JP2022130834A - Tape cassette supply device, component mounting system, and tape cassette supply method - Google Patents

Abstract

To provide a tape cassette supply device, a component mounting system, and a tape cassette supply method capable of automatically transferring a tape cassette to the component mounting device and inserting a carrier tape pulled out from the tape cassette into the component supply unit.SOLUTION: A tape cassette supply device 1H that supplies a storage cassette 22B containing a carrier tape CT to a component supply portion 1B of a component mounting device 1T includes: a cassette transfer portion 63 that transfers the storage cassette 22B taken out from a cassette stock portion 74 to the component supply portion 1B via a tape feeding position set in the vicinity of a tape entrance 23G of a tape feeder 23; and a tape feeding portion 64 that feeds the leading portion of the carrier tape CT to the tape entrance 23G after holding the leading portion of the carrier tape CT pulled out from the storage cassette 22B when the storage cassette 22B is positioned at the tape feeding position by the cassette transfer unit 63.SELECTED DRAWING: Figure 48

Description

The present invention relates to a tape cassette supply device, a component mounting system, and a tape cassette supply method for supplying a tape cassette storing a roll of carrier tape to a component mounting device.

Conventionally, a component mounting apparatus for mounting components on a substrate is known, and a tape feeder using a carrier tape is often used as a component supply unit for supplying components to the component mounting apparatus. The carrier tape is a tape member containing components, is transported and stored while being wound around a core of a reel as a tape holder, and is pulled out from the reel and supplied to a tape feeder when used.

In addition, it has been proposed to eliminate the tape holder such as the reel described above and transport, store, and use the carrier tape in the form of a disk-shaped rolled body without a core (for example, the following patent document 1). Patent Literature 1 discloses a technique in which a roll body is stored in a partially opened case-like storage device, and the storage device in which the roll body is stored can be set in a tape feeder.

WO2020/202737

As described above, in a component mounting apparatus that uses a carrier tape stored in a storage device (hereinafter referred to as a tape cassette) in the form of a roll, the tape cassette is automatically supplied to the component mounting apparatus. is preferred. However, there is no device that not only automatically transfers the tape cassette to the component mounting device, but also automatically inserts the leading end of the carrier tape pulled out from the tape cassette into the tape inlet of the tape feeder. , the transfer of the tape cassette and the insertion of the carrier tape into the component supply unit (tape feeder) must be performed.

Accordingly, the present invention provides a tape cassette supply device, a component mounting system, and a tape cassette supply that can automatically transfer a tape cassette to a component mounting device and insert a carrier tape pulled out of the tape cassette into a component supply unit. The purpose is to provide a method.

A tape cassette supply device according to the present invention is a tape cassette supply device for supplying a tape cassette containing a carrier tape to a component mounting device, comprising a cassette stock section for stocking the tape cassette, and a tape taken out from the cassette stock section. The tape cassette is moved along a path passing through a tape feed position where the leading end of the carrier tape pulled out from the tape cassette is opposed to the tape entrance of the component supply unit provided in the component mounting device. a cassette transfer section for transferring to a component mounting device; and after holding the leading portion of the carrier tape pulled out from the tape cassette when the tape cassette is positioned at the tape feed position by the cassette transfer section; a tape feeding section for feeding the leading portion of the carrier tape toward the tape inlet.

A component mounting system of the present invention includes a component mounting device, a tape cassette supply device for supplying a tape cassette containing a carrier tape to the component mounting device, and a cassette transfer section for transferring the tape cassette. In the component mounting system, the tape cassette supply device includes a cassette stock section for stocking tape cassettes, and a tape cassette taken out from the cassette stock section and a leading portion of the carrier tape pulled out from the tape cassette. a cassette transfer section for transferring a tape cassette to the component mounting device by moving the tape cassette along a path passing through a tape feeding position facing a tape inlet of a component supply unit provided in the component mounting device; a tape feeding unit for holding the leading portion of the carrier tape pulled out from the tape cassette when the tape cassette is positioned at the tape feeding position by a portion, and then feeding the leading portion of the carrier tape toward the tape entrance; , have

A tape cassette supplying method according to the present invention is a tape cassette supplying method using the component mounting system according to the present invention, wherein the tape cassette is taken out from the cassette stock section, and the leading end of the carrier tape pulled out from the taken out tape cassette. a transfer step of moving a tape cassette along a path passing through a tape feed position facing a tape inlet of a component supply unit provided in the component mounting device and transferring the tape cassette to the component mounting device; After holding the leading portion of the carrier tape pulled out from the tape cassette when positioned at the tape feeding position, the leading portion of the carrier tape is moved to the tape inlet during or after the transferring step. and a tape feeding step for feeding to.

According to the present invention, it is possible to automatically transfer the tape cassette and insert the carrier tape pulled out from the tape cassette into the component supply unit.

1 is a side view of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of a component mounting device included in a component mounting system according to an embodiment of the present invention; FIG. 1 is a side view of a component supply section of a component mounting apparatus according to an embodiment of the present invention; FIG. 1 is a perspective view showing a tape cassette provided in a component mounting apparatus according to an embodiment of the present invention together with a roll of carrier tape stored therein; FIG. FIG. 2 is an enlarged perspective view of a portion of the carrier tape pulled out from the roll body used in the component mounting apparatus according to one embodiment of the present invention; FIG. 2 is a side view showing constituent elements of a component supply unit of a component mounting apparatus according to one embodiment of the present invention; 1 is a perspective view of a tape cassette according to one embodiment of the present invention; FIG. 1 is a side view of a tape cassette according to one embodiment of the present invention; FIG. 1 is a front view of a tape cassette according to one embodiment of the present invention; FIG. 1 is an exploded perspective view of a tape cassette according to one embodiment of the present invention; FIG. FIG. 2 is a side view of a frame included in a tape cassette according to one embodiment of the present invention; 1 is a side cross-sectional view of a part of a component mounting apparatus according to one embodiment of the present invention; 1 is a side cross-sectional view of a part of a component mounting apparatus according to one embodiment of the present invention; 1 is a sectional side view of a tape cassette according to one embodiment of the present invention; FIG. 1 is a sectional side view of a tape cassette according to one embodiment of the present invention; FIG. FIG. 2 is a side view of a shutter included in a tape cassette according to one embodiment of the present invention; (a) to (g) Cross-sectional views of a tape cassette according to one embodiment of the present invention (a), (b), and (c) are side views of a tape cassette showing how a roll of carrier tape is put into and taken out of the storage cassette according to one embodiment of the present invention. (a), (b), and (c) are front views of a plurality of types of tape cassettes with different width dimensions in one embodiment of the present invention. 1 is a perspective view of an example of a tape cassette having the largest width dimension in one embodiment of the present invention; FIG. FIG. 1 is a side view of a tape cassette supply device provided in a component mounting system according to one embodiment of the present invention; FIG. 1 is a plan view of a tape cassette supply device provided in a component mounting system according to one embodiment of the present invention; FIG. 1 is a front view of a tape cassette supply device included in a component mounting system according to one embodiment of the present invention; 1 is a see-through side view of a tape cassette supply device provided in a component mounting system according to an embodiment of the present invention; FIG. (a) and (b) are side views showing a floating mechanism included in the tape cassette supply device of the component mounting system according to the embodiment of the present invention. 1 is a side view of a component mounting system according to one embodiment of the present invention; FIG. 1 is a plan view of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of a component mounting system according to one embodiment of the present invention; FIG. (a), (b), and (c) are side views showing how the tape cassette supply device provided in the component mounting system according to the embodiment of the present invention is connected to the component mounting device. 1 is a side view of a component mounting system according to one embodiment of the present invention; FIG. 1 is a plan view of a component mounting system according to one embodiment of the present invention; FIG. 1 is a bottom perspective view of a chuck device included in a component mounting system according to one embodiment of the present invention; FIG. (a) and (b) are plan views showing gripping pins of a chuck device provided in a component mounting system according to an embodiment of the present invention. FIG. 2 is a cross-sectional plan view showing a gripping pin of a chuck device provided in a component mounting system according to one embodiment of the present invention; (a) and (b) are perspective views showing a block to be gripped and a gripping pin for gripping the block provided in the tape cassette handled by the component mounting apparatus component mounting system according to one embodiment of the present invention. (a), (b), (c), and (d) are perspective views of a portion of the tape cassette handled by the component mounting system according to one embodiment of the present invention. (a) and (b) are plan views of a portion of the tape cassette handled by the component mounting system according to the embodiment of the present invention. (a) and (b) are plan views of a portion of the tape cassette handled by the component mounting system according to the embodiment of the present invention. (a) and (b) are plan views of a portion of the tape cassette handled by the component mounting system according to the embodiment of the present invention. (a) and (b) are plan views of a portion of the tape cassette handled by the component mounting system according to the embodiment of the present invention. (a) and (b) are plan views of a portion of the tape cassette handled by the component mounting system according to the embodiment of the present invention. FIG. 2 is a perspective view of a tape feeding section included in a tape cassette supply device of a component mounting system according to one embodiment of the present invention; (a) and (b) are front views of a tape feeding section provided in a tape cassette supply device of a component mounting system according to an embodiment of the present invention. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. (a), (b), (c), and (d) are perspective views showing a procedure for supporting the leading portion of the carrier tape pulled out from the tape cassette by the tape feeding section provided in the component mounting system according to the embodiment of the present invention. (a) (b) Partial side view of the component mounting system according to one embodiment of the present invention 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. (a) (b) Partial side view of the component mounting system according to one embodiment of the present invention 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. (a) (b) Partial side view of the component mounting system according to one embodiment of the present invention (a) (b) Partial side view of the component mounting system according to one embodiment of the present invention 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. (a) (b) Partial side view of the component mounting system according to one embodiment of the present invention 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. 1 is a side view of part of a component mounting system according to one embodiment of the present invention; FIG. (a) (b) Partial side view of the component mounting system according to one embodiment of the present invention

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a component mounting system 1 according to one embodiment of the present invention. The component mounting system 1 repeatedly executes a series of component mounting operations in which a component BH is mounted on a board KB carried in from another apparatus in an upstream process and carried out to another apparatus in a downstream process. and a tape cassette feeding device 1H.

