JP7474970B2 - Tape feeder and component placement device - Google Patents

Description

The present invention relates to a tape feeder that transports a carrier tape containing components and supplies the components to a component supply position, and a component mounting device equipped with this tape feeder.

Conventionally, component mounting devices that mount components on a board are known, and as a component supply means for such component mounting devices, a tape feeder that transports a carrier tape containing components and supplies the components to a component supply position is often used. The tape feeder includes a frame in which a carrier tape transport path is formed, a tape transport section that transports the carrier tape in the transport path, and a cover member that is attached to the frame so as to be able to swing and open/close a part of the transport path. The top tape peeled off from the base tape is pulled out upstream from a carrier tape pull-out opening provided in the cover member (for example, see Patent Document 1 below).

The top tape pulled out from the cover member to the upstream side in the above manner is sandwiched between two rollers that make up the top tape feed mechanism provided on the upstream side of the cover member, and then sent to a recovery area provided at the rear of the frame by the feeding action of the two rollers. The two rollers are configured to be easy to sandwich the top tape, but also to be able to feed the top tape reliably without causing slippage between the two rollers. Therefore, a spring member is generally used to bias one roller against the other roller.

International Publication No. 2015/186196

However, conventional tape feeders have a problem in that the top tape feed mechanism becomes large because space must be secured within the frame to accommodate the spring member.

The present invention aims to provide a tape feeder and component mounting device that can reduce the overall size of the tape feeder by downsizing the top tape feed mechanism.

The tape feeder of the present invention comprises a frame in which a transport path for a carrier tape having a top tape affixed to a base tape storing components is formed, a tape transport mechanism that transports the carrier tape in the transport path to position a component at a component supply position, and a top tape feeding mechanism having two rollers that perform a feeding operation while sandwiching the top tape that has been peeled off from the base tape of the carrier tape transported through the transport path by the tape transport mechanism, and at least one of the two rollers has an elastic member interposed between it and a shaft member that supports the roller, the shaft member has a groove provided on its outer periphery, and the elastic member is disposed in the groove .

The component mounting device of the present invention includes the tape feeder of the present invention described above and a mounting head that picks up components supplied by the tape feeder and mounts them on a board.

According to the present invention, the top tape feed mechanism can be made smaller, thereby reducing the overall size of the tape feeder.

FIG. 1 is a schematic configuration diagram of a component mounting device according to an embodiment of the present invention; FIG. 1 is a perspective view showing a carrier tape used in a component mounting device according to an embodiment of the present invention together with a reel; FIG. 1 is a perspective view of a portion of a carrier tape used in a component mounting apparatus according to an embodiment of the present invention; FIG. 2 is a side view of a tape feeder used in the component mounting apparatus according to the embodiment of the present invention; FIG. 2 is a side view of a portion of a tape feeder according to an embodiment of the present invention; FIG. 1 is a perspective view of a portion of a tape feeder according to an embodiment of the present invention; (a) and (b) are side views of a portion of a tape feeder according to an embodiment of the present invention. FIG. 1 is a perspective view of a tape feeder according to an embodiment of the present invention with a cover member in an open position; FIG. 2 is a side view of a portion of a tape feeder according to an embodiment of the present invention; FIG. 2 is a cross-sectional side view of a portion of a tape feeder according to an embodiment of the present invention; FIG. 1 is a cross-sectional perspective view of a portion of a tape feeder according to an embodiment of the present invention; 1A and 1B are cross-sectional views of a shaft member and a first roller provided in a tape feeder according to an embodiment of the present invention. 4A, 4B, and 4C are cross-sectional views of a shaft member and a first roller, illustrating how the first roller rotates due to rotation of the shaft member included in the tape feeder according to one embodiment of the present invention; FIG. 1 is a side view showing a state in which a top tape peeled off from a carrier tape is inserted into a top tape insertion opening of a cover member provided in a tape feeder according to an embodiment of the present invention. 10A and 10B are side cross-sectional views of the vicinity of a cover member illustrating a procedure for preparing a top tape for collection from a tape feeder according to an embodiment of the present invention; 10A and 10B are side cross-sectional views of the vicinity of a cover member illustrating a procedure for preparing a top tape for collection from a tape feeder according to an embodiment of the present invention; 10A and 10B are side cross-sectional views of the vicinity of a cover member illustrating a procedure for preparing a top tape for collection from a tape feeder according to an embodiment of the present invention; 1A and 1B are side cross-sectional views of the vicinity of a cover member, illustrating a procedure for feeding a short tape by a tape feeder according to an embodiment of the present invention; 1A and 1B are side cross-sectional views of the vicinity of a cover member, illustrating a procedure for feeding a short tape by a tape feeder according to an embodiment of the present invention; 1A and 1B are side cross-sectional views of the vicinity of a cover member, illustrating a procedure for feeding a short tape by a tape feeder according to an embodiment of the present invention; 1A and 1B are side cross-sectional views of the vicinity of a cover member, illustrating a procedure for feeding a short tape by a tape feeder according to an embodiment of the present invention; 1A and 1B are side cross-sectional views of the vicinity of a cover member, illustrating a procedure for feeding a short tape by a tape feeder according to an embodiment of the present invention; 1A and 1B are side cross-sectional views of the vicinity of a cover member, illustrating a procedure for feeding a short tape by a tape feeder according to an embodiment of the present invention;

The following describes an embodiment of the present invention with reference to the drawings. FIG. 1 shows a component mounting device 1 in one embodiment of the present invention. As shown in FIG. 1, the component mounting device 1 is equipped with a base 11, a board transport unit 12, a tape feeder 13, a mounting head 14, a head movement mechanism 15, and a component camera 16, and repeatedly performs a component mounting operation in which components BH are mounted on a board KB sent from an upstream process side and the board is conveyed to a downstream process side. In this embodiment, for convenience of explanation, the left-right direction as seen from the worker OP is the X-axis direction, the front-back direction as seen from the worker OP is the Y-axis direction, and the up-down direction is the Z-axis direction. In addition, in the Y-axis direction, the side in front of the worker OP may be referred to as the front-rear side, and the opposite side as the front side.

