprocket gear 12, and the transfer sprocket gear 14 via a plurality of gears. As a result, torque is transmitted to the positioning sprocket 7, the ejection sprocket 8, and the transportation sprocket 6, which are provided coaxially with the positioning sprocket gear 11, the ejection sprocket gear 12, and the transportation sprocket gear .

The positioning sprocket 7 is a first sprocket that engages with feed holes provided in the carrier tape 20 and rotates to convey the component P to the supply position 4b to the component mounting apparatus. The ejection sprocket 8 is a second sprocket that engages with the feed holes 20c of the carrier tape 20 after the parts P have been supplied, rotates, and ejects the carrier tape 20 from the tape feeder 1. FIG. The conveying sprocket 6 is a third sprocket that engages with the feed holes 20c of the carrier tape 20 and rotates to convey the carrier tape 20 to the first sprocket.

Of these three sprockets, the upper surfaces of the positioning sprocket 7 and the discharge sprocket 8 are provided with an opening/closing cover 18 (cover) having a function of pressing the carrier tape 20 conveyed by the conveying sprocket gear 14. This pressing causes the engagement pins of the positioning sprocket 7 and the discharge sprocket 8 to engage with the feed holes 20c of the carrier tape 20 (see FIG. 3). That is, the tape conveying section 3 has an opening/closing cover 18 for pressing the carrier tape 20 against the positioning sprocket 7 as the first sprocket and the ejection sprocket 8 as the second sprocket.

That is, the motor 5 generates torque for driving the positioning sprocket 7 as the first sprocket, the discharge sprocket 8 as the second sprocket, and the transfer sprocket 6 as the third sprocket. The tape conveying section 3 having the above-described structure has a plurality of gears for transmitting the torque generated by the motor 5 to the positioning sprocket 7 , the ejection sprocket 8 and the conveying sprocket 6 . These gears are a positioning sprocket gear 11 (first gear) coaxial with the positioning sprocket 7 which is the first sprocket, and a discharge sprocket gear 12 (second gear) coaxial with the discharge sprocket 8 which is the second sprocket. 2 gear), and a fourth transmission gear 13 (third gear) that meshes with the positioning sprocket gear 11 and the ejection sprocket gear 12 .

As shown in FIG. 3, an engagement pin 7a is provided on the outer circumference of the positioning sprocket 7. As shown in FIG. Feed holes 20c (see FIG. 6) are formed in the carrier tape 20 at a pitch corresponding to the pitch of the engaging pins 7a. By intermittently rotating the positioning sprocket 7 while engaging the engagement pins 7a with the feed holes, the carrier tape 20 is fed along the tape transport path 4 at a predetermined feed pitch. Similarly, the discharge sprocket 8 and the transfer sprocket 6 are intermittently rotated to feed the carrier tape 20 at a predetermined feed pitch.

The plurality of gears that the tape conveying section 3 has further includes the following gears. That is, these gears include a transport sprocket gear 14 (fourth gear) coaxial with the transport sprocket 6 which is the third sprocket, a positioning sprocket gear 11 (first gear), and a transport sprocket gear 14 (first gear). 4 gear) and a third transmission gear 15 (fifth gear).

Furthermore, the plurality of gears described above are a peeling roller gear 16 (sixth gear) coaxial with the driving peeling roller 22 of the tape peeling mechanism 21 that feeds and picks up the cover tape 20a peeled from the carrier tape 20, and a peeling roller gear 16. and a fifth transmission gear 17 (seventh gear) that meshes with the conveying sprocket gear 14 . In this embodiment, the tape conveying section 3 in which a plurality of gears are arranged rotates the conveying sprocket 6, the positioning sprocket 7, and the ejection sprocket 8 using a single motor 5 as a driving source. .

As a result, the carrier tape 20 introduced from the tape insertion port 4a is conveyed to the positioning sprocket 7 by the conveying sprocket 6. As shown in FIG. Then, the positioning sprocket 7 positions the carrier tape 20 at the supply position 4b. Furthermore, the carrier tape 20 from which the components P have been taken out at the supply position 4b is discharged to the downstream side of the tape feeder 1 by the discharge sprocket 8. As shown in FIG. With such a configuration, the carrier tape 20 can be stably and reliably conveyed in the tape feeder 1 .

In this embodiment, the diameter of the ejection sprocket 8, which is the second sprocket, is set smaller than the diameter of the positioning sprocket 7, which is the first sprocket. As a result, the side of the tape feeder 1 that is close to the component mounting apparatus can be made compact, and the component supply section to which the plurality of tape feeders 1 are mounted can be miniaturized in the component mounting apparatus.