In FIG. 2, the component mounting device 1T comprises a mounting device main unit 1A and a component supply unit 1B. The mounting device main unit 1A includes a base 11, a substrate transfer unit 12, a mounting head 13, and a head moving mechanism . The substrate transfer unit 12 is composed of a conveyor mechanism, and horizontally transfers the substrate KB received from the apparatus of the upstream process and positions it at a predetermined working position. In this embodiment, the direction in which the board KB is conveyed in the component mounting apparatus 1T is defined as the X direction (horizontal direction), the vertical direction is defined as the Z direction, and the direction orthogonal to both the X direction and the Z direction is defined as the Y direction (forward and backward direction). direction).

In FIG. 2, the mounting head 13 has a plurality of downwardly extending nozzles 13N, and a vacuum suction force for sucking the component BH can be generated at the lower end of each nozzle 13N. The head moving mechanism 14 is composed of, for example, an XY table, and moves the mounting head 13 within the XY plane.

2 and 3, the component supply section 1B includes a carriage 21, a tape cassette 22 and a tape feeder 23. As shown in FIG. The tape cassette 22 can store a roll body RT (hereinafter simply referred to as a roll body RT) of the carrier tape CT wound in a disk shape without a core (see also FIG. 4). . That is, the tape cassette 22 handles the roll body RT which is not wound on the reel.

The carrier tape CT includes a base tape BT and a top tape TT, as shown in FIG. 5 (FIG. 5 is an enlarged view of the area AR in FIG. 4). A large number of upwardly opening pockets PK are provided in the base tape BT in a row and at equal intervals in the longitudinal direction of the base tape BT, and each pocket PK stores a component BH. The top tape TT is attached to the upper surface of the base tape BT and encloses the component BH in the pocket PK. A plurality of feed holes SH are arranged in a row at regular intervals at positions parallel to the row of pockets PK of the base tape BT.

2 and 3, the base 11 has a pair of carriage guide portions 11G extending rearward and facing in the X direction, and a pair of carriages extending rearward and facing in the X direction. A holding portion 11H is provided. A pair of carriage guide portions 11G are members that guide both left and right sides of the lower portion of the carriage 21 when holding the carriage 21, and a pair of carriage holding portions 11H are guided by the carriage guide portions 11G and approach the base 11. It is a member that lifts and holds the left and right side portions of the carriage 21 that has been lifted.

In FIG. 6, a feeder base 31 is provided on the top of the truck 21 . A feeder mounting slot 31S for mounting the tape feeder 23 is provided on the upper surface of the feeder base 31 so as to extend in the Y direction.

The tape feeder 23 functions as a component supply unit that supplies components BH to the mounting device main body 1A. The tape feeder 23 can be attached to the feeder base 31 by sliding a slide projection 23T (FIG. 6) provided on the bottom surface of the feeder base 31 into the feeder attachment slot 31S.

The feeder base 31 is provided with a plurality of feeder mounting slots 31S arranged side by side in the X direction. Therefore, a plurality of tape feeders 23 can be mounted on the feeder base 31 side by side in the X direction.

2, 3 and 6, the carriage 21 is provided with a cassette mounting portion 33 formed in a flat plate shape as a whole at the rear (left side in each of these figures) of a carriage base 32 which is movable on the floor FL. there is As shown in FIG. 6, a pair of lower brackets 34 projecting upward are provided on the carriage base 32 at an intermediate portion in the front-rear direction so as to face each other in the X direction. Both ends of a lower support bar 35 extending in the X direction are supported by the pair of lower brackets 34 .

In FIG. 6, below the feeder base 31, a pair of upper brackets 36 projecting downward are provided facing each other in the X direction. Both ends of an upper support bar 37 extending in the X direction are supported by the pair of upper brackets 36 . The upper support bar 37 extends parallel to the lower support bar 35 above the lower support bar 35 (FIG. 6).

4 and 7, the tape cassette 22 has a case-shaped storage portion 41 and a shutter 42 as a regulation portion provided in the storage portion 41. As shown in FIG. In the storage portion 41 of the tape cassette 22, the roll body RT is stored in a vertical posture. Here, the “vertical posture” means a posture in which the center axis CJ of the disc-shaped roll body RT is substantially horizontal.

The tape cassette 22 is used in two usage patterns in this embodiment. A first mode of use is used as a receiving portion for the roll body RT of the carrier tape CT (current tape) currently being conveyed by the tape feeder 23 , and the carriage base 32 and the cassette mounting portion 33 are straddled. be worn. The tape cassette 22 used as a receiver for such a roll RT of current tape is hereinafter referred to as a "receiving cassette 22A" (FIGS. 3 and 6).

A second mode of use of the tape cassette 22 is that it is used as a storage device for storing a roll body RT of carrier tape CT (supplementary tape) for replenishment when the current tape runs out of parts. It is attached to the carriage base 32 . The tape cassette 22 used as a storage device for such a roll body RT of replenishment tape is hereinafter referred to as a "storage cassette 22B" (FIGS. 3 and 6). Thus, the receiving cassette 22A and the storage cassette 22B are tape cassettes 22 having the same structure.

The tape feeder 23 draws out the carrier tape CT from the roll body RT of the receiving cassette 22A and supplies the component BH to the mounting head 13 . In addition, following the carrier tape CT, the carrier tape CT is pulled out from the roll body RT of the storage cassette 22B, and the component BH is supplied to the mounting head 13. FIG.

In the present embodiment, the tape feeder 23 is a so-called autoload feeder, which detects when the leading portion of the carrier tape CT is inserted from the tape entrance 23G (FIG. 3) provided at the rear end portion and feeds the carrier tape. The CT is conveyed forward, and the component BH is supplied to the predetermined component supply port 23K. At this time, the tape feeder 23 feeds the carrier tape CT while pulling it out as a current tape from the roll body RT in the receiving cassette 22A.

The leading end of the carrier tape CT (supplementary tape) pulled out from the roll body RT in the storage cassette 22B can be inserted into the tape inlet 23G of the tape feeder 23 before the current tape runs out. . When the tape feeder 23 detects that the trailing portion of the current tape has passed a predetermined position within the tape feeder 23, the tape feeder 23 starts feeding the supplementary tape. As a result, a plurality of carrier tapes CT are continuously conveyed without a break, and the components BH are supplied to the component mounting apparatus 1T without running out of components.

When the component mounting apparatus 1T performs the component mounting work, first, the board transfer section 12 operates to bring in the board KB from the outside and position it at a predetermined work position. When the substrate KB is positioned at the work position by the substrate transport section 12, the mounting turn is performed by interlocking the operation of the tape feeder 23 to supply the component BH to the component supply port 23K and the operation of the head moving mechanism 14 to move the mounting head 13. repeatedly.

In one mounting turn, the mounting head 13 moves to a position above the tape feeder 23 and sucks (picks up) the component BH with the nozzle 13N, and then moves to a position above the board KB to mount the component BH on the board KB. Perform a series of actions. When all the components BH to be mounted on the board KB are mounted by repeating the mounting turns, the board transfer section 12 is operated to unload the board KB to the equipment in the downstream process. This completes the component mounting work for each board KB.

Next, the configuration of the tape cassette 22 used as the receiving cassette 22A or the storage cassette 22B for the roll body RT of the carrier tape CT and the mounting procedure on the carriage 21 will be described.

7, 8 and 9, the tape cassette 22 has a storage portion 41 and a shutter 42 as a regulation portion provided in the storage portion 41. As shown in FIG. The storage portion 41 includes a U-shaped frame 43 and a pair of plate members (side plates 44) mounted on both sides of the frame 43 in the width direction. A space surrounded by the U-shaped frame 43 and the pair of side plates 44 is a storage space 41S for storing the roll body RT. The opening of the U-shaped frame 43 faces forward, so that a front opening 41K is formed in front of the storage section 41 as an opening.

As described above, in the present embodiment, the storage unit 41 includes a U-shaped frame 43 surrounding the storage space 41S and a pair of side plates 44 (plate members) fixed to the frame 43 covering the sides of the storage space 41S. , and the storage portion 41 has a front opening 41K at the front facing the outer peripheral surface of the roll body RT.

7, 9 and 10, the frame 43 is composed of two frame members 43Z arranged in the width direction. As shown in FIGS. 10 and 11, the upper side of the frame 43 with the opening facing in the horizontal direction is a frame upper portion 43a, and the lower side is a frame lower portion 43b. An arc-shaped guide portion 43c is provided between the frame upper portion 43a and the frame lower portion 43b.

7, 9 and 11, when the frame 43 is sandwiched between the pair of side plates 44, the frame upper portion 43a of the frame 43 is positioned facing the upper edge of the side plate 44, and the frame lower portion 43b of the frame 43 is located on the side plate 44. It is positioned facing the lower edge of the As shown in FIG. 11, a shutter guide portion 43g that protrudes toward the center of the arc of the frame 43 is formed on the inner peripheral surface of the guide portion 43c. A guide surface 43F is provided on the lower surface of the front end portion of the frame upper portion 43a and is inclined upward toward the front.

7 and 11, the frame upper portion 43a is provided with an engagement groove 43M, a gripped block 45 as a gripped portion, and a lower support bar engagement portion 43P in this order from the front end side. The engaging groove 43M is provided facing the upper surface of the frame upper portion 43a and opens forward. The gripped block 45 is made of a block-shaped member, and is provided extending in the Y direction (the direction orthogonal to the width direction of the tape cassette 22 and the in-plane direction of the roll body RT accommodated in the tape cassette 22). .

7 and 11, the frame lower portion 43b is provided with three pin insertion portions 43S arranged side by side in the Y direction. An upper support bar engaging portion 43Q is provided in a region between two front pin insertion portions 43S and one rear pin insertion portion 43S among the three pin insertion portions 43S.

In FIG. 6, on the upper surface of the cassette mounting portion 33, three storage cassette holding pins 33P are arranged in a row in the Y direction. These three storage cassette holding pins 33P constitute one cassette holding pin row 33L.