In FIG. 1, the board transport unit 12 is equipped with a pair of belt conveyors 12a extending in the X-axis direction on the base 11. The board transport unit 12 transports the board KB in the X-axis direction by simultaneously operating the pair of belt conveyors 12a, and positions the board KB at a predetermined work position. The tape feeder 13 is attached to a feeder cart FD connected to the front side of the base 11. The tape feeder 13 transports the carrier tape CT containing the parts BH, and supplies the parts BH to the part supply position 13K (FIG. 1).

As shown in FIG. 2, the carrier tape CT is supplied wound around a reel RL. As shown in FIG. 3 (FIG. 3 is an enlarged view of area AR1 in FIG. 2), the carrier tape CT is configured by attaching a top tape TT to the upper surface of a base tape BT. The base tape BT has a number of pockets PT arranged in a row in the longitudinal direction, and each pocket PT contains a component BH. The top tape TT is attached to the base tape BT to prevent the component BH from falling out of each pocket PT. The base tape BT has rows of feed holes KH that engage with the outer circumferential pins of three sprockets (transport sprocket 35, positioning sprocket 36, and discharge sprocket 38; see FIG. 4) of the tape feeder 13, which will be described later, and are arranged parallel to the rows of pockets PT (FIG. 3).

In FIG. 1, the mounting head 14 has multiple nozzles 14N that extend downward (see also FIG. 4). The head movement mechanism 15 is, for example, a Cartesian coordinate robot, and moves the mounting head 14 in a horizontal plane. The mounting head 14 picks up the component BH that the tape feeder 13 has supplied to the component supply position 13K by suction to the lower end of the nozzle 14N.

In FIG. 1, the part camera 16 is attached to the base 11 with its imaging field of view facing upward. The part camera 16 captures an image of the part BH picked up by the mounting head 14 using the nozzle 14N from below.

In FIG. 1, the component mounting device 1 is equipped with a control device 17. The control device 17 controls the operations of the board transport section 12, each tape feeder 13, the mounting head 14, the head moving mechanism 15, and the component camera 16. An input/output panel PN is connected to the control device 17. An operator OP can perform input operations to the control device 17 through the input/output panel PN. Meanwhile, the control device 17 can provide the operator OP with necessary information and necessary operating instructions through the input/output panel PN.

When performing component mounting work, the control device 17 first operates the board transport unit 12 to receive the board KB from the upstream process side and positions the board KB at a predetermined position. After positioning the board KB, it operates the tape feeder 13 to supply components BH to the component supply position 13K, while operating the head movement mechanism 15 to have the mounting head 14 repeatedly perform component transfer operations. The component transfer operation consists of an operation of adsorbing the components BH supplied by the tape feeder 13 to the nozzle 14N, an operation of having the component camera 16 capture an image of the adsorbed components BH, and an operation of mounting the components BH on the board KB based on the image of the components BH captured by the component camera 16.

When all the components BH to be mounted on the board KB have been mounted by repeatedly executing the supply operation of the components BH by the tape feeder 13 and the component transfer operation by the mounting head 14, the control device 17 operates the board transport unit 12 to transport the board KB to the downstream process side. This completes the component mounting work for one board KB.

Next, the configuration and operation of the tape feeder 13 will be described. As shown in FIG. 4, the tape feeder 13 includes a frame 21 in which a transport path 21L for the carrier tape CT is formed, a tape transport mechanism 22 provided in the frame 21 for transporting the carrier tape CT in the transport path 21L, a cover member 23, and a top tape feed mechanism 24. In this embodiment, in the Y-axis direction, the side where the tape inlet 21K of the tape feeder 13 is located is defined as the upstream side, and the side where the tape discharge path 21T is located is defined as the downstream side. In addition, the downstream end of the carrier tape CT is defined as the rear end, and the upstream end is defined as the front end.

In FIG. 4, the frame 21 has a shape that is wide overall in the front-to-rear direction (Y-axis direction) and the up-down direction (Z-axis direction), and the transport path 21L is formed from the upstream side of the frame 21 toward the downstream side. In detail, the transport path 21L extends downstream from the tape inlet 21K that opens at the upstream end of the frame 21, and then extends diagonally upward from the middle part of the frame 21 in the Y-axis direction. Then, after extending downstream with the upper part of the frame 21 exposed upward, it opens to the outside of the frame 21 at the downstream end of the frame 21 as the tape discharge passage 21T.

In FIG. 4, a top tape recovery area 21S is formed at the upper upstream side of the frame 21 to recover (store) the top tape TT peeled off from the base tape BT of the carrier tape CT. A connection portion 21R is provided at the lower part of the frame 21 to connect to the feeder cart FD.