Next, referring to FIGS. 4 and 5, the configuration and function of the opening/closing cover 18 that covers the upper surfaces of the positioning sprocket 7 and the ejection sprocket 8 and presses the carrier tape 20 against the positioning sprocket 7 and the ejection sprocket 8 to engage them. explain. FIG. 4A is a plan view of the opening/closing cover holding portion 19 (cover holding portion) holding the opening/closing cover 18, which is pivotally supported by the block 31 fixed to the main body portion 2 by the support shaft 32. FIG. 4(b) is a plan view showing the opening/closing cover 18 alone shown in FIG. 4(a).

The opening/closing cover 18 is a member having a substantially U-shaped cross section with an open bottom side. The upper surface of the opening/closing cover 18 is a cover portion 18a (see FIG. 3) that abuts and presses the carrier tape 20. As shown in FIG. The cover portion 18a is provided with a component take-out opening 18b for taking out the component P at the supply position 4b. The component extraction opening 18b functions as a supply section for supplying the component P to the component mounting apparatus.

Further, the cover portion 18a is provided with engagement pins 7a of the positioning sprocket 7 and the discharge sprocket 8, respectively, when the opening/closing cover 18 is lowered with respect to the main body portion 2 and closed as shown in FIG. 4(a). A first escape portion 18d and a second escape portion 18e are provided to escape the pin 8a. Further, the cover portion 18a is provided with a notch portion 18c formed by notching the first relief portion 18d to one side surface. As shown in FIG. 4(b), the opening/closing cover 18 is provided with a base portion 18f with both side surfaces extending upstream. Further, the opening/closing cover 18 is provided with an engaging portion 18g (see FIG. 5) formed by extending the cover portion 18a toward the downstream side.

In FIG. 5, a block 31 is a rectangular block-shaped member and fixed to the main body 2 . A substantially plate-shaped tape pressing member 30 is arranged along the tape transport path 4 between the lower surface side of the block 31 and the upper surface of the tape transport path 4 . The tape pressing member 30 has a function of contacting the upper surface of the carrier tape 20 conveyed along the tape conveying path 4 and pressing it from above (see FIG. 6).

The tape pressing member 30 is urged downward by a spring member 33 arranged between it and the block 31 so that it can be displaced in the thickness direction of the carrier tape 20 . As a result, a plurality of types of carrier tapes 20 having different thicknesses can be stably conveyed without forming gaps on the pressing surface.

The opening/closing cover holding portion 19 is rotatably supported on the block 31 via a support shaft 32 . The opening/closing cover holding portion 19 is a substantially disk-shaped member having an extension portion 19c partially extending in the tangential direction. A base portion 18f of the opening/closing cover 18 shown in FIG. 4B is fixed to the extending portion 19c by screwing. With such a configuration, the opening/closing cover 18 is held by the opening/closing cover holding portion 19 with respect to the main body portion 2 of the tape feeder 1 so as to be openable and closable.

FIG. 5 shows a state in which the opening/closing cover 18 held by the opening/closing cover holding portion 19 is closed. In this state, the opening/closing cover 18 is kept closed by the lock mechanism provided on the front cover 9 . That is, the front cover 9 includes an elevating portion 9a that can slide vertically with respect to the base portion 9b (arrow d) and that is biased downward by a biasing spring member 9c. The sliding motion of the elevating section 9a is guided by a guide mechanism combining a long hole 9e provided in the elevating section 9a and a pin 9d provided in the base 9b.

A locking pin 9f (see FIG. 4(a)) is provided on the upper portion of the lifting portion 9a, and the locking pin 9f locks a locking portion 18g extending from the downstream end of the opening/closing cover 18. possible shape. In order to close the opening/closing cover 18, the lifting portion 9a is first lifted to raise the locking pin 9f, and in this state the opening/closing cover 18 is closed to position the locking portion 18g below the locking pin 9f. Next, in this state, the lifting portion 9a is lowered to bring the locking pin 9f into contact with the locking portion 18g. As a result, the engaging portion 18g is pressed downward by the biasing force of the biasing spring member 9c and locked, and the open/close cover 18 is kept closed.

To open the opening/closing cover 18 from the closed state, the opening operation shown in FIG. 9 is performed. That is, first, the elevating portion 9a is raised against the biasing force of the biasing spring member 9c to release the locked state in which the locking portion 18g is held down by the locking pin 9f. Next, the opening/closing cover 18 is lifted to the open state shown in FIG. 9 (arrow m).

The opening/closing cover holding portion 19 in the present embodiment is provided with a positioning portion configured as described below for positioning the opening/closing cover holding portion 19 in the open state and the closed state in the opening/closing operation described above. That is, as shown in FIG. 12, two concave portions, a first engaging portion 19a and a second engaging portion 19b corresponding to the open/closed state of the open/close cover 18, are formed on the outer periphery of the open/close cover holding portion 19. ing.