In FIG. 6, one receiving cassette holding pin 33Q is provided in front of each cassette holding pin row 33L coaxially with the cassette holding pin row 33L. That is, on the upper surface of the cassette mounting portion 33, a plurality of pin rows in which three storage cassette holding pins 33P (cassette holding pin row 33L) and one receiving cassette holding pin 33Q are arranged in a row are provided in the X direction. .

As shown in FIGS. 3 and 12, the receiving cassette 22A is mounted on the carriage 21 with the storage cassette 22B turned upside down, that is, upside down. When the receiving cassette 22A is mounted on the carriage 21, as shown in FIG. 12, the lower support bar engaging portion 43P is engaged with the lower support bar 35, and the upper support bar engaging portion 43Q is supported on the upper side. It is engaged with the bar 37 and the engagement groove 43M is engaged with the receiving cassette holding pin 33Q. Thus, in the present embodiment, one receiving cassette holding pin 33Q, lower support bar 35, and upper support bar 37 form a receiving cassette mounting portion 38 (receiving portion mounting portion) to which the receiving cassette 22A is mounted. there is

11 and 12, the tape cassette 22 has a sub-mounting portion 43R composed of upper support bar engaging portions 43Q of an upper frame portion 43a and a lower frame portion 43b. , the tape cassette 22 is mounted in the component mounting apparatus 1T as a receiving cassette 22A. In this manner, the receiving cassette mounting portion 38 is mounted with the tape cassette 22 turned upside down.

As shown in FIG. 13, the storage cassette 22B is configured such that three storage cassette holding pins 33P constituting one cassette holding pin row 33L are inserted into three pin insertion portions 43S provided in the frame lower portion 43b. and mounted on the carriage 21 (the cassette mounting portion 33 of the component supply portion 1B). The storage cassette 22B attached to the carriage 21 is held in a vertical posture with the front opening 41K facing forward.

As described above, in the present embodiment, the storage portion 41 of the storage cassette 22B has pins that are engaged portions that can be engaged with the cassette holding pin rows 33L (three storage cassette holding pins 33P) provided in the component supply portion 1B. Equipped with an insertion portion 43S, the storage cassette 22B is positioned and held by a storage cassette mounting portion 39 consisting of a cassette holding pin row 33L (three storage cassette holding pins 33P). That is, in the present embodiment, the three storage cassette holding pins 33P (cassette holding pin row 33L) aligned in the Y direction form a storage cassette mounting portion 39 (storage device mounting portion) to which the storage cassette 22B is mounted. ing.

Further, in the present embodiment, the tape cassette 22 has a main attachment portion 43U (attachment portion) constituted by a frame lower portion 43b (FIGS. 11 and 13), and the main attachment portion 43U is attached to the storage cassette mounting portion 39. , the tape cassette 22 is installed in the component mounting apparatus 1T as a storage cassette 22B. As a result, the storage cassette 22B held in the storage cassette mounting portion 39 is sandwiched between the pair of side plates 44 of the receiving cassette 22A positioned in front thereof, thereby moving in the X direction (the sideward tilting direction). is suppressed.

12 and 13, the receiving cassette mounting section 38 mounts the receiving cassette 22A with the front opening 41K of the receiving cassette 22A facing the storage cassette mounting section 39. As shown in FIG. Further, the storage cassette mounting section 39 mounts the storage cassette 22B with the front opening 41K of the storage cassette 22B facing the receiving cassette 22A mounted on the receiving cassette mounting section 38 . In this manner, the receiving cassette 22A and the storage cassette 22B are mounted on the carriage 21 with the front opening 41K of the receiving cassette 22A and the front opening 41K of the storing cassette 22B facing each other. can be moved to the receiving cassette 22A.

Further, the receiving cassette mounting section 38 mounts the receiving cassette 22A at a position lower than the storage cassette 22B mounted on the storage cassette mounting section 39 . As a result, the roll body RT is smoothly moved from the storage cassette 22B to the receiving cassette 22A, and the roll body RT stored in the receiving cassette 22A is prevented from moving to the storage cassette 22B.

Further, the receiving cassette mounting portion 38 mounts the receiving cassette 22A in an inclined posture that becomes lower as the distance from the storage cassette mounting portion 39 increases. As a result, the roll body RT is smoothly moved from the storage cassette 22B to the receiving cassette 22A, and the roll body RT stored in the receiving cassette 22A is prevented from moving to the storage cassette 22B.

7, 14 and 15, the shutter 42 is provided within the storage space 41S of the storage section 41. As shown in FIG. As shown in FIG. 16, the shutter 42 has a J-shape as a whole, and includes an arcuate slider portion 51 and a shutter tip portion 52 linearly extending from one end of the slider portion 51 . . The slider portion 51 is connected to an operating lever 53 that protrudes outward (away from the center) of the arcuate slider portion 51 and is positioned to protrude rearward of the storage portion 41 .

7, 8 and 9, a tape holding portion 54 is provided at the tip portion of the shutter 42 (the end portion of the shutter tip portion 52). The tape holding portion 54 is a plate-like portion extending in the direction in which the shutter tip portion 52 extends. These two tape locking projections 55 are arranged in parallel in a plane orthogonal to the width direction of the storage portion 41 .

The shutter 42 is guided by the arc-shaped shutter guide portion 43 g provided on the frame 43 at the outer peripheral surface of the arc-shaped slider portion 51 . When the operation lever 53 is operated, the shutter 42 is guided by the shutter guide portion 43g and slides in the inner region of the frame 43 in the rotational direction about the axis parallel to the X direction.

The shutter 42 has a closed position (first position) that closes the front opening 41K of the storage section 41 at a position where the tip portion 52 of the shutter extends in the vertical direction (Z direction) at the front portion of the storage space 41S. Take (Fig. 14). Further, at a position where the shutter tip portion 52 extends in the front-rear direction (Y direction) under the storage space 41S, the front opening 41K of the storage portion 41 is opened (second position) (Fig. 15). When the shutter 42 is at the closed position, the roll body RT in the storage space 41S cannot pass through the front opening 41K and move out of the storage section 41, but when the shutter 42 is at the open position , the roll body RT in the storage space 41S can pass through the front opening 41K and move to the outside of the storage section 41. As shown in FIG.

In FIGS. 11, 14 and 15, an opening-side stopper surface 43T is formed at the front end of the lower frame portion 43b, and a boundary portion between the slider portion 51 and the shutter tip portion 52 of the shutter 42 has a shutter tip portion. A contact surface 52T, which is an end surface of the portion 52, is formed (FIG. 14). When the operating lever 53 is moved from the lower position to the upper position, the shutter 42 rotates clockwise in FIG. 14 (FIGS. 14 to 15), and when the contact surface 52T contacts the open-side stopper surface 43T, the closed position is reached. (Fig. 15).

17(a) to 17(f) are cross sections (AA cross section, BB cross section, CC cross section, DD cross section) of the tape cassette 22 with the shutter 42 positioned at the closed position. , EE section and FF section). FIG. 17G is a partial cross section (GG cross section) of the tape cassette 22 when the shutter 42 is at the open position.

11 and 15, a closing side stopper surface 43K is formed at the upper end (rear end) of the frame lower portion 43b. When the operation lever 53 is moved from the upper position to the lower position, the shutter 42 rotates counterclockwise in FIG. 15 (FIGS. 15 to 14), and when the operation lever 53 contacts the closing side stopper surface 43K, the closing position is reached. (Fig. 14). As described above, in the present embodiment, the operating lever 53 is an operating portion that performs an operation to displace the shutter 42 between the closed position (first position) and the open position (second position).

When the roll body RT is to be stored in the tape cassette 22, the roll body RT is inserted through the front opening 41K of the storage section 41 with the shutter 42 positioned at the open position (see the arrow in FIG. 18A). M1), and moves the operating lever 53 downward (an arrow N1 shown in FIG. 18(b)). As a result, the shutter 42 moves from the open position to the closed position, the front opening 41K of the storage section 41 is closed by the shutter 42, and the roll body RT is stored in the tape cassette 22 (FIG. 18(b)). .

On the other hand, to take out the roll body RT stored in the tape cassette 22, the operation lever 53 is moved upward (an arrow N2 shown in FIG. 18(c)). As a result, the shutter 42 moves from the closed position to the open position, the front opening 41K of the storage section 41 is opened, and the roll body RT can be taken out from the storage section 41 (see the arrow in FIG. 18(c)). M2).

As described above, in the present embodiment, the tape cassette 22 as a storage device has a storage space 41S for storing the roll RT and a front opening 41K through which the roll RT can be taken in and out. A first position (closed position) for restricting movement of the roll body RT stored in the storage space 41S to the outside of the storage section 41 through the front opening 41K by blocking at least a portion of the opening 41K and storage. A shutter 42 is provided as a restricting portion that is displaced between a second position (open position) that allows the roll body RT stored in the space to pass through the front opening 41K and move to the outside of the storage portion 41. It has a configuration. When the shutter 42 is displaced to the closing position, the slider portion 51 is guided by a shutter tip portion 52 located at the front opening 41K and a shutter guide portion 43g provided on the frame 43 to slide. there is

By the way, a plurality of types of tape cassettes 22 having different widthwise dimensions are required in order to cope with the difference in the widthwise dimensions of the roll body RT. As mentioned above, the frame 43 is composed of two frame members 43Z (FIGS. 7 and 9). For this reason, one of the frame members 43Z has a thickness dimension corresponding to the widthwise dimension of the roll body RT, and the other is used in common regardless of the difference in the widthwise dimension of the roll body RT. It is possible to reduce the manufacturing cost of a plurality of types of tape cassettes 22 by sharing members. 19(a), (b), and (c) show examples of a plurality of types of tape cassettes 22 having different width dimensions.

FIG. 19(a) shows a configuration in which one frame member 43Z is removed and one frame member 43Z is used in common. Smaller than case can be accommodated. In FIG. 19B, by increasing the width dimension of one of the two frame members 43Z, it is possible to cope with the case where the width dimension of the roll body RT is larger than in the case described above.