As shown in FIG. 5 (FIG. 5 is an enlarged view of area AR2 in FIG. 4), the tape transport mechanism 22 is provided in the downstream area of the frame 21. The tape transport mechanism 22 includes a drive motor 31, a drive gear 32, a reduction gear 33, a first intermediate gear 34, a transport sprocket 35, a positioning sprocket 36, a second intermediate gear 37, and an ejection sprocket 38.

The drive motor 31 is installed below the downstream side of the frame 21, and the drive gear 32 is attached to the drive shaft of the drive motor 31. The drive motor 31 can rotate the drive gear 32 in either the forward or reverse direction.

The reduction gear 33 is driven by the drive gear 32, and reduces the speed of the rotation of the drive motor 31 while increasing the torque and transmitting it to the first intermediate gear 34. The first intermediate gear 34 meshes with both the conveying sprocket 35 and the positioning sprocket 36, and rotates the conveying sprocket 35 and the positioning sprocket 36 in the same direction.

The transport sprocket 35 is installed below the part of the transport path 21L that extends diagonally upward in the middle, and its outer circumferential pins pass through the transport path 21L. The positioning sprocket 36 is located above the downstream side of the transport sprocket 35 (below the part of the transport path 21L that extends almost horizontally), and its outer circumferential pins pass through the transport path 21L. The discharge sprocket 38 is located downstream of the positioning sprocket 36 (below the part of the transport path 21L that extends almost horizontally), and its outer circumferential pins pass through the transport path 21L.

The second intermediate gear 37 is driven by the positioning sprocket 36 and rotates the discharge sprocket 38 in the same direction as the transport sprocket 35 and the positioning sprocket 36. In this way, the tape transport mechanism 22 is configured to rotate the transport sprocket 35, the positioning sprocket 36, and the discharge sprocket 38 in the same direction by the rotational power of the drive motor 31.

As described above, the outer peripheral pins of the transport sprocket 35, the positioning sprocket 36, and the discharge sprocket 38 pass through the transport path 21L, so the carrier tape CT in the transport path 21L is transported by the three sprockets (transport sprocket 35, positioning sprocket 36, and discharge sprocket 38) that rotate in the same direction from the upstream side to the downstream side of the frame 21 (from left to right in FIG. 4) (referred to as the "downstream direction"), or from the downstream side to the upstream side of the frame 21 (from right to left in FIG. 4) (referred to as the "upstream direction"). Each sprocket (transport sprocket 35, positioning sprocket 36, and discharge sprocket 38) transports the carrier tape CT by engaging the outer peripheral pins with the feed holes KH of the carrier tape CT as it rotates.

As shown in Figures 4, 5 and 6 (Figure 6 is a view of area AR1 viewed diagonally from above), a shaft member 41 is provided at the upper part of the middle part in the Y-axis direction of the frame 21 (above the transport sprocket 35). This shaft member 41 extends laterally (in the X-axis direction) of the frame 21 and pivots the rear end of the cover member 23. Therefore, the cover member 23 can freely swing about the shaft member 41 between a position where it is closed relative to the frame 21 (referred to as the "closed position"; Figure 7(a)) and a position where it is open relative to the frame 21 (referred to as the "open position"; Figure 7(b)).

When the cover member 23 is closed (positioned in the closed position), the upper areas of the positioning sprocket 36 and the discharge sprocket 38, and a portion of the upper area downstream of the transport sprocket 35 are covered by the cover member 23. On the other hand, when the cover member 23 is open (positioned in the open position), the transport path 21L upstream of the shaft member 41 is exposed upward. In this way, the cover member 23 is configured to swing relative to the frame 21 to open and close a portion of the transport path 21L. When the cover member 23 is positioned in the open position, as shown in Figures 7(b) and 8, a transport path intermediate opening 42, which is an opening that opens into the middle part of the transport path 21L, is formed at the base of the cover member 23 (near the shaft member 41).

In Figures 4, 5 and 6, a component removal opening 43 is provided in the middle of the cover member 23 in the Y-axis direction, which opens above the component supply position 13K when the cover member 23 is in the closed position. In addition, a pull-out opening 44 is provided upstream of the component removal opening 43 of the cover member 23, for pulling out the top tape TT peeled off from the base tape BT of the carrier tape CT transported in the transport path 21L to the outside of the frame 21.

As the carrier tape CT is transported downstream along the transport path 21L, the top tape TT is pulled out from the pull-out opening 44 before it reaches the component supply position 13K. As a result, the pocket PT provided in the base tape BT is exposed upward when it reaches the component supply position 13K, and the mounting head 14 can suck and remove the component BH located at the component supply position 13K using the nozzle 14N through the component removal opening 43 of the cover member 23 (Figure 4).

6 and 7(a) and (b), a top tape insertion opening 45 is provided at a position upstream of the pull-out opening 44 in the cover member 23. The tip of the top tape TT pulled out from the pull-out opening 44 is inserted into this top tape insertion opening 45 (details will be described later).

In Figures 6 and 7(a) and (b), a roller member 46 with a rotation axis arranged in the lateral direction (X-axis direction) of the cover member 23 is provided between the top tape insertion opening 45 and the withdrawal opening 44 and is exposed on the upper surface side of the cover member 23. A tape presser 47 is provided on the lower surface side of the cover member 23 to press down the carrier tape CT on the transport path 21L from above when the cover member 23 is in the closed position.

As shown in Figures 7(b) and 8, a tape insertion guide 48 is provided in the frame 21 near the intermediate opening 42 of the transport path. The tape insertion guide 48 is used when inserting the rear end of a relatively short carrier tape CT (described later), and has a vertical portion 48a extending upward from the frame 21 and a horizontal portion 48b that projects horizontally inward from the upper end of the vertical portion 48a. The tape insertion guide 48 is exposed when the cover member 23 is open (positioned in the open position).