Further, a positioning member 40 having a positioning projection 40a engageable with the first engaging portion 19a and the second engaging portion 19b is arranged on the outer periphery of the opening/closing cover holding portion 19. As shown in FIG. The positioning member 40 is rotatable around a fulcrum 40b, and is moved in the direction of arrow q, i.e., the positioning projection 40a to the first engaging portion 19a by a biasing spring member 41 coupled to the opposite end of the positioning projection 40a. , is urged in the direction of engaging with the second engaging portion 19b. As a result, the opening/closing cover 18 is positioned as described below.

First, when opening the opening/closing cover 18, as shown in FIG. 13, by lifting the opening/closing cover 18 (arrow r), the opening/closing cover holding portion 19 is rotated to move the positioning convex portion 40a to the first engagement. Engage with joint 19a. When the opening/closing cover 18 is to be closed, the positioning convex portion 40a is engaged with the second engaging portion 19b as shown in FIG.

As a result, the opening/closing cover holding portion 19 can be positioned according to the opening/closing state of the opening/closing cover 18 . That is, in the present embodiment, the opening/closing cover holding portion 19 has a first engaging portion 19a that engages with the positioning convex portion 40a when the opening/closing cover 18 is open, and positions the opening/closing cover 18 when the opening/closing cover 18 is closed. It is configured to have a second engaging portion 19b that engages with the convex portion 40a.

12, in order to stabilize the engaging state of the carrier tape 20 with the positioning sprocket 7 and the ejection sprocket 8 that constitute the tape conveying section 3, the opening and closing cover 18 is attached to the tape conveying section 3. It is desirable that an urging force F pressing against is acting. In order to achieve this biasing force F with a simple structure, the extending portion 19c connecting the opening/closing cover 18 to the opening/closing cover holding portion 19 may be provided with a biasing means 19d having a function of applying the above-described biasing force F. desirable. As the biasing means 19d, for example, an elastic member such as a coiled spring that generates elastic force in the rotational direction can be used.

Next, with reference to FIGS. 4 and 5, the configuration and function of the tape peeling mechanism 21 for picking up the cover tape 20a peeled from the carrier tape 20 will be described. As shown in FIG. 5 , a tape peeling mechanism 21 is arranged in the tape conveying path 4 on the upstream side of the positioning sprocket 7 . The tape peeling mechanism 21 includes a driving peeling roller 22 and a driven peeling roller 23, which are a pair of rollers for picking up the cover tape 20a peeled from the carrier tape 20. As shown in FIG.

The drive peeling roller 22 and the driven peeling roller 23 are toothed rollers provided with mutually meshing teeth on their outer circumferences. It has a function to pick up As shown in FIG. 5 , one of the pair of rollers, the driving peeling roller 22 , is rotatably provided in the opening/closing cover holding portion 19 . The driven peeling roller 23, which is one of the pair of rollers, is rotatably provided at the downstream end of the tape pressing member 30 arranged along the tape transport path 4 on the lower surface side of the block 31. As shown in FIG.

A tape cover 24 is provided downstream of the tape pressing member 30 in the tape transport path 4 along the upper surface of the tape transport path 4 up to a position before the supply position 4b. The tape cover 24 is fixed to the tape pressing member 30 and can be displaced along with the tape pressing member 30 in the thickness direction of the carrier tape 20 . The tape cover 24 functions as a first cover that covers the upper surface of the carrier tape 20 from which the cover tape 20 a has been peeled by the tape peeling mechanism 21 .

That is, in the carrier tape 20 with the cover tape 20a peeled off, the pocket 20b is exposed and the stored component P becomes unstable. By covering the upper surface of the carrier tape 20 with the tape cover 24, the carrier tape 20 after the cover tape 20a is peeled off can be stably conveyed without causing problems such as falling off of the parts P.

It is also possible to make the downstream end of the tape cover 24 function as a peeling section 24a for peeling the cover tape 20a from the carrier tape 20 (see FIGS. 10 and 11). In this case, the tape cover 24 is a first cover provided with a peeling portion 24a for holding down the carrier tape 20 and peeling off the cover tape 20a.

In the tape feeder 1 according to the present embodiment, the tape cover 24, which is the first cover, is fixed to the tape pressing member 30 that presses the carrier tape 20 upstream of the pair of the driving stripping roller 22 and the driven stripping roller 23. are provided. The opening/closing cover 18, which is the second cover, is provided with a component take-out opening 18b as a supply unit for supplying the component P to the component mounting apparatus, and is configured to be openable and closable with respect to the main body of the tape feeder 1. It's becoming

Next, the driving mechanism of the tape peeling mechanism 21 will be described. As shown in FIG. 4, the driving peeling roller 22 is provided coaxially with the peeling roller gear 16 . A fifth transmission gear 17 that meshes with the peeling roller gear 16 is provided coaxially with the opening/closing cover holding portion 19 . In the opening/closing cover holding portion 19, the drive peeling roller 22 is arranged at a position where the coaxial peeling roller gear 16 meshes with the fifth transmission gear 17 (see also FIG. 2).