FIG. 19(c) shows two frame members 43Z connected by a rod-like spacer SP, which is adapted to a roll body RT having a width dimension larger than that of FIG. 19(b). (see also FIG. 20). The two frame members 43Z connected by the spacer SP are used in common. 19(b) and 19(c), the gripped blocks 45 are provided on each of the two frame members 43Z.

When the tape cassette 22 is lifted by gripping the block 45 to be gripped, if the block 45 to be gripped is provided only on one of the two frame members 43Z, the position of the center of gravity of the entire tape cassette 22 is determined. This is because it will be tilted from the vertical position due to the relationship, and it will be difficult to perform the mounting work on the carriage 21 . Also, if one gripped block 45 is gripped to force the tape cassette 22 into the vertical position, an excessive bending moment acts on the gripped block 45 and may damage the gripped block 45 . be.

As described above, the tape cassette 22 in the present embodiment supplies the roll body RT of the carrier tape CT containing the components BH to the component mounting apparatus 1T, and includes the storage section 41 and the shutter 42. It's becoming The storage unit 41 includes a storage space 41S for storing the roll RT and a front opening 41K through which the roll RT can be taken in and out. A closed position (first position) for restricting movement of the roll RT to the outside of the storage section 41 through the front opening 41K, and a closed position (first position) for restricting movement of the roll body RT to the outside of the storage section 41 through the front opening 41K. It is displaceable between the permissible open position (second position). The storage unit 41 is mounted with the front opening 41K facing the component mounting apparatus 1T, and the roll body RT is supplied to the component mounting apparatus 1T with the shutter 42 positioned at the open position.

Next, a procedure for attaching the tape cassette 22 to the component supply section 1B provided in the component mounting apparatus 1T will be described. In attaching the tape cassette 22 to the component supply unit 1B, first, the receiving cassette 22A is attached to the receiving cassette mounting portion 38 of the carriage 21, which is the receiving portion mounting portion.

When the receiving cassette 22A is mounted in the receiving cassette mounting portion 38, first, the operation lever 53 is used to position the shutter 42 at the open position (second position), and then the tape cassette 22 is turned upside down. Then, the lower support bar engaging portion 43P provided on the frame upper portion 43a is engaged with the lower support bar 35, and the upper support bar engaging portion 43Q provided on the frame lower portion 43b is engaged with the upper support bar 37. 12 to 13).

When the receiving cassette 22A is mounted on the carriage 21, the tape cassette 22 is tilted forward and slightly downward, and the guide surface 43F provided on the frame upper portion 43a is substantially horizontal (see FIG. 13). ). Further, the shutter 42 of the receiving cassette 22A mounted on the carriage 21 is positioned at the open position (second position).

After the receiving cassette 22A is mounted on the receiving cassette mounting portion 38 of the carriage 21 as described above, the storage cassette 22B in which the roll body RT is stored is mounted on the storage cassette mounting portion 39 of the carriage 21 . The shutter 42 of the storage cassette 22B is positioned at the closed position until immediately before the storage cassette 22B is attached to the storage cassette attachment portion 39, and the roll body is held by the tape holding portion 54 of the shutter 42 positioned at the closed position. The leading portion of the carrier tape CT pulled out from the RT is held (FIG. 13).

Here, the holding of the leading portion of the carrier tape CT by the tape holding portion 54 is achieved by the two tape locking protrusions 55 provided on the tape holding portion 54 being provided at the leading portion of the carrier tape CT pulled out from the roll body RT. 7 and 13). In this state, the leading portion of the carrier tape CT is substantially horizontal.

As described above, in the present embodiment, the tape holding portion 54 provided at the tip portion of the shutter 42 (shutter tip portion 52) has two feeding hole engaging portions capable of engaging with the feeding holes SH of the carrier tape CT. These tape engaging projections 55 hold the carrier tape CT pulled out from the roll body RT. At this time, the leading portion of the carrier tape CT is in a horizontal posture. That is, when the shutter 42 is positioned (displaced) at the closed position (first position), the tape holding section 54 horizontally holds the carrier tape CT.

The operation of mounting the storage cassette 22B to the cassette mounting portion 33 is automatically performed by the tape cassette supply device 1H. Here, the tape cassette supply device 1H will be described.

21, 22 and 23 show the tape cassette feeder 1H. The tape cassette supply device 1H is a device that supplies the tape cassette 22 (storage cassette 22B) containing the roll body RT of the carrier tape CT to the component supply section 1B of the component mounting device 1T. 62 , a cassette transfer section 63 and a tape feeding section 64 .

First, the cassette supply section 61 will be described. 21, 23 and 24, the cassette supply section 61 includes a reference base 71, a supply device body section 72, a floating mechanism 73, a cassette stock section 74, a shutter operation section 75 and a control section . The reference base 71 has a plurality of wheels 71S on its lower surface and can run on the floor FL. The supply device main body 72 is arranged above the reference base 71 . The supply device main body 72 includes an elevating base 72a (bottom plate) and a top plate 72b, and has a housing shape that opens forward.

In FIGS. 21, 23 and 24, the floating mechanism 73 is provided between the reference base 71 and the feeder main body 72 (specifically, the elevating base 72a). The floating mechanism 73 is a mechanism that holds the supply device body 72 vertically movably with respect to the reference base 71 .

25(a) and 25(b), the floating mechanism 73 includes four lifting guides 81 and spring members 82, and a plurality of link mechanisms 83. In FIG. The four elevation guides 81 are arranged on the front, back, left and right between the reference base 71 and the elevation base 72a, and the four spring members 82 correspond to the four elevation guides 81 (through the elevation guides 81). are placed.

As described above, in the present embodiment, the supply device main body 72 is vertically movable with respect to the reference base 71 and is elastically supported by the spring member 82 of the floating mechanism 73 . Note that FIG. 25(b) shows a case where the height HT of the lift base 72a with respect to the reference base 71 is higher than the case of FIG. 25(a) (height HT in FIG. 25(a)=H1 , H1<H2 at height HT=H2 in FIG. 25(b).

The link mechanism 83 included in the floating mechanism 73 includes a pair of link portions 101 spaced apart in the Y direction (the traveling direction of the supply device main body portion 72 with respect to the component mounting device 1T, as will be described later), and a pair of link portions 101. A connecting portion 102 connecting the link portions 101 is provided to constitute a parallel link. In this embodiment, as shown in FIG. 23, two link mechanisms 83 are provided side by side in the X direction.

25(a) and 25(b), the link portion 101 connects the reference base 71 and the feeder main body portion 72 (lower surface of the elevating base 72a). It consists of two linking elements 101E of the same length that are connected to each other. The lower link element 101E has its lower end pin-connected to the upper surface of the reference base 71, and the upper link element 101E has its upper end pin-connected to the lower surface of the elevation base 72a. The upper end of the lower link element 101E and the lower end of the upper link element 101E are pin-connected. The connecting portion 102 is formed of a rod-shaped member extending in the Y direction, and both front and rear end portions thereof are pivotally connected to intermediate portions (pin-connected portions) of the two link portions 101 .

Each of the two link portions 101 operates according to a change in the distance between the reference base 71 and the feeder main body portion 72 (elevating base 72a). link the actions of Since the link mechanism 83 is a parallel link, as long as the reference base 71 is in a horizontal posture, even if an upward or downward force acts on a part of the lifting base 72a, the lifting base 72a also maintains its horizontal posture.

21, 23 and 24, the cassette stock section 74 is made up of a member having a horizontal upper surface and is provided inside the supply device main body section 72. As shown in FIG. A plurality of storage cassettes 22B are placed and stocked on the upper surface of the cassette stock section 74 in a vertical posture with the front opening 41K facing forward. A plurality of storage cassettes 22B can be placed on the cassette stock portion 74 in a state of being arranged in the X direction (the width direction of the storage cassettes 22B).

In FIGS. 22, 23 and 24, the shutter operation section 75 is provided inside the main body section 72 of the supply device. The shutter operation section 75 includes a pair of left and right operation section bases 91 , an operation bar 92 and an operation bar driving section 93 .

The left and right operating portion bases 91 are provided in front regions of the cassette stock portion 74 in a state of being arranged outside the left and right ends of the cassette stock portion 74 . The left and right operation unit bases 91 are each formed of a plate-like member extending in the YZ plane, and the surfaces (inner surfaces) facing each other are provided with operation bar guides 91G extending in the Z direction. The left and right operation bar guides 91G are provided with bar holding portions 91B movable in the Z direction.

The operation bar 92 is made of a rod-shaped member extending in the X direction, and both ends thereof are held by left and right bar holding portions 91B. The operation bar driving portion 93 is composed of, for example, a rodless cylinder, and is attached to each of the left and right operation portion bases 91 . When the left and right operation bar drive units 93 synchronously raise and lower the respective bar holding units 91B, the operation bar 92 moves in the Z direction while maintaining its horizontal posture.

In FIGS. 21, 22, 23 and 24, the controller 76 is provided inside the main body 72 of the supply device. In addition to the operation bar drive unit 93, the control unit 76 controls the operation of other drive units (a chuck device moving mechanism 122, an opening/closing operation unit 131K, a sprocket drive motor 141, and an arm drive cylinder 143, which will be described later) provided in the tape cassette feeding device 1H. Control.

Next, the alignment section 62 will be described. 21, 22 and 24, the alignment section 62 includes left and right supply device side connection sections 111 . The left and right supply device side connection portions 111 are each composed of an alignment arm 112 , a horizontal alignment roller 113 and a height alignment roller 114 .

The alignment arm 112 is provided so as to extend forward from the supply device body portion 72 of the cassette supply portion 61 . Two horizontal alignment rollers 113 are provided in the front-rear direction at the front end of the alignment arm 112 . The horizontal alignment roller 113 is rotatable around an axis (Z axis) parallel to the Z direction.

One height alignment roller 114 is provided at the front end of the alignment arm 112 . A height alignment roller 114 is positioned above the two horizontal alignment rollers 113 (FIGS. 21 and 24) and is rotatable about an axis parallel to the X direction (X axis).