As shown in Figures 5 and 9 (Figure 9 is a side view of area AR3 in Figure 5 from the opposite side), the top tape feed mechanism 24 includes a first transmission gear 51, a second transmission gear 52, a third transmission gear 53, a first roller 54, a second roller 55, a third roller 56, and a manual operation unit 57. When the transport sprocket 35 rotates in a direction to advance the carrier tape CT downstream, the rotation of the transport sprocket 35 is transmitted to the first transmission gear 51 via a drum coaxial with the first transmission gear 51.

In Figures 5 and 9, the second transmission gear 52 meshes with the first transmission gear 51, and the third transmission gear 53 meshes with the second transmission gear 52. Therefore, the third transmission gear 53 rotates in the same direction as the first transmission gear 51. One end of the aforementioned shaft member 41 is connected to the third transmission gear 53, so that the shaft member 41 rotates integrally with the third transmission gear 53.

Figure 10 is an enlarged view of area AR4 in Figure 5, and Figure 11 is a cross-sectional perspective view taken along the line V1-V1 in Figure 10. Figure 12(a) is a cross-sectional view taken along the line V2-V2 in Figure 11, and Figure 12(b) is a cross-sectional view taken along the line V3-V3 in Figure 11. As shown in Figures 10 and 11, the first roller 54 has a hollow portion 54H that extends through the frame 21 in the lateral direction (X-axis direction), and the shaft member 41 is inserted loosely into the hollow portion 54H (Figure 11).

The hollow portion 54H of the first roller 54 has a portion where the inner cross section is circular (the portion of the cross section shown in FIG. 12(a)) and a portion where the inner cross section is rectangular (the portion of the cross section shown in FIG. 12(b)), and the shaft member 41 also has a portion where the outer cross section is circular (the portion of the cross section shown in FIG. 12(a)) and a portion where the outer cross section is rectangular (the portion of the cross section shown in FIG. 12(b)). The portion where the inner cross section of the hollow portion 54H is circular and the portion where the outer cross section of the shaft member 41 is circular face each other, and an elastic member 66 is interposed between them (FIGS. 11 and 12(a)).

In this embodiment, the elastic member 66 is made of an annular member (O-ring) and is fitted onto the outer surface of the shaft member 41 at a portion where the cross section is circular (FIG. 12(a)). As shown in FIG. 11, two (i.e., multiple) elastic members 66 are arranged in the axial direction of the shaft member 41, and the position of the first roller 54 relative to the shaft member 41 is stabilized. In this way, the first roller 54 is supported by the shaft member 41 via the elastic members 66 and is arranged coaxially with the third transmission gear 53.

11 and 12(b), the inner surface of the hollow portion 54H having a rectangular cross section and the outer surface of the shaft member 41 having a rectangular cross section are separated when the shaft member 41 is not rotating. When the third transmission gear 53 is driven and the shaft member 41 rotates, the shaft member 41 abuts a part of its outer surface (the part of the outer surface having a rectangular cross section) against a part of the inner surface of the hollow portion 54H (the part of the inner surface having a rectangular cross section), causing the first roller 54 to rotate (FIG. 13(a) → FIG. 13(b) → FIG. 13(c)). Thus, in this embodiment, the shaft member 41 is driven by the power of the tape transport mechanism 22 (specifically, the power of the drive motor 31), and the first roller 54 is a roller (i.e., a drive roller) that is driven by the rotation of the shaft member 41 being transmitted thereto.

In Figures 7(a), (b) and 10, the second roller 55 and the third roller 56 are each attached to the cover member 23 and are each externally in contact (meshed) with the first roller 54. In other words, the second roller 55 and the third roller 56 are each rollers that are rotated by the first roller 54 (i.e., driven rollers).

In Figures 5 and 9, when the transport sprocket 35 rotates in the forward direction, i.e., in the direction that advances the carrier tape CT downstream (arrow R1 shown in these figures), the third transmission gear 53 and the first roller 54 rotate in the opposite direction to the transport sprocket 35 (arrow R2 shown in Figures 9 and 10) via the first transmission gear 51 and the second transmission gear 52. In addition, the second roller 55 and the third roller 56 each rotate in the opposite direction to the first roller 54 (arrows R3 and R4 shown in Figure 10).

5 and 9, the manual operation unit 57 is provided downstream of the first transmission gear 51. The manual operation unit 57 is a disk-shaped member with outer teeth, and is externally tangentially meshed with the first transmission gear 51. The upper end of the manual operation unit 57 is exposed upward from a notch 21D (FIG. 9) formed in a part of the upper part of the frame 21, and the exposed upper end of the manual operation unit 57 can be fed downstream (arrow F shown in FIG. 9). When the operator OP feeds the upper end of the manual operation unit 57 downstream, the first roller 54 rotates in the same direction as when the conveying sprocket 35 is rotated forward, via the first transmission gear 51, the second transmission gear 52, the third transmission gear 53, and the shaft member 41.

The manual operation unit 57 is operated when the drive motor 31 is not operating and the transport sprocket 35 is not being driven by the drive motor 31. When the manual operation unit 57 is moved downstream in this state, the transport sprocket 35 does not rotate and remains stopped because a slip clutch is provided between the first transmission gear 51 and the adjacent drum.