Therefore, when the opening/closing cover holding portion 19 rotates with the opening/closing of the opening/closing cover 18, the peeling roller gear 16 is always engaged with the fifth transmission gear 17. It rolls along the outer circumference of 17 . In this rolling, the rotation is transmitted from the fifth transmission gear 17 to the peeling roller gear 16 regardless of the position of the peeling roller gear 16, and the drive peeling roller 22 is rotationally driven.

That is, in the above configuration, the fifth transmission gear 17 is a roller driving gear in which a peeling roller gear 16 (roller gear) coaxial with one driving peeling roller 22 is rotatably provided along the outer circumference. One of the pair of rollers, the driving peeling roller 22, rolls along the outer circumference of the fifth transmission gear 17 as the opening/closing cover holding portion 19 is opened and closed, and the fifth transmission gear, which is a roller driving gear. 17 and a peeling roller gear 16 which is a roller gear.

As shown in FIG. 5, the driven peeling roller 22 that is rotationally driven in this way meshes with the driven peeling roller 23 only when the opening/closing cover 18 is closed. That is, the tape peeling mechanism 21 in the present embodiment is configured to perform the function of pinching the cover tape 20a between the driving peeling roller 22 and the driven peeling roller 23 only when the opening/closing cover 18 is closed. there is

Next, with reference to FIGS. 6 and 7, the detailed configuration of the driven peeling roller 23 constituting the tape peeling mechanism 21 and the guide mechanism for guiding the carrier tape 20 conveyed to the tape peeling mechanism 21 will be described. 6A shows a cross section of the downstream end of the tape pressing member 30 in a direction orthogonal to the transport direction of the carrier tape 20. FIG. In FIG. 6A, the upper surface of the main body 2 is a tape transport surface 2i for transporting the carrier tape 20. As shown in FIG. The tape conveying path 4 is open to the tape conveying surface 2i, and the carrier tape 20 is set in the tape conveying path 4 with the pocket 20b positioned in the conveying state. In this set state, the carrier tape 20 is in contact with the tape transport surface 2i, and the convex portion 30a provided on the lower surface of the tape pressing member 30 is in contact with the upper surface of the cover tape 20a.

As shown in FIG. 6(b), a spring member 33, which is an elastic body, is attached to a concave portion 30b formed on the upper surface of the tape pressing member 30 and a concave portion 31a formed on the lower surface of the block 31. As shown in FIG. The spring member 33 is a compression spring, and exerts an urging force in the pressing direction between the fixed block 31 and the tape pressing member 30 that can be displaced in the thickness direction. As a result, the convex portion 30a formed on the lower surface of the tape pressing member 30 comes into contact with the cover tape 20a and presses the carrier tape 20 against the tape conveying surface 2i (arrow e).

In the above configuration, the tape pressing member 30 is connected to a block 31 fixed to the body portion 2 of the tape feeder 1 by a spring member 33 as an elastic body. This makes it possible to absorb the difference in thickness of the carrier tape 20 to be conveyed. Further, the tape holding member 30 has a convex portion 30a that can come into contact with the cover tape 20a on the upper surface of the carrier tape 20. As shown in FIG. As a result, in the structure in which the carrier tape 20 is pressed by the tape pressing member 30, it is possible to prevent the problem that the tape pressing member 30 sticks to the cover tape 20a and interferes with the smooth sliding operation.

6A, a peeling roller support shaft 36 is rotatably held via a bearing 35 in a bearing portion 34 provided at one side end portion of the tape pressing member 30. As shown in FIG. A roller member 37 constituting the driven peeling roller 23 is coupled to the peeling roller support shaft 36 . The roller member 37 is a toothed roller member provided with teeth engaging with the driving peeling roller 22 on its outer periphery, and two circumferential grooves 37a are formed on its outer periphery.

A entanglement prevention member 38 shown in FIG. 7 engages with the circumferential groove 37a in a form that allows the rotation of the roller member 37 around the peeling roller support shaft 36. As shown in FIG. The entanglement prevention member 38 is a plate member that engages with the inner periphery of the circumferential groove 37a in the form of an E-ring, and its upstream end is fixed to the block 31 (see FIG. 7).

That is, the roller member 37 is supported around the peeling roller support shaft 36 and held in a state where it is allowed to rotate by the entanglement prevention member 38 . 4, illustration of the entanglement prevention member 38 is omitted. Further, the driving separation roller 22 is also equipped with a entanglement prevention member 38 having a similar structure. The presence of the entanglement prevention member 38 in the form of being fitted in the circumferential groove 37a formed in the roller member 37 provides the following effects.

In tape peeling, in which the cover tape 20a is sandwiched between a pair of driving peeling rollers 22 and driven peeling rollers 23 and pulled off, the sandwiched cover tape 20a winds around one of the peeling rollers, preventing normal tape pulling. may occur. To solve this problem, the entanglement prevention member 38 as shown in the present embodiment is provided to prevent the cover tape 20a from being entangled in the outer circumferences of the driving peeling roller 22 and the driven peeling roller 23. FIG.