26 and 27, a pair of left and right alignment guides 11V extending rearward from the rear of the base 11 and a pair of guides 11V extending rearward from the rear of the base 11 are provided on the base 11 of the mounting device main body 1A. A pair of left and right horizontal alignment guides 11W are provided. The height alignment guide 11V is located above the horizontal alignment guide 11W.

In FIG. 26, the upper surface of the height direction alignment guide 11V is provided with a slope portion 11S having a shape that slopes upward from the rear to the front. A recessed portion 11K having a shape recessed downward is formed at the front end of the slope portion 11S.

The tape cassette supply device 1H is connected to the component mounting device 1T from behind the component mounting device 1T. When the tape cassette supply device 1H is connected to the component mounting device 1T, the tape cassette supply device 1H is caused to travel on the floor FL by the traveling robot RB as a moving body, and the mounting device main body section with the carriage 21 connected thereto. 1A (in the Y direction) is approached (FIG. 28). At this time, the Y-direction axis of the tape cassette feeder 1H is arranged to be parallel to the Y-direction axis of the base 11 . For this reason, the tape cassette supply device 1H approaches the mounting device main body 1A in a posture in which the carriage 21 connected to the base 11 is accommodated between the left and right alignment arms 112 .

Here, the traveling robot RB functions as a moving body that moves the tape cassette supply device 1H to the front of the component supply section 1B that requires supply of the carrier tape CT. For the traveling robot RB, for example, an automatic guided vehicle (AGV) that is self-propelled under wireless control is employed.

As the tape cassette feeding device 1H approaches the mounting device main body 1A, the left and right horizontal alignment rollers 113 of the tape cassette feeding device 1H come into contact with the inner surfaces of the left and right horizontal alignment guides 11W of the base 11 and roll. move. Therefore, the tape cassette feeding device 1H advances to the back side of the mounting device main body 1A while being positioned in the horizontal direction (X direction) with respect to the mounting device main body 1A.

Further, when the tape cassette supply device 1H is brought closer to the base 11 of the mounting device main body 1A, the left and right height alignment rollers 114 move over the upper surfaces (inclined portions) of the left and right height direction alignment guides 11V of the base 11. 11S) and rolls, and climbs the slope portion 11S (FIG. 29(a)→FIG. 29(b)). During this time, the supply device main body 72 is lifted with respect to the floor FL (that is, with respect to the reference base 71) (FIG. 29(b)).

The left and right height alignment rollers 114 climb the slopes 11S of the left and right height direction alignment guides 11V, and then fall into the left and right recesses 11K when they reach the front ends of the slopes 11S (FIG. 29(b) → FIG. 29(c)). As a result, the supply device main body 72 (elevating base 72a) of the tape cassette supply device 1H is positioned in the height direction with respect to the base 11 of the component mounting device 1T (FIGS. 30 and 31), and the traveling robot RB stops running.

As described above, in the present embodiment, the supply device side connection portion 111 provided in the tape cassette supply device 1H is connected to the height direction alignment guide 11V and the horizontal direction alignment guide 11W provided in the component mounting device 1T, and the connected state , the supply device main body 72 is positioned in the height direction. Therefore, the vertical and horizontal positions of the tape cassette feeding device 1H can be easily aligned with the component mounting device 1T, which is horizontally leveled and installed and whose height from the floor FL is not uniform. can.

Further, in positioning the supply device body 72 in the height direction, the left and right height alignment rollers 114 provided in the supply device side connection portion 111 are connected to the height direction alignment guide 11V while being connected to the height direction alignment guide 11V. (i.e., between the component mounting apparatus 1T) and receives an upward force from the height direction alignment guide 11V to adjust the height of the supply apparatus main body 72 with respect to the mounting apparatus main body 1A. Department. The height of the supply device main body 72 with respect to the component mounting device 1T can be changed by the outer diameter dimension of the left and right height alignment rollers 114 .

On the other hand, a height direction alignment guide 11V and a horizontal direction alignment guide 11W provided in the component mounting device 1T serve as mounting device side connection portions to which the tape cassette supply device 1H is connected. The height direction alignment guide 11V serves as a mounting device side height direction connecting portion to which the tape cassette feeding device 1H is connected so as to be positioned in the height direction with respect to the mounting device main body portion 1A. Further, the horizontal alignment guide 11W serves as a mounting device side horizontal connecting portion to which the tape cassette feeding device 1H is connected so as to be horizontally positioned with respect to the mounting device main body 1A.

Here, a pair of height direction alignment guides 11V are arranged in the width direction (X direction) of the mounting device main body 1A, and the height alignment rollers 114 correspond to the pair of height direction alignment guides 11V and tape cassettes. A pair is arranged in the width direction (X direction) of the supply device 1H. The pair of height direction alignment guides 11V are provided at positions sandwiching the component supply section 1B held by the carriage holding section 11H from its width direction (X direction). Therefore, when the tape cassette supply device 1H is connected to the mounting device main body 1A, the carriage 21 connected to the mounting device main body 1A is held from the sides by the pair of feeding device side connection portions 111. (Fig. 31).

When the tape cassette supply device 1H is connected to the mounting device main body 1A as described above, while the height alignment roller 114 is climbing the slope portion 11S of the height direction alignment guide 11V, the height alignment roller 114 is inserted into the concave portion 11K, the supply device side connection portion 111 receives an upward force from the height direction alignment guide 11V. As a result, the front portion of the supply device main body 72 is pushed up with respect to the rear portion. As described above, the elevating base 72a, which is the bottom plate of the feeder body 72, maintains a horizontal posture, thereby preventing the entire tape cassette feeder from tilting and becoming unstable.

In the present embodiment, as described above, the tape cassette supply device 1H is connected not to the carriage 21 but to the base 11 of the mounting device main body 1A. If the tape cassette supply device 1H were to be supported by the carriage 21, a heavy object would be placed on the carriage 21, and the front side (operator side) of the carriage 21 would be lowered. As a result, the position of the tape feeder 23 changes due to the change in the attitude of the carriage 21, and there is a risk that the mounting head 13 will pick up the component BH from the tape feeder 23, causing a pick-up error. However, in this embodiment, since the tape cassette supply device 1H is not connected to the carriage 21, there is no such fear, and the pickup accuracy of the component BH by the mounting head 13 does not deteriorate.

Also, the design of the carriage 21 is changed so as to support the tape cassette feeding device 1H (more specifically, the height direction alignment guide 11V for supporting the horizontal alignment roller 113 and the height alignment roller 114 on the side of the tape cassette feeding device 1H is changed. and a design change to provide a horizontal alignment guide 11W), the weight of the carriage 21 increases and handling becomes difficult.

Next, the cassette transfer section 63 will be described. 21, 22, 23 and 24, the cassette transfer section 63 is a mechanism section that takes out the tape cassette 22 (storage cassette 22B) from the cassette stock section 74 and transfers it to the component supply section 1B.

The cassette transfer section 63 includes a chuck device 121 as a gripping portion and a chuck device moving mechanism 122 as gripping portion moving means for moving the chuck device 121 . The chuck device moving mechanism 122 is composed of an X-axis table 123, two X guides 124, a Y-axis table 125, and a chuck lifting cylinder 126 as chuck lifting means.

The X-axis table 123 is provided so as to extend in the X direction on the rear portion of the upper surface of the top plate 72b of the supply device body portion 72. As shown in FIG. The two X guides 124 are provided extending in the X direction on the front and rear sides of the upper surface of the top plate 72b. The Y-axis table 125 is provided extending in the Y direction on the upper surface of the top plate 72b. A Y-axis table 125 is driven by an X-axis table 123 and guided by two X guides 124 to move in the X direction.

The chuck elevating cylinder 126 directs the lower end of the elevating rod 126R, which is a piston rod, downward. The chuck elevating cylinder 126 is driven by the Y-axis table 125 to move in the Y direction, and the X-axis table 123 drives the Y-axis table 125 in the Y direction to move in the Y direction.

21, 22, 23 and 24, the chuck device 121 is provided at the lower end of the lifting rod 126R. Therefore, the chuck device 121 moves in the X direction and the Y direction integrally with the chuck lifting cylinder 126, and moves up and down with respect to the supply device main body 72 when the chuck lifting cylinder 126 advances and retreats the lifting rod 126R. The operations of the X-axis table 123, the Y-axis table 125, and the chuck lifting cylinder 126 are controlled by the control unit 76 described above.

32, the chuck device 121 includes a chuck base 131, two front and rear block support shafts 132J arranged in the Y direction, and two front and rear opening/closing blocks 132 arranged in the Y direction attached to each block support shaft 132J. and a plurality of gripping pins 133 (pin members) attached to each opening/closing block 132 .

In FIG. 32, the chuck base 131 is attached to the lower end of the lifting rod 126R. The two block support shafts 132J each extend downward from the chuck base 131, and the two opening/closing blocks 132 are attached to the lower ends of the two block support shafts 132J.

In FIG. 32, an opening/closing portion 131K is provided in the chuck base 131. As shown in FIG. The opening/closing operation unit 131K is operated under the control of the control unit 76, and moves the two block support shafts 132J in the separating direction in the Y direction and in the approaching direction in which they approach each other in the Y direction. By moving the two block support shafts 132J by the opening/closing operation part 131K, the two opening/closing blocks 132 are moved to the open position (FIG. 33(a)) where the distance between them is the largest and the position where the distance between them is the smallest. 33(b)).

A gripping pin 133 extends downward from each of the two opening/closing blocks 132 . A collar portion 133D having an outer diameter larger than that of the gripping pin 133 is formed at the lower end of each gripping pin 133 (FIGS. 32 and 33(a), (b)).

In this embodiment, two opening/closing blocks 132 are provided with a plurality of pairs (four pairs) of gripping pins 133 . Two gripping pins 133 of each pair are arranged facing each other in the Y direction, and four sets of gripping pins 133 are provided side by side in the X direction.

When the two opening/closing blocks 132 are opened/closed by the opening/closing operation part 131K, the two gripping pins 133 of each of the four sets are separated from each other (FIG. 33(b)→FIG. 33(a)) or come close to each other. (FIG. 33(a)→FIG. 33(b)). As will be described later, the chuck device 121 grips the gripped block 45 attached to the tape cassette 22 (storage cassette 22B) by bringing the two gripping pins 133 close to each other by closing the two opening/closing blocks 132 .