In FIG. 10, the cover member 23 is provided with a roller cover 61 that covers the upper area between the first roller 54 and the second roller 55. The lower surface of the roller cover 61 is formed with a tape guide surface 62 that has a curved shape corresponding to the outer peripheral shape of the first roller 54.

10 and 11, a guide surface 63 having a curved shape corresponding to the outer peripheral shape of the second roller 55 is formed below the second roller 55 of the tape holder 47 of the cover member 23. A pointed portion 64 that is pointed toward the upstream side is formed at the upstream end of the tape holder 47. The pointed portion 64 is located in the transport path 21L, and as described later, serves as a trigger for peeling the top tape TT from the carrier tape CT passing downstream in the transport path 21L. The tip of the top tape TT lifted by air is guided by the pointed portion 64 and enters between the first roller 54 and the second roller 55, and the top tape TT is taken up by the first roller 54 and the second roller 55, so that the top tape TT is peeled off from the carrier tape CT.

In this embodiment, the two rollers consisting of the first roller 54 and the second roller 55 are provided above the transport path 21L and serve as a peeling section that performs a feeding operation while sandwiching the top tape TT from the base tape BT of the carrier tape CT transported through the transport path 21L by the tape transport mechanism 22.

In FIG. 10, an air outlet 71 that opens upward toward the transport path 21L is provided below the first roller 54 in the frame 21. An air blowing unit 73 is connected to the air outlet 71 via an air passage 72. The air blowing unit 73 operates under the control of the control device 17, and blows air from below into the transport path 21L through the air passage 72 and the air outlet 71. The air passage 72 is provided at any location inside the tape feeder 13.

In FIG. 10, an operating piece passage 81 that opens into the transport path 21L is provided at a position downstream of the air outlet 71 in the frame 21 and extends in the vertical direction. An operating piece 82 is housed in the operating piece passage 81 in the vertical direction.

The operating piece 82 is movable within the operating piece passage 81 between a position where the upper end protrudes into the transport path 21L (referred to as the "protruding position") and a position where the upper end does not protrude into the transport path 21L (referred to as the "non-protruding position"). The operating piece 82 is biased toward the protruding position by the biasing means 83. Therefore, when the carrier tape CT is not located directly above the operating piece passage 81, the operating piece 82 is biased upward by the biasing means 83 and is positioned at the protruding position with its upper end protruding into the transport path 21L (FIG. 10). However, when the carrier tape CT is located directly above the operating piece passage 81, the upper end of the operating piece 82 is pushed into the operating piece passage 81 by the carrier tape CT and is positioned at the non-protruding position.

In FIG. 10, information on the position of the operating piece 82 in the operating piece passage 81 is detected by the operating piece position detection unit 84 and transmitted to the control device 17. Based on the information on the position of the operating piece 82 transmitted from the operating piece position detection unit 84, the control device 17 determines whether the carrier tape CT is located directly above the operating piece passage 81, i.e., whether the carrier tape CT is present at a position directly above the operating piece passage 81. The position where the operating piece passage 81 is thus provided is the position where the presence or absence of the carrier tape CT is to be detected, and this position (the position upstream of the apex 64) will be referred to below as the "tape detection position."

When setting the carrier tape CT in the tape feeder 13, the operator OP, with the cover member 23 open (positioned in the open position) relative to the frame 21, inserts the front end of the carrier tape CT pulled out from the reel RL toward the downstream side through the tape inlet 21K of the frame 21. The operator OP then further feeds the carrier tape CT downstream so that the front end of the carrier tape CT protrudes downstream from the intermediate transport path opening 42. The operator then peels off the top tape TT from the base tape BT of the carrier tape CT protruding downstream from the intermediate transport path opening 42, and pulls out the leading end (front end) of the top tape TT that has been peeled off through the pull-out opening 44 of the cover member 23 to the top surface side of the cover member 23. The operator then inserts the leading end of the top tape TT pulled out through the pull-out opening 44 from the top surface side of the cover member 23 into the top tape insertion opening 45 (FIG. 14).

When the tip of the top tape TT is inserted into the top tape insertion opening 45, the tip of the top tape TT moves along the guide surface 63 formed on the tape retainer 47 of the cover member 23 and enters the contact portion (meshing portion) between the first roller 54 and the second roller 55 (FIG. 15). At this time, the guide surface 63 of the tape retainer 47 of the cover member 23 functions as a top tape guide that guides the tip of the top tape TT inserted into the top tape insertion opening 45 between the first roller 54 and the second roller 55.

When the leading end of the top tape TT inserted from the top tape insertion opening 45 enters the contact area between the first roller 54 and the second roller 55, the operator OP closes the cover member 23 against the frame 21 (see FIG. 16, arrow M in the figure). As a result, the second roller 55 and the third roller 56 connected to the cover member 23 rotate on their own axes while revolving around the first roller 54 (in FIG. 16, they rotate in the clockwise direction as indicated by arrows R3 and R4 while revolving around the first roller 54 in the clockwise direction).

As described above, the second roller 55 rotates while revolving around the first roller 54, so that the tip of the top tape TT is sandwiched between the first roller 54 and the second roller 55 and transported upward. At this time, the direction in which the top tape TT is transported is the direction in which the top tape TT is peeled off from the base tape BT (the direction from below to above between the first roller 54 and the second roller 55 in FIG. 16), and the rotation direction of the first roller 54 and the second roller 55 in which the top tape TT is peeled off from the base tape BT is hereinafter referred to as the "peeling direction". When the tip of the top tape TT is thus sandwiched between the first roller 54 and the second roller 55, preparation for collection of the top tape TT is complete.