That is, the entanglement prevention member 38 functions as an entanglement prevention portion that prevents the cover tape 20a picked up by the pair of driving peeling roller 22 and driven peeling roller 23 from being entangled. The driven peeling roller 23, which is one of the pair of the driving peeling roller 22 and the driven peeling roller 23, is attached to the block 31 fixed to the main body 2 of the tape feeder 1 via the entanglement prevention member 38 as an entanglement prevention portion. It has a connected form.

In the above-described configuration, the driven peeling roller 23 of the tape peeling mechanism 21 is held by the tape pressing member 30 via the peeling roller support shaft 36 . As a result, even if the thickness of the target carrier tape 20 changes, the driven peeling roller 23 moves along with the tape pressing member 30 in the thickness direction of the carrier tape 20, and the distance of the driven peeling roller 23 from the cover tape 20a remains constant. kept in

In FIG. 6(a), the bottom surface of the tape transport path 4 has air ejection holes 2h at positions corresponding to the tape peeling mechanism 21 consisting of a pair of rollers (see FIG. 7). The air ejection holes 2 h eject air supplied through the air joint 2 d (see FIG. 1) and the air supply holes 2 g between the driven separation roller 22 and the driven separation roller 23 . As a result, the leading edge of the cover tape 20 a peeled from the carrier tape 20 is blown up and introduced between the driving peeling roller 22 and the driven peeling roller 23 .

That is, the air joint 2d for supplying air, the air supply hole 2g, and the air ejection hole are located at positions corresponding to the driving peeling roller 22 and the driven peeling roller 23, which are a pair of rollers, in the transport path of the tape transport path 4 of the carrier tape 20. , and constitutes an introducing portion for introducing the cover tape 20a between the driving peeling roller 22 and the driven peeling roller 23 using the flow of gas jetted from the air ejection holes. At this time, as described above, the distance between the driven peeling roller 23 and the cover tape 20a is kept constant, so that the driven peeling roller 22 and the driven peeling roller 23 reliably catch the tip of the cover tape 20a blown up. be able to.

In the example shown in the present embodiment, air ejected from the air ejection holes is used as the gas flow described above. Instead of blowing air, a negative pressure is applied between the driving peeling roller 22 and the driven peeling roller 23, and this negative pressure is used to move the cover tape 20a between the driving peeling roller 22 and the driven peeling roller 23. may be introduced into

FIG. 8 shows the take-up operation of the cover tape 20a by the introduction section described above. This take-up operation is automatic peeling performed with the opening/closing cover 18 closed. First, as shown in FIG. 8(a), the carrier tape 20 is conveyed along the tape conveying path 4 in a state where the cover tape 20a of a predetermined length at the leading end has been peeled off from the carrier tape 20 in advance (arrow g). . At this time, in the tape peeling mechanism 21, the driving peeling roller 22 and the driven peeling roller 23 are both in a rotating state as the driving peeling roller 22 is rotationally driven (arrows i and j). Air for introduction is ejected from the air ejection holes provided in the tape transport path 4 (arrow h).

When the transport is continued in this state, the peeled cover tape 20a at the leading end reaches the tape peeling mechanism 21 as shown in FIG. 8(b). As a result, the cover tape 20 a at the leading end is blown up by the action of the air ejected from the air ejection holes and introduced between the driving peeling roller 22 and the driven peeling roller 23 . By sandwiching the cover tape 20a between the rotating driving peeling roller 22 and the driven peeling roller 23, the cover tape 20a is peeled off from the carrier tape 20 and taken off as shown in FIG. 8(c).

FIG. 9 shows a state in which the opening/closing cover 18 is opened after the automatic peeling described above. First, the elevating portion 9a of the front cover 9 is lifted (arrow k) to release the locking of the locking portion 18g by the locking pin 9f. Next, the opening/closing cover 18 is lifted (arrow m), the opening/closing cover holding portion 19 is rotated around the support shaft 32, and as shown in FIG. . As a result, the opening/closing cover 18 is kept open with respect to the main body 2 .

Next, with reference to FIGS. 10 and 11, an embodiment in which the cover tape 20a is peeled off using the peeling portion 24a of the tape cover 24 without using the automatic peeling by the tape peeling mechanism 21 will be described. As in this embodiment, when a plurality of types of carrier tapes 20 are to be worked, the peeling characteristics of the cover tape 20a differ depending on the carrier tapes 20 to be worked. That is, there are not only tape types to which automatic peeling can be applied without problems as shown in FIG. 8, but also tape types for which automatic peeling is difficult without operation errors.