As described above, in the present embodiment, the chuck device 121, which is a gripping portion, includes a pair of (two) opening/closing blocks 132 as opening/closing members that are moved in the direction of separating from each other and in the direction of approaching to approach each other, and the pair of opening/closing blocks 132 as opening/closing members. It is configured with a gripping pin 133 extending from each of the blocks 132 . By moving the pair of opening/closing blocks 132 in the approaching direction to reduce the distance between the pair of gripping pins 133, the gripped block 45 provided on the tape cassette 22 is gripped.

As shown in FIG. 34, the four pairs of gripping pins 133 are two gripping pins (first gripping pins 133a) whose spacing is L1 when the opening/closing block 132 is in the closed position, and the spacing is greater than L1. two gripping pins 133 (second gripping pins 133b) with a larger L2 (>L1) and two gripping pins 133 (third gripping pins 133c) with an interval L3 (>L2) larger than L2. , two gripping pins 133 (fourth gripping pin 133d) with an interval L4 (>L3) larger than L3. As described above, in this embodiment, a pair of opening/closing blocks 132 includes a plurality of pairs of gripping pins 133, and the distances between each pair of gripping pins 133 are different from each other.

As shown in FIGS. 35(a) and 35(b), the gripped block 45 provided on each tape cassette 22 has two portions, a block base portion 45K and a block body portion 45H. The block base portion 45K is a portion that is directly attached to the frame upper portion 43a, and the block body portion 45H is a portion that is connected to the upper portion of the block base portion 45K and has a shape that protrudes outward from both ends of the block base portion 45K in the Y direction. .

A pair of recessed portions 45M (front and rear recessed portions 45M) are provided at both end portions of the block body portion 45H in the front-rear direction. These front and rear recessed portions 45M have shapes that are recessed in the mutually facing direction (Y direction). The inner diameter of each of the two recesses 45M is slightly larger than the outer diameter of the gripping pin 133 of the chuck device 121. As shown in FIG.

In this embodiment, as shown in FIGS. 36(a), (b), (c), and (d), there are four types of gripped blocks 45 (first gripped block 45a, second gripped block 45a, 45b, a third gripped block 45c and a fourth gripped block 45d) are used. These four types of gripped blocks 45 have different lengths in the Y direction of the block body 45H (that is, the distance between the two recessed portions 45M) so that they can be used according to the width of the tape cassette 22. It's becoming

The four types of gripped blocks 45 included in the two opening/closing blocks 132 are the four sets of two gripping pins 133 (the first gripping pin 133a, the second gripping pin 133b, the third gripping pin 133c and the fourth gripping pin 133c). 133d). Specifically, the distance between the two depressions 45M of the first gripped block 45a is L1 (FIG. 36(a)), and the distance between the two depressions 45M of the second gripped block 45b is L1. L2 (FIG. 36(b)). The distance between the two depressions 45M of the third gripped block 45c is L3 (FIG. 36(c)), and the distance between the two depressions 45M of the fourth gripped block 45d is L4 (FIG. 36(c)). 36(d)).

When the gripped block 45 of the tape cassette 22 (storage cassette 22B) is gripped by the chuck device 121, the tape cassette supply device 1H first operates the opening/closing operation section 131K to position the opening/closing block 132 at the open position. . Then, the two gripping pins 133 corresponding to the gripped block 45 to be gripped are positioned outside the gripped block 45 to be gripped in the Y direction (FIG. 35(a)). At this time, the opening/closing block 132 is positioned at a height such that the flange portions 133D of the two gripping pins 133 are positioned below the lower surface of the block body portion 45H.

When the two gripping pins 133 are positioned outside the gripped block 45 in the Y direction, the tape cassette feeding device 1H operates the opening/closing operation part 131K to position the opening/closing block 132 at the closed position (see FIG. 35 ( a)→FIG. 35(b)). As a result, the two gripping pins 133 are fitted into the two recesses 45M of the gripped block 45, respectively, and the chuck device 121 grips the gripped block 45 (FIG. 35(b)). When the chuck device 121 grips the gripped block 45, the flanges 133D of the two gripping pins 133 are positioned below the block main body 45H.

In this manner, the chuck device 121 moves the two gripping pins 133 in the Y direction (the in-plane direction of the roll body RT accommodated in the tape cassette 22) to grip the gripped block 45. The gripped block 45 of the target tape cassette 22 can be gripped without interfering with the tape cassette 22 .

As described above, the distance between the two gripping pins 133 of each set (the distance when the two open/close blocks 132 are positioned at the closed position) is the distance between the two depressions 45M provided in the corresponding gripped block 45. matches Therefore, the first gripped block 45a can be gripped only by the first gripping pin 133a (FIG. 37(a)→FIG. 37(b)), and the second gripped block 45b (FIG. 36(b)) can be gripped only by the first gripping pin 133a. It can be gripped only by the two gripping pins 133b (FIG. 38(a)→FIG. 38(b)). Further, the third gripped block 45c (FIG. 36(c)) can be gripped only by the third gripping pin 133c (FIG. 39(a)→FIG. 39(b)), and the fourth gripped block 45d (FIG. 39(c)) 36(d)) can be gripped only by the fourth gripping pin 133d (FIG. 40(a)→FIG. 40(b)).

As described above, the tape cassette 22 has one or two gripped blocks 45, one of which is always the first gripped block 45a. Therefore, when the width dimension of the tape cassette 22 is large, the two gripped blocks 45 included in the tape cassette 22 are a combination of the first gripped block 45a and the second gripped block 45b (FIG. 36(b)). or a combination of the first gripped block 45a and the third gripped block 45c (FIG. 36(c)), or a combination of the first gripped block 45a and the fourth gripped block 45d (FIG. 36(d)). ) or Specifically, as the width dimension of the tape cassette 22 increases, the gripped block 45 having a longer Y-direction length (interval between the front and rear recessed portions 45M) is added.

Here, when the second gripped block 45b is added in addition to the first gripped block 45a (FIG. 36(b)), as shown in FIGS. The distance between the gripped block 45a and the second gripped block 45b in the X direction (the width direction of the tape cassette 22) is the distance between the rows of the first gripping pins 133a and the rows of the second gripping pins 133b in the chuck device 121 in the X direction. is set to be equal to When the third gripped block 45c is added in addition to the first gripped block 45a (FIG. 36(c)), as shown in FIGS. The interval between the gripping block 45a and the third gripped block 45c is set to be equal to the interval between the row of the first gripping pins 133a and the row of the third gripping pins 133c. Further, when adding the fourth block to be grasped 45d in addition to the first block to be grasped 45a (FIG. 36(d)), as shown in FIGS. The interval between 45a and the fourth gripped block 45d is set to be equal to the interval between the row of the first gripping pins 133a and the row of the fourth gripping pins 133d.

When the tape cassette supply device 1H grips the tape cassette 22 having only the first gripped block 45a, the first gripped block 45a is gripped by the first gripping pin 133a (FIG. 37(a)→FIG. 37(b)). When gripping the tape cassette 22 including the second gripped block 45b in addition to the first gripped block 45a, the first gripped block 45a is gripped by the first gripped block 45a and the second gripped pin 133b is held. grips the second gripped block 45b (FIG. 38(a)→FIG. 38(b)).

When the tape cassette supply device 1H grips the tape cassette 22 having the third gripped block 45c in addition to the first gripped block 45a, the first gripped block 45a is gripped by the first gripping pin 133a. At the same time, the third gripped block 45c is gripped by the third gripping pin 133c (FIG. 39(a)→FIG. 39(b)). When gripping the tape cassette 22 including the fourth gripped block 45d in addition to the first gripped block 45a, the first gripped block 45a is gripped by the first gripped block 133a, and the fourth gripped pin 133d is held at the same time. grips the fourth gripped block 45d (FIG. 40(a)→FIG. 40(b)).

As described above, in the present embodiment, the chuck device 121 is configured such that two or more sets of two gripping pins 133 are used to hold two or more gripped blocks 45 provided at each of both ends in the width direction of the storage cassette 22B. is designed to hold the

In this embodiment, the four sets of gripping pins 133 provided in the chuck device 121 have different intervals in the Y direction. 121 prevents the other adjacent tape cassettes 22 from being erroneously gripped together.

FIG. 41(a) shows a state in which the tape cassette 22 having only the first gripped block 45a and the tape cassette 22 having the first gripped block 45a and the fourth gripped block 45d are arranged side by side. . In such a case, by gripping the first gripped block 45a with the two gripping pins 133 (first gripping pins 133a) having the smallest distance L1 (FIG. 41(a)→FIG. 41(b)), , only the target tape cassette 22 can be gripped.

Next, the tape feeding section 64 will be described. 21, 23 and 23, the tape feeder 64 is attached to the lower end of a feeder base 125B extending downward from the front end of the Y-axis table 125. As shown in FIG. When the X-axis table 123 drives the Y-axis table 125 in the X direction, the tape feeding section 64 moves in the X direction together with the feeding section base 125B.

42 and 43(a), (b), the tape feeding section 64 comprises a feeding mechanism section 64A and a tape support mechanism section 64B. The feed mechanism section 64A has a sprocket drive motor 141 and a sprocket 142 .

42 and 43(a), (b), the sprocket drive motor 141 is provided on the feeder base 125B with the drive shaft 141J directed in the X direction, and the sprocket 142 is attached to the drive shaft 141J. The sprocket 142 has a plurality of engagement pins 142P on its outer periphery. The operation of the sprocket drive motor 141 is controlled by the controller 76 . When the sprocket drive motor 141 rotates the drive shaft 141J, the sprocket 142 rotates within the YZ plane.

42 and 43(a), (b), the tape support mechanism section 64B has an arm drive cylinder 143 (arm drive section) and a support arm 144. As shown in FIG. The arm drive cylinder 143 is arranged so that the arm drive rod 143R, which is a piston rod, advances and retreats within the XZ plane. The upper end of the arm drive rod 143R is directed obliquely upward. A controller 76 controls the forward/backward movement of the arm drive rod 143R by the arm drive cylinder 143 .