In this way, the tape feeder 13 in this embodiment is equipped with a top tape feed mechanism 24 having two rollers (first roller 54 and second roller 55) that perform a feed operation while sandwiching the top tape TT peeled off from the base tape BT of the carrier tape CT transported in the transport path 21L by the tape transport mechanism 22, and when the cover member 23 is swung from the open position to the closed position, the two rollers move relative to each other to sandwich the tip of the top tape TT. In detail, the first roller 54 is attached to the frame 21, and the second roller 55 is attached to the cover member 23 and is in contact with the first roller 54, and when the cover member 23 is swung from the open position to the closed position, the second roller 55 rotates while revolving around the first roller 54, and sandwiches the tip of the top tape TT between the first roller 54. Therefore, in the preparation work for collecting the top tape TT, it is not necessary to perform a troublesome work such as widening the gap between the two rollers to sandwich the top tape TT.

As described above, the elastic member 66 is interposed between the first roller 54 and the shaft member 41, which is the drive shaft of the first roller 54. Therefore, the first roller 54 can move slightly in the radial direction of the shaft member 41 relative to the shaft member 41, and the top tape TT can enter between the first roller 54 and the second roller 55. After the top tape TT enters between the first roller 54 and the second roller 55, the top tape TT is firmly sandwiched between the first roller 54 and the second roller 55 due to the force of the elastic member 66 biasing the first roller 54 against the second roller 55.

In this manner, the top tape feed mechanism 24 of the tape feeder 13 in this embodiment is configured such that one of the two rollers (first roller 54 and second roller 55) that perform the feed operation while sandwiching the top tape TT peeled off from the base tape BT of the carrier tape CT is the first roller 54, and an elastic member 66 is interposed between the roller and the shaft member 41 that supports the roller, thereby ensuring the retention of the top tape TT by the two rollers while also allowing a gap to be formed between the two rollers as necessary.

As described above, the operator OP swings the cover member 23 from the open position to the closed position to pinch the leading end of the top tape TT peeled off from the base tape BT between the first roller 54 and the second roller 55, and then operates the upper end of the manual operation unit 57 in the downstream direction (the direction of the arrow F in FIG. 9). This causes the first roller 54 and the second roller 55 to rotate in a direction in which the top tape TT is peeled off from the base tape BT (peeling direction), and the top tape TT is further transported above the contact portion (interlocking portion) of the first roller 54 and the second roller 55.

The top tape TT, which is transported further upward by the operation of the manual operation unit 57, is guided by the tape guide surface 62 of the roller cover 61 and proceeds along the outer circumference of the first roller 54, and then enters the contact portion (meshing portion) of the first roller 54 and the third roller 56. The third roller 56 is rotated by the first roller 54 in the opposite direction (arrows R3 and R4 shown in FIG. 17) to the rotation direction of the first roller 54 (arrow R2 shown in FIG. 17), so that the tip of the top tape TT advances upstream, that is, into the top tape recovery area 21S, while being sandwiched between the first roller 54 and the third roller 56 (FIG. 17). When an appropriate tension is applied to the top tape TT, which is drawn out upstream from the drawing opening 44 of the cover member 23, the operator OP ends the operation of the manual operation unit 57.

After applying an appropriate tension to the top tape TT by operating the manual operation unit 57, the operator OP performs the required operation from the input/output panel PN and causes the component mounting device 1 to start the component mounting operation through the control device 17. When the control device 17 causes the component mounting device 1 to perform the component mounting operation, it sends a command signal to the tape feeder 13 and causes the drive motor 31 to intermittently rotate in the forward direction so that the carrier tape CT is transported downstream in the transport path 21L. This causes the transport sprocket 35, positioning sprocket 36, and discharge sprocket 38 to rotate intermittently in synchronization, and the carrier tape CT is pitch-fed in the transport path 21L. At this time, the transport sprocket 35 transfers the carrier tape CT to the positioning sprocket 36, and the positioning sprocket 36 operates to transfer the carrier tape CT to the discharge sprocket 38.

The pitch feed interval of the carrier tape CT caused by the intermittent rotation of the drive motor 31 corresponds to the interval between the pockets PT on the carrier tape CT, and when the carrier tape CT stops on the transport path 21L, the pocket PT is located below the component removal opening 43 of the cover member 23. Therefore, the mounting head 14 can suck and remove the component BH from the component removal opening 43 using the nozzle 14N.

After the pocket PT passes under the component removal opening 43 (i.e., the component supply position 13K), the carrier tape CT is discharged to the outside of the tape feeder 13 through the tape discharge passage 21T at the front end of the frame 21 (Figure 4). Since the discharge sprocket 38 is provided near the entrance of the tape discharge passage 21T, the rear end of the carrier tape CT can also be reliably discharged from the tape discharge passage 21T.

Meanwhile, the top tape TT inserted into the top tape insertion opening 45 of the cover member 23 is transported upstream by the top tape feed mechanism 24. Specifically, as the first roller 54 rotates, the top tape TT is transported while being sandwiched between the first roller 54 and the second roller 55, and further between the first roller 54 and the third roller 56. As a result, the top tape TT pulled out from the pull-out opening 44 is pulled upstream, and the top tape TT is peeled off from the base tape BT.