Therefore, in the present embodiment, for tape types for which automatic peeling is difficult to apply, the cover tape 20a is peeled using the peeling portion 24a of the tape cover 24, as described below. In this mode, first, as shown in FIG. 10, the opening/closing cover 18 is opened (arrow n). In this state, the carrier tape 20 is fed along the tape transport path 4, passes under the tape cover 24, and reaches the front cover 9 via the top of the positioning sprocket 7 and the ejection sprocket 8. Let Thereby, the cover tape 20a is exposed on the downstream side of the tape cover 24 .

Next, the exposed cover tape 20a is peeled off from the carrier tape 20 and, as shown in FIG. The peeled cover tape 20a is guided to the cover tape storage section 2b on the upstream side through between the opening/closing cover 18 and the tape cover 24 (arrow o).

Next, as shown in FIG. 11, the opening/closing cover 18 is closed and locked by the front cover 9 . That is, a downward biasing force is applied to the biasing spring member 9c of the elevating portion 9a of the front cover 9 (arrow p), and the locking portion 18g of the opening/closing cover 18 is pressed downward by the locking pin 9f. In this state, the driven peeling roller 22 fixed to the opening/closing cover holding portion 19 is positioned to mesh with the driven peeling roller 23 . As a result, the cover tape 20a is nipped between the pair of the driving peeling roller 22 and the driven peeling roller 23 and pulled upstream.

That is, in the peeling mode using the peeling portion 24a of the tape cover 24, the cover tape 20a is folded back in the direction opposite to the conveying direction of the carrier tape 20 at the peeling portion 24a of the tape cover 24, which is the first cover. stripped by Then, the cover tape 20a peeled off by the peeling portion 24a is picked up by a pair of drive peeling roller 22 and driven peeling roller 23 through between the tape cover 24 which is the first cover and the opening/closing cover 18 which is the second cover. .

In other words, the tape feeder 1 according to the present embodiment has the first stripping path for performing the above-described automatic stripping and the second stripping path for stripping the cover tape 20a using the stripping portion 24a of the tape cover 24. It has a configuration with a peeling path of .

That is, the first stripping path includes the tape transport path 4 in which the carrier tape 20 is transported, and a pair of drive stripping paths that pinch the cover tape 20a at the tip of the carrier tape 20 and strip the cover tape 20a from the carrier tape 20. It is configured to have a roller 22 and a driven peeling roller 23 .

The second peeling path includes a tape transport path 4 in which the carrier tape 20 is transported, and a peeling section that presses the carrier tape 20 and peels off the cover tape 20a from the carrier tape 20 at the end of the carrier tape 20 in the transport direction. 24a, and a path for guiding the cover tape 20a peeled at the peeling portion 24a to a pair of driving peeling rollers 22 and driven peeling rollers 23. As shown in FIG.

Next, with reference to FIGS. 14, 15, and 16, the backlash adjusting function of the tape conveying section 3 provided in the tape feeder 1 according to the present embodiment will be described. In the tape feeder 1, in order to ensure high accuracy of the parts stop position at the supply position 4b, it is required to transmit the torque generated by the motor 5, which is the drive source, to the positioning sprocket 7 with high accuracy. For this reason, the tape transport section 3 shown in the present embodiment employs the following configuration so that the backlash can be adjusted with high precision and good workability at the key points of torque transmission.

FIG. 14 shows a transmission path for transmitting the torque generated by the motor 5 in the tape conveying section 3 to the positioning sprocket 7. As shown in FIG. In this transmission path, since the motor 5 and the drive gear 50, the first transmission gear 51 and the second transmission gear 52, and the positioning sprocket 7 and the positioning sprocket gear 11 are coaxial, rotation transmission error may occur. A certain point is limited to a transmission point from the drive gear 50 to the first transmission gear 51 and a transmission point from the second transmission gear 52 to the positioning sprocket gear 11 via the third transmission gear 15 .

For this reason, in the present embodiment, at least one gear to be adjusted is rotatably supported so that the backlash at the two transmission points can be adjusted with high accuracy and good workability. A support member that can be displaced with respect to the portion 2 is provided.

First, at least one gear includes a drive gear 50 provided coaxially with the motor 5 . The motor mounting member 5a supports the motor 5 and the driving gear 50, and by finely adjusting the position of the motor mounting member 5a, the relative position between the driving gear 50 and the first transmission gear 51 can be finely adjusted ( Arrow s), adjust the backlash. Here, the motor mounting member 5a is connected to the main body portion 2 of the tape feeder 1 through a support shaft 5b, and the motor mounting member 5a can be displaced by rotating around the support shaft 5b.