43(a) and (b), the support arm 144 is attached to the arm drive rod 143R. The support arm 144 has its distal end directed obliquely upward, and its axis extends parallel to the extending direction of the axis of the arm drive rod 143R. Therefore, when the arm drive cylinder 143 advances and retreats the arm drive rod 143R, the support arm 144 advances and retreats integrally with the arm drive rod 143R.

When the arm drive cylinder 143 retracts the arm drive rod 143R by full stroke (FIG. 43(a)), the tip (upper end) of the support arm 144 moves from directly below the sprocket 142 to laterally below (sprocket drive). (below the motor 141). On the other hand, when the arm drive cylinder 143 advances the arm drive rod 143R with its full stroke (FIG. 43(b)), the tip of the support arm 144 is positioned directly below the sprocket 142. As shown in FIG.

Next, a procedure (tape cassette supply method) for supplying (transferring) the tape cassette 22 (storage cassette 22B) to the component supply unit 1B provided in the component mounting apparatus 1T by the tape cassette supply device 1H having such a configuration will be described. .

When the storage cassette 22B is transferred to the cassette mounting section 33 of the component supply section 1B by the tape cassette supply device 1H, first, the traveling robot RB travels on the floor FL, and the reference base 71 provided in the tape cassette supply device 1H. (Fig. 28). When the traveling robot RB is connected to the reference base 71 of the tape cassette supply device 1H, it travels on the floor FL while pressing the tape cassette supply device 1H from behind. Then, the tape cassette supply device 1H is brought closer to the mounting device main body 1A in a state where the carriage 21 is connected (Fig. 28 → Fig. 29(a) → Fig. 29(b).

The traveling robot RB connects the tape cassette supply device 1H to the mounting device main body 1A in the manner described above. As a result, the supply device side connection portion 111 provided in the tape cassette supply device 1H is connected to the height direction alignment guide 11V and the horizontal direction alignment guide 11W provided in the mounting device main body portion 1A.

In this method of connecting the tape cassette supply device 1H to the mounting device main body 1A (inter-device connection method; part of the tape cassette supply method), the tape cassette feeding device 1H is moved and brought closer to the mounting device main body 1A. As a result, a step (connection step) of connecting the tape cassette feeding device 1H to the left and right height direction alignment guides 11V is included.

In the inter-connection method according to the present embodiment, the tape cassette supply device 1H, which is a heavy object, is connected not to the component supply section 1B (carriage 21) of the component mounting device 1T, but to the mounting device main body 1A. be. Therefore, as described above, the weight of the tape cassette feeding device 1H does not act on the carriage 21 and the attitude of the carriage 21 (that is, the attitude of the tape feeder 23) does not change, and the component BH is picked up by the mounting head 13. Mistakes can be prevented.

When the tape cassette feeding device 1H is connected to the mounting device main body 1A as described above, the left and right height alignment rollers 114 of the tape cassette feeding device 1H are aligned with the left and right heights of the mounting device main body 1A. It is in a state of being fitted into left and right concave portions 11K provided in the direction alignment guide 11V. As a result, the supply device main body 72 is positioned in the height direction with respect to the mounting device main body 1A (FIG. 29(c)).

As described above, in the tape cassette supply method according to the present embodiment, by connecting the supply device side connection portion 111 to the component mounting device 1T, the supply device main body portion 72 is moved in the height direction (Z direction) with respect to the component mounting device 1T. position (positioning step).

In the above positioning step, the supply device main body 72 receives an upward pressing force from the mounting device main body 1A in the direction in which the front portion is pushed up. is equipped with a floating mechanism 73, which prevents the lifting base 72a, which is the bottom plate of the feeder main body 72, from tilting from the horizontal posture (with respect to the reference base 71 in the horizontal posture), so that a stable posture can be maintained. can.

In FIG. 27, the base 11 of the component mounting apparatus 1T is provided with a power supply connector 11C as power supply means, and the tape cassette supply apparatus 1H is provided with a power reception connector 151 as power reception means. ing. When the tape cassette supply device 1H is connected to the component mounting device 1T, the power receiving connector 151 and the power supply connector 11C are fitted together, and the tape cassette feeding device 1H and the component mounting device 1T are electrically connected (see FIG. 27). → Fig. 31). As a result, the tape cassette supply device 1H can receive power supplied from the component mounting device 1T.

After the feeding device main body 72 is connected and positioned to the mounting device main body 1A as described above, the tape cassette feeding device 1H operates the chuck device moving mechanism 122 to move the chuck device 121 to the transfer target. is located above the storage cassette 22B. Then, the chuck device 121 grips the gripped block 45 provided in the upper portion (frame upper portion 43a) of the storage portion 41 of the storage cassette 22B to be transferred. Specifically, as described above, by closing the opening/closing block 132 from the open position toward the closed position, the gripped block 45 is gripped by the two gripping pins 133 (FIG. 35(a)→ FIG. 35(b)).

As described above, the tape cassette supply method according to the present embodiment includes a step (gripping step) of gripping the tape cassette (storage cassette 22B) by the chuck device 121, which is a gripping portion.

In this gripping step, as described above, the tape cassette 22 having only the first gripped block 45a is gripped by only the two gripping pins 133 (first gripping pins 133a). For a tape cassette 22 having other gripping blocks 45 (second gripping block 45b, third gripping block 45c, or fourth gripping block 45d) in addition to first gripping block 45a, In addition to the first gripping pin 133a, the two gripped blocks 45 are gripped by any one of the second gripping pin 133b, the third gripping pin 133c, and the fourth gripping pin 133d (FIG. 44).

After gripping one or two gripped blocks 45 provided in the tape cassette 22 by the chuck device 121, the tape cassette supply device 1H operates the Y-axis table 125 of the cassette transfer section 63 (chuck device moving mechanism 122). , moves the chuck lifting cylinder 126 forward (arrow E1 shown in FIG. 45). Then, the chuck elevating cylinder 126 is operated to lower the chuck device 121 to the tape feeding position. Here, the "tape feed position" means that the leading portion of the carrier tape CT pulled out from the storage cassette 22B and engaged with the two tape locking projections 55 is aligned substantially horizontally with the tape inlet 23G of the tape feeder 23 ( Here, it is a position (FIG. 45) facing the Y direction).

When positioning the storage cassette 22B at the tape feed position, the cassette transfer unit 63 of the tape cassette supply device 1H first positions the leading end of the carrier tape CT pulled out from the storage cassette 22B directly below the sprocket 142. (FIGS. 43(a) and 46(a)). Then, by operating the chuck lifting cylinder 126, the chuck device 121 is slightly lifted (arrow F1 shown in FIG. 46(b)). As the chuck device 121 rises, the lowermost end of the sprocket 142 is moved to one feed hole SH (the feed hole SH positioned between the two fitted tape locking projections 55) at the leading end of the carrier tape CT. engagement pin 142P (lowermost end engagement pin 142D).

As described above, in the present embodiment, the sprocket 142 functions as a tape engaging portion that engages with the feed hole SH of the leading portion of the carrier tape CT pulled out from the tape cassette 22 (storage cassette 22B). When the lowermost end engaging pin 142D of the sprocket 142 engages one feeding hole SH at the leading end of the carrier tape CT (FIGS. 43(b) and 46(b)), the storage cassette 22B is positioned at the tape feeding position. state.

When the storage cassette 22B is positioned at the tape feed position, the tape cassette supply device 1H operates the arm drive cylinder 143 to advance the arm drive rod 143R (arrow P shown in FIG. 46(c)). As a result, the leading end of the carrier tape CT is supported from below by the leading end of the support arm 144 entering between the two tape locking projections 55, and is sandwiched between the sprocket 142 and the support arm 144 ( Figures 43(b) and 46(c)).

A groove extending along the direction in which the carrier tape CT extends is formed at the tip of the support arm 144 . Therefore, the support arm 144 can support the leading end of the carrier tape CT without interfering with the lowermost engaging pin 142D of the sprocket 142 penetrating the carrier tape CT from above. Thus, in the present embodiment, the support arm 144 serves as a support portion that supports the leading portion of the carrier tape CT.

When the leading end of the carrier tape CT is sandwiched between the sprocket 142 and the support arm 144, the cassette transfer unit 63 lowers the storage cassette 22B using the chuck lifting cylinder 126 (FIG. 46(d)). arrow F2 shown in the middle). As a result, the two tape locking projections 55 come out downward from the leading end of the carrier tape CT. The state of engagement with dowel pin 142D is maintained (Fig. 46(d)).

After the storage cassette 22B is lowered as described above and the two tape locking protrusions 55 are pulled out of the carrier tape CT, the tape cassette supply device 1H rotates the sprocket 142 to direct the carrier tape CT forward. (ie, toward the tape entrance 23G) (arrow R shown in FIG. 47(a)). As a result, the carrier tape CT advances forward (FIG. 47(a)→FIG. 47(b)), and its leading end enters the tape entrance 23G of the tape feeder 23 (FIG. 47(b)). At this time, since the carrier tape CT is supported from below by the support arm 144, it advances straight forward (toward the tape entrance 23G) without sagging downward. Here, the tape feeder 23 is connected to the component mounting device 1T through the carriage 21, and the tape cassette feeding device 1H is also connected to the component mounting device 1T. The leading portion of the carrier tape CT can be fed accurately toward 23G.

As described above, the tape cassette feeding method according to the present embodiment holds the leading portion of the carrier tape CT pulled out from the storage cassette 22B when the tape cassette 22 (storage cassette 22B) is positioned at the tape feed position. , a step of feeding the leading portion of the carrier tape CT toward the tape inlet 23G of the tape feeder 23 (tape feeding step).

When the leading portion of the carrier tape CT fed by the tape feeder 64 is inserted into the tape inlet 23G of the tape feeder 23, the tape feeder 23 detects this and pulls in the carrier tape CT. Then, when the carrier tape CT is pulled in by the tape feeder 23 by a certain amount (FIG. 48), the tape cassette supply device 1H moves the chuck device 121 rearward (arrow E2 shown in FIG. 49), and the shutter operating section 75 is operated to raise the operation bar 92 (arrow J1 shown in FIG. 49).