The top tape TT transported upstream by the top tape feed mechanism 24 is stored in the top tape recovery area 21S (Figure 4). As described above, the first roller 54 is driven by the drive motor 31 in the same manner as the transport sprocket 35, the positioning sprocket 36, and the discharge sprocket 38, so that the recovery and transport operation of the top tape TT is performed in conjunction with the transport operation of the carrier tape CT. Here, the top tape TT between the pull-out opening 44 and the top tape insertion opening 45 moves upstream while abutting against the aforementioned roller member 46 provided on the cover member 23 and rolling the roller member 46.

In this manner, in the tape feeder 13 of this embodiment, the first roller 54, like the transport sprocket 35, the positioning sprocket 36, and the discharge sprocket 38, is driven by the power of the tape transport mechanism 22, and a single power source (drive motor 31) transports the carrier tape CT and collects the top tape TT. As described above, the mode in which the carrier tape CT inserted from the tape inlet 21K is transported from upstream to downstream to supply the parts BH is called the "normal operation mode."

In the present embodiment, the tape feeder 13 can be used to supply components even with a carrier tape CT that is relatively short in length (hereinafter referred to as "short tape CT0"). This is explained below.

When supplying components using the short tape CT0 with the tape feeder 13, the operator OP first opens the cover member 23 relative to the frame 21 to the open position (Fig. 7(a) → Fig. 7(b)). When the cover member 23 is opened, a transport path intermediate opening 42 is formed downstream of the shaft member 41, which is the swing support for the cover member 23, and the tape insertion guide 48 is exposed.

When the operator OP sets the short tape CT0 in the tape feeder 13, the operator OP makes sure that the tip of the top tape TT is formed with a top tape protrusion TS that is a predetermined length (e.g., about 5 to 20 mm) longer than the front end of the base tape BT. Then, after performing an operation on the input/output panel PN to supply components using the short tape CT0, the operator inserts the rear end of the short tape CT0 from the transport path intermediate opening 42 toward the upstream side (Figure 18, arrow SN shown in the figure). At this time, the operator OP makes sure that the rear end of the short tape CT0 passes under the horizontal portion 48b of the tape insertion guide 48, so that the rear end of the short tape CT0 can be easily inserted into the transport path 21L.

As described above, when an operation is performed on the input/output panel PN to supply components using the short tape CT0, the control device 17 transitions to the "tape set mode." The operation of the tape feeder 13 in the tape set mode is described below.

After inserting the rear end of the short tape CT0 into the transport path 21L through the transport path intermediate opening 42, the operator OP closes the cover member 23 (arrow M in FIG. 19). As a result, the short tape CT0 inserted into the transport path 21L is pressed against the transport path 21L by the tape presser 47 of the cover member 23, and the operating piece 82, which was in the protruding position until then, is pushed downward by the short tape CT0 and moves to a non-protruding position (arrow Y1 in FIG. 19).

Such movement of the operating piece 82 (movement from the protruding position to the non-protruding position) is detected by the operating piece position detector 84, and the control device 17 thereby detects the state in which the short tape CT0 is inserted into the transport path 21L. When the control device 17 detects the state in which the short tape CT0 is inserted into the transport path 21L, it operates the drive motor 31 to rotate the transport sprocket 35 in a direction (reverse direction) in which the short tape CT0 is transported upstream (arrow R5 shown in FIG. 20). As a result, the short tape CT0 is transported upstream on the transport path 21L (arrow KS1 shown in FIG. 20). In detail, the front end of the short tape CT0 (i.e., the carrier tape CT) is moved upstream of the peeling position near the apex 64.

When the short tape CT0 is transported upstream on the transport path 21L and the front end of the short tape CT0 (the front end of the base tape BT) passes the tape detection position and the operation piece 82 is no longer pressed by the short tape CT0, the operation piece 82, which was in the non-protruding position until then, returns to the protruding position (arrow Y2 shown in FIG. 20). The control device 17, which has received such movement information of the operation piece 82, stops the rotation of the transport sprocket 35 at the timing when the front end of the short tape CT0 (the front end of the base tape BT) is located upstream of the air outlet 71 (left side in FIG. 20). Then, it notifies the input/output panel PN that parts supply is possible. Thus, in this embodiment, the operation piece 82 is a detection means that detects that the front end of the carrier tape CT transported upstream by the tape transport mechanism 22 has passed the tape detection position on the transport path 21L.

The operating piece position detection unit 84 may detect the timing at which the leading end (front end) of the carrier tape CT moving upstream passes, and the control device 17 may switch the transport direction of the carrier tape CT from the upstream direction to the downstream direction based on the detection result of this timing.

When the input/output panel PN indicates that parts can be supplied, the operator OP operates the input/output panel PN to start the operation. When the control device 17 detects that the input/output panel PN has been operated to start the operation, it operates the drive motor 31 and rotates the transport sprocket 35 in the forward direction (arrow R1 shown in FIG. 21). As a result, the first roller 54 and the second roller 55 rotate in the peeling direction (arrows R2 and R3 shown in FIG. 21), and the third roller 56 also rotates in the same direction as the second roller 55 (arrow R4 shown in FIG. 21). As a result, the short tape CT0 is transported downstream on the transport path 21L. In this way, in this embodiment, the tape transport mechanism 22 transports the carrier tape CT downstream after the operation piece 82, which is the detection means, detects that the front end of the carrier tape CT has passed the tape detection position in the upstream direction.