At least one gear includes a third transmission gear 15 meshing with the positioning sprocket gear 11 and the second transmission gear 52 . A slide member 15a supporting the third transmission gear 15 is fitted in a guide groove 43 (see also FIG. 2) formed in the body portion 2 of the tape feeder 1. As shown in FIG. That is, the slide member 15a is guided by the guide surface 43a of the guide groove 43 with respect to the main body 2 of the tape feeder 1 in the predetermined direction indicated by the arrow t. Here, the predetermined direction indicated by the arrow t is a direction in which the relative positions of the third transmission gear 15, the positioning sprocket gear 11, and the second transmission gear 52 can be finely adjusted together. Displacement to slide to is possible.

The motor mounting member 5a and the slide member 15a described above are adjusted by a position adjusting tool shown in FIG. installed as possible. That is, a position adjustment tool 44 described below is fitted into the adjustment openings 42 provided in the motor attachment member 5a and the slide member 15a, respectively, and a predetermined adjustment operation is performed, whereby the motor attachment member 5a and the slide member 15a are adjusted. A fine adjustment of the position of the member 15a is performed. After the fine adjustment is executed, the motor mounting member 5a and the slide member 15a are fixed to the main body 2 by tightening the fixing screws 5c and 15d, respectively.

FIG. 15 shows the configuration and adjustment operation of the position adjustment tool 44 used for this fine adjustment. As shown in FIG. 15(a), the position adjustment tool 44 has a cylindrical rod-shaped operating member 45 coupled to a circular member 46, and has a projecting portion 45a in which the tip of the operating member 45 protrudes from the circular member 46. It is configured.

The position adjustment tool 44 is an eccentric tool, and as shown in FIG. 15(b), the axis of the operating member 45 is eccentric with respect to the center of the circular member 46 by a predetermined eccentricity e. Fitting portions 2j for fitting projections 45a are provided in the body portion 2 at positions corresponding to the adjustment openings 42 formed in the motor mounting member 5a and the slide member 15a.

To finely adjust the positions of the motor mounting member 5a and the slide member 15a using the position adjustment tool 44, as shown in FIG. It is fitted into the opening 42 and the protrusion 45a is fitted into the fitting portion 2j. In this state, the operating member 45 is rotated (arrow u) to rotate the circular member 46 around the operating member 45 . At this time, by adjusting the rotation direction and rotation amount of the operation member 45, the motor mounting member 5a and the slide member 15a can be displaced by a desired adjustment amount (arrow v).

For this position adjustment, as shown in FIG. 16, first, the fixing screws 5c and 15d are loosened to make the motor mounting member 5a and the slide member 15a displaceable, and then the working operation shown in FIG. 15(c) is performed. That is, the position adjusting tool 44 is sequentially inserted into the adjustment openings 42 of the motor mounting member 5a and the slide member 15a, and the operation shown in FIG. , y).

By this operation, the motor mounting member 5a is displaced around the support shaft 5b so that the drive gear 50 moves in the direction of the arrow s. Similarly, the slide member 15a is displaced so that the third transmission gear 15 slides in the arrow t direction. This displacement adjusts the backlash of the meshing portions of the driving gear 50 and the first transmission gear 51 , the third transmission gear 15 and the positioning sprocket gear 11 and the second transmission gear 52 . After adjusting the backlash in this manner, the fixing screws 5c and 15d are tightened to fix the positions of the motor mounting member 5a and the slide member 15a.

As described above, the tape feeder 1 shown in the present embodiment conveys the carrier tape 20 having a plurality of pockets 20b in which components are stored and to which the cover tape 20a for sealing the pockets 20b is attached. A tape feeder 1 for supplying components to a component mounting apparatus, comprising a tape conveying section 3 engaging with a carrier tape 20 to convey the carrier tape 20, and an opening/closing cover 18 engaging the carrier tape 20 with the tape conveying section 3. , an opening/closing cover holding portion 19 for holding the opening/closing cover 18 so as to be openable/closable with respect to the main body portion 2 of the tape feeder 1, a pair of drive peeling rollers 22 for picking up the cover tape 20a peeled from the carrier tape 20, and a driven peeling roller. 23 , and one of the driving peeling roller 22 and the driven peeling roller 23 is configured to be rotatably provided in the opening/closing cover holding portion 19 . With this configuration, the opening and closing of the opening and closing cover 18 and the opening and closing of the pair of driving peeling roller 22 and driven peeling roller 23 can be performed simultaneously in a single operation, thereby simplifying the preparation work for setting the carrier tape 20. Efficiency can be improved.

Further, the tape feeder 1 shown in the present embodiment has the same configuration as the tape feeder 1 described above, and includes a pair of driven peeling rollers 22 for peeling the cover tape 20a from the carrier tape 20 by pinching and pulling the cover tape 20a. , a driven peeling roller 23, and a tape cover 24 provided with a peeling portion 24a for pressing the carrier tape 20 and peeling off the cover tape 20a. With this configuration, even when a plurality of types of carrier tapes 20 with different characteristics are targeted, the cover tape 20a can be reliably peeled from the carrier tape 20 by a peeling method according to the characteristics of the carrier tape 20, preventing mounting errors. can be suppressed.