When the short tape CT0 is transported downstream on the transport path 21L by the forward rotation of the transport sprocket 35 (arrow KS2 shown in FIG. 21), the top tape protrusion TS is pushed up (upward) away from the transport path 21L by air blown out from the air outlet 71. As a result, the top tape protrusion TS passes above the peak 64 and approaches the contact portion (meshing portion) of the first roller 54 and the second roller 55, and is sandwiched between the first roller 54 and the second roller 55, which are rotating in the peeling direction (FIG. 22). Then, air is blown out for a short time at a timing when it can blow up the top tape protrusion TS, and the top tape TT is pulled in by the rotation of the first roller 54 and the second roller 55, so that the top tape TT is peeled off from the base tape BT.

When the short tape CT0 is further transported downstream by the transport sprocket 35, the front end of the short tape CT0 (the front end of the base tape BT) advances downstream while pushing the operation piece 82 from the protruding position to the non-protruding position. Meanwhile, the leading end of the top tape TT including the top tape protruding portion TS is transported in the direction to be peeled off from the base tape BT while being sandwiched between the first roller 54 and the second roller 55, and is further transported upstream while being sandwiched between the first roller 54 and the third roller 56, and is sent into the top tape recovery area 21S (Figure 23). Thereafter, the short tape CT0 is handed over from the transport sprocket 35 to the positioning sprocket 36, and further to the discharge sprocket 38, and is finally discharged from the tape discharge passage 21T to the outside of the frame 21.

In this manner, in the tape feeder 13 of this embodiment, when the rear end of the carrier tape CT (short tape CT0) is inserted through the transport path intermediate opening 42, which is an opening that opens into the middle part of the transport path 21L, the tape transport mechanism 22 transports the carrier tape CT in the upstream direction, and then transports it in the downstream direction, peeling off the top tape TT by the rotation of the first roller 54 and the second roller 55. Therefore, even with the short tape CT0, which is relatively short in length, it is possible to use the transport path 21L used when transporting a normal carrier tape CT as is.

As described above, the tape feeder 13 in this embodiment is provided with a top tape feed mechanism 24 having two rollers (first roller 54 and second roller 55) that sandwich the top tape TT peeled off from the base tape BT of the carrier tape CT transported in the transport path 21L by the tape transport mechanism 22, and performs a feeding operation while sandwiching the top tape TT. One of the two rollers, the first roller 54, is configured with an elastic member 66 interposed between it and the shaft member 41 that supports the first roller 54, so that while ensuring the retention of the top tape TT by the two rollers, a gap can be formed between the two rollers as necessary. Therefore, a spring member that biases one roller against the other roller as in the conventional case is not necessary, and the size of the top tape feed mechanism 24 can be reduced, so that the entire tape feeder 13 can be made smaller.

Although the embodiment of the present invention has been described so far, the present invention is not limited to the above, and various modifications are possible. For example, the configuration of the tape transport mechanism 22 shown in the above embodiment is one example, and other configurations may be provided as long as the carrier tape CT on the transport path 21L can be transported. In addition, in the above embodiment, only one (first roller 54) of the two rollers (first roller 54 and second roller 55) constituting the top tape feed mechanism 24 is configured to have an elastic member 66 between the roller and the shaft member 41 supporting the roller, but each of the two rollers may be configured to have an elastic member 66 between the roller and the shaft member supporting the roller. In addition, the top tape protrusion TS in the short tape CT0 does not have to be the top tape TT itself, and may be a long and thin film member attached to the front end of the top tape TT.

To provide a tape feeder and component mounting device that can reduce the overall size of the tape feeder by downsizing the top tape feed mechanism.

REFERENCE SIGNS LIST 1 Component mounting device 13 Tape feeder 13K Component supply position 14 Mounting head 21 Frame 21L Transport path 22 Tape transport mechanism 24 Top tape feed mechanism 41 Shaft member 54 First roller (one roller)
54H: Hollow portion 55: Second roller 66: Elastic member CT: Carrier tape BT: Base tape TT: Top tape BH: Part

Claims (7)

a frame on which a transport path for a carrier tape is formed, the carrier tape being made of a base tape containing components and a top tape attached thereto;
a tape transport mechanism that transports the carrier tape in the transport path to position a component at a component supply position;
a top tape feeding mechanism having two rollers that perform a feeding operation while sandwiching the top tape that has been peeled off from the base tape of the carrier tape that is fed through the feed path by the tape feeding mechanism,
At least one of the two rollers has an elastic member interposed between it and a shaft member supporting the roller,
The shaft member has a groove formed on an outer periphery thereof,
The resilient member is disposed within the groove. The tape feeder of claim 1, wherein the elastic member is an annular member fitted onto the shaft member. A tape feeder as described in claim 2, wherein the elastic member is an O-ring. The groove is provided in a plurality of grooves in the axial direction of the shaft member ,
4. The tape feeder according to claim 2, wherein the elastic members are disposed in the plurality of grooves. one of the two rollers is a drive roller that is driven by the rotation of the shaft member, the one roller has a hollow portion into which the shaft member is loosely fitted, and the elastic member is interposed between the inner surface of the hollow portion and the shaft member;
5. The tape feeder according to claim 1, wherein the shaft member rotates the one roller by abutting a part of an outer surface against a part of an inner surface of the hollow portion. The tape feeder according to claim 5, wherein the shaft member rotates one of the rollers by abutting a portion of the outer surface having a rectangular cross section against a portion of the inner surface of the hollow portion of the one of the rollers having a rectangular cross section. A component mounting device comprising a tape feeder according to any one of claims 1 to 6 and a mounting head that picks up components supplied by the tape feeder and mounts them on a board.

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