Further, the tape feeder 1 shown in the present embodiment has the same configuration as described above, and rotates in engagement with the feeding hole 20c provided in the carrier tape 20 to feed the component mounting apparatus to the supply position 4b. a positioning sprocket 7 for conveying the parts to the tape feeder 1; The diameter of the sprocket 8 is set smaller than the diameter of the positioning sprocket 7. - 特許庁As a result, in the tape feeder 1 having the discharge sprocket 8, it is possible to reduce the size of the leading end portion and realize compactness.

Further, the tape feeder 1 shown in the present embodiment has the same configuration as described above, and is provided on the tape transport path 4 for transporting the carrier tape 20. A pair of drive stripping members are provided on the tape transport path 4 for transporting the carrier tape 20 and pull the cover tape 20a therebetween. In a configuration including a roller 22, a driven peeling roller 23, and a tape pressing member 30 that presses the upper surface of the carrier tape 20 and is displaceable in the thickness direction of the carrier tape 20, the driven peeling roller 23, which is one of the pair of rollers, is provided. is rotatably provided on the tape pressing member 30 . As a result, in the structure in which the cover tape 20a is taken off by a pair of rollers, the cover tape 20a can be taken off stably even when the carrier tape 20 is thin.

Further, the tape feeder 1 shown in the present embodiment has the same configuration as described above, and rotates in engagement with the feeding holes 20c provided in the carrier tape 20 to feed the components to the component mounting apparatus. a positioning sprocket 7 for conveying, a motor 5 for generating torque for rotating the positioning sprocket 7, and at least one gear for transmitting the torque to the positioning sprocket 7, at least one gear being rotatably supported, It is configured to have a motor mounting member 5a and a slide member 15a that can be displaced with respect to the body portion 2 of the tape feeder 1. As shown in FIG. As a result, it is possible to easily adjust the backlash, and to ensure high component stop position accuracy.

INDUSTRIAL APPLICABILITY The component supply device of the present invention has the effect of reliably separating the cover tape from the carrier tape and suppressing the occurrence of mounting errors. Useful.

Reference Signs List 1 tape feeder 2 main body 3 tape conveying section 4 tape conveying path 5 motor 5a motor mounting member 6 conveying sprocket 7 positioning sprocket 8 discharge sprocket 10 feeder control section 11 positioning sprocket gear 12 discharge sprocket gear 13 fourth transmission gear 14 conveying sprocket gear 15 Third transmission gear 15a Slide member 16 Separation roller gear 17 Fifth transmission gear 18 Open/close cover 18a Cover portion 18b Component extraction opening 19 Open/close cover holding portion 19a First engaging portion 19b Second engaging portion 19d Biasing means 20 carrier tape 20a cover tape 20b pocket 21 tape peeling mechanism 22 drive peeling roller 23 driven peeling roller 24 tape cover 24a peeling portion 30 tape pressing member 30a convex portion 31 block 33 spring member 38 entanglement prevention member 44 position adjustment tool 46 circular member

Claims (6)

A component supply device that conveys a carrier tape in which a plurality of pockets containing components are sealed with a cover tape and supplies the components to a component mounting device,
a pair of rollers for peeling off the cover tape from the carrier tape by pinching and pulling the cover tape;
a first cover provided with a peeling portion for holding down the carrier tape and peeling the cover tape;
a supply unit that supplies the component to the component mounting apparatus;
a second cover provided with the supply unit and openable and closable with respect to the main body of the component supply device;
The cover tape is peeled by being folded back in the opposite direction to the conveying direction of the carrier tape at the peeling portion of the first cover,
The component supply device , wherein the cover tape peeled by the peeling section is picked up by the pair of rollers through between the first cover and the second cover . The component supply device according to claim 1, further comprising:
Provided at a position corresponding to the pair of rollers in the transport path of the carrier tape,
A component supply device comprising an introduction section for introducing the cover tape to the pair of rollers using gas flow. The component supply device according to claim 2,
The component supply device, wherein the introducing section ejects air to introduce the cover tape into the pair of rollers. The component supply device according to claim 2,
The component supply device, wherein the introduction section introduces the cover tape to the pair of rollers using a negative pressure. The component supply device according to claim 1,
The component supply device, wherein the first cover is fixed to the tape pressing member. A component supply device that conveys a carrier tape in which a plurality of pockets containing components are sealed with a cover tape and supplies the components to a component mounting device,
a transport path along which the carrier tape is transported;
a first peeling path having a pair of rollers for pinching the cover tape at the tip of the carrier tape and peeling the cover tape from the carrier tape;
a cover provided with a peeling portion for holding down the carrier tape and peeling the cover tape from the carrier tape at an end portion of the carrier tape in the conveying direction;
a second stripping path having a path for guiding the cover tape stripped by the stripping section to the pair of rollers.

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