When the operation bar 92 contacts the operation lever 53 of the storage cassette 22B from below by moving the chuck device 121 backward and raising the operation bar 92 (FIG. 49), the tape cassette supply device 1H starts to move the chuck device 121. (that is, the storage portion 41 of the storage cassette 22B) is moved diagonally forward and downward (arrow E3 shown in FIG. 50). As a result, the operating lever 53 rises relative to the housing portion 41 . The tape cassette supply device 1H stops the movement of the chuck device 121 when the operation lever 53 reaches a predetermined height (referred to as “first height”) set with respect to the storage section 41 .

In this embodiment, the "first height" is a height corresponding to about 1/3 of the total amount of movement of the operating lever 53 in the height direction when the shutter 42 is moved from the closed position to the open position. is set to Therefore, when the operating lever 53 reaches the first height, the front opening 41K of the storage cassette 22B is opened to about one-third of its entirety (FIG. 50).

After stopping the movement of the chuck device 121, the tape cassette supply device 1H raises the operation bar 92 by means of the operation bar driving section 93 (arrow J2 shown in FIG. 51). The tape cassette supply device 1H stops the operation lever 53 from rising when the operation lever 53 reaches a predetermined height (referred to as a “second height”) set with respect to the storage section 41 .

In the present embodiment, the above-mentioned "second height" corresponds to about 2/3 of the total amount of movement of the operating lever 53 in the height direction when the shutter 42 is moved from the closed position to the open position. is set to Therefore, when the operating lever 53 reaches the second height, the front opening 41K of the storage cassette 22B is opened about two-thirds of its entirety (FIG. 51).

After stopping the lifting of the operation bar 92, the tape cassette supply device 1H obliquely moves the chuck device 121 rearward and downward (arrow E4 shown in FIG. 52). As a result, the operating lever 53 rises relative to the housing portion 41 . The tape cassette supply device 1H stops the movement of the chuck device 121 when the operating lever 53 reaches a predetermined height (referred to as “third height”) set with respect to the storage section 41 .

In this embodiment, the "third height" is set to a height corresponding to the total amount of movement of the operating lever 53 in the height direction when the shutter 42 is moved from the closed position to the open position. . Therefore, when the operating lever 53 reaches the third height, the front opening 41K of the storage cassette 22B is entirely opened (FIGS. 52 and 18(c)).

When the entire front opening 41K of the storage cassette 22B is opened, the tape cassette supply device 1H obliquely moves the chuck device 121 forward and upward (arrow E5 shown in FIG. 53). The storage cassette 22B is moved above the storage cassette mounting portion 39 (three storage cassette holding pins 33P). Then, by lowering the chuck device 121 (arrow E6 shown in FIG. 54), the storage cassette 22B is attached to the cassette attachment portion 33 (attached to the storage cassette attachment portion 39) (FIG. 55(a)→FIG. 55( b)).

When the storage cassette 22B is attached to the cassette attachment portion 33 (storage cassette attachment portion 39), the tape cassette supply device 1H inserts the cassette of the carriage 21 into the three pin insertion portions 43S provided in the frame lower portion 43b of the storage cassette 22B. The three storage cassette holding pins 33P provided on the mounting portion 33 are inserted (FIG. 55(a)→FIG. 55(b)). When the storage cassette 22B is attached to the cassette attachment portion 33, the transfer of the storage cassette 22B to the component supply portion 1B is completed.

As described above, in the tape cassette supply method of the present embodiment, after the storage cassette 22B is gripped by the chuck device 121 and taken out from the supply device main body 72 positioned in the positioning step, the chuck device 121 is moved to store the storage cassette 22B. It includes a step (transfer step) of moving the storage cassette 22B along a path in which the leading portion of the carrier tape CT pulled out from the cassette 22B passes through the tape feeding position and transferring it to the component mounting apparatus 1T. there is

In the tape cassette supply device 1H, when the storage cassette 22B is attached to the cassette attachment portion 33 in the transfer step, the front end 43E of the lower portion (frame lower portion 43b) of the storage cassette 22B is attached to the receiving cassette attachment portion 38. 55(a)→FIG. 55(b). As shown in FIG. 9, the lower end of the frame lower portion 43b is formed with a tapered surface 43D having a shape (a shape that narrows downward) that facilitates guiding the frame lower portion 43b between the pair of projecting portions 44H. Only by lowering the storage cassette 22B, the lower front end 43E of the storage cassette 22B can be reliably passed between the pair of projecting portions 44H of the receiving cassette 22A.

When the storage cassette 22B is attached to the storage cassette attachment portion 39 in the manner described above (with the lower front end 43E passing between the pair of overhanging portions 44H of the receiving cassette 22A), the pair of storage cassettes 22B are mounted. The side plates 44 are positioned inside the pair of side plates 44 of the receiving cassette 22A (FIG. 55(b)). As a result, the storage cassette 22B is sandwiched between the pair of side plates 44 of the reception cassette 22A located in front of it, and its movement in the X direction (the direction of tilting to the side) is suppressed. stabilizes.

At least part of the front opening 41K of the storage cassette 22B is inserted into the front opening 41K of the receiving cassette 22A. In other words, the storage cassette mounting section 39 mounts the storage cassette 22B with at least part of the front opening 41K of the storage cassette 22B inserted into the front opening 41K of the receiving cassette 22A. As a result, since the side plates 44 of the storage cassette 22B are positioned inside the side plates 44 of the receiving cassette 22A, troubles such as the roll body RT moving from the storage cassette 22B to the receiving cassette 22A being caught by the edges of the side plates 44 can be avoided. can be prevented.

When the transfer of the storage cassette 22B to the component supply unit 1B is completed, the tape cassette supply device 1H operates the chuck elevating cylinder 126 to raise the chuck device 121 (arrow E7 shown in FIG. 56), and the arm By operating the drive cylinder 143, the support arm 144 supporting the carrier tape CT is lowered. As a result, the carrier tape CT inserted into the tape entrance 23G of the tape feeder 23 is released from the support by the support arm 144 (the carrier tape CT is in a suspended state, FIG. 57).

The tape feeder 23, which has drawn in the carrier tape CT in the process of mounting the storage cassette 22B to the storage cassette mounting portion 39, conveys the carrier tape CT as it is when the drawn-in carrier tape CT is the current tape, thereby feeding the component BH. supply. On the other hand, if the drawn-in carrier tape CT is a supplementary tape, the supplementary tape is put on standby until it is detected that the trailing portion of the current tape has passed a predetermined position within the tape feeder 23 . When the tape feeder 23 starts conveying the replenishment tape, the roll body RT stored in the storage cassette 22B is pulled by the carrier tape CT drawn by the tape feeder 23 and rolls forward, and the receiving cassette located in front of it rolls. 58(a)→FIG. 58(b)→FIG. 59(a)).

As described above, when the roll RT moves from the storage cassette 22B into the receiving cassette 22A, the roll RT is guided by the guide surface 43F of the receiving cassette 22A. In addition, since the pair of side plates 44 of the storage cassette 22B are positioned inside the pair of side plates 44 of the receiving cassette 22A positioned in front thereof, the roll RT can be smoothly moved into the receiving cassette 22A and stored therein. (FIG. 58(b)→FIG. 59(a)).

When the roll body RT stored in the storage cassette 22B is moved into the receiving cassette 22A, the storage cassette 22B becomes empty. The empty storage cassette 22B is removed from the cassette mounting section 33 (FIG. 59(b)) in order to load the next replenishment tape roll body RT (storage cassette 22B) into the component supply section 1B, and the cassette stock section 74 (FIG. 60). The empty storage cassette 22B is moved by gripping the block 45 to be gripped by the chuck device 121 and movement of the chuck device 121 by the chuck device 121 by the cassette transfer section 63 .

After returning the empty storage cassette 22B to the cassette stock section 74, the tape cassette supply device 1H moves the cassette transfer section 63 from the cassette stock section 74 to supply the supplementary storage cassette 22B to the component mounting device 1T. Take out the tape cassette 22 (storage cassette 22B). Then, the new storage cassette 22B is transferred to the cassette mounting portion 33 along the route passing through the tape feeding position (FIG. 61(a)→FIG. 61(b)).

After transferring a new storage cassette 22B to the cassette mounting portion 33, the tape cassette supply device 1H lifts the chuck device 121 (arrow E8 shown in FIG. 62) and lowers the support arm 144 to feed the carrier tape. Unsupport the CT (Fig. 63).

When it is detected that the trailing portion of the roll body RT carrier tape CT in the receiving cassette 22A has passed a predetermined position in the tape feeder 23, the tape feeder 23 continues feeding the carrier tape CT by the tape feeder 23. The supplementary tape (carrier tape CT in the storage cassette 22B) that has been on standby is transported as a new current tape (FIG. 64(a)). Then, the supply of parts BH is continued. When the tape feeder 23 starts conveying the carrier tape CT from the roll RT stored in the storage cassette 22B, the roll RT of the carrier tape CT is pulled and rolls forward. 64(a)→FIG. 64(b).

As a result, the storage cassette 22B is emptied and becomes the same state as in FIG. 59(a). The steps of (a)→FIG. 64(b)→FIG. 59(a) are repeated. Therefore, the component mounting apparatus 1T can continue supplying the components BH by the tape feeder 23 while receiving the replenishment of the roll body RT (that is, the carrier tape CT).

In FIG. 59(b), the receiving cassette 22A removed from the receiving cassette mounting portion 38 can be used as a new storage cassette 22B. Further, since the receiving cassette 22A uses the tape cassette 22 upside down, the winding direction of the roll body RT housed in the receiving cassette 22A is the same as the winding direction when used as the storage cassette 22B. Therefore, when using the receiving cassette 22A as the storage cassette 22B, it is possible to omit the work of taking out the roll body RT, reversing the orientation, and storing it again.

As described above, the tape cassette feeding device 1H in this embodiment has the floating mechanism 73 between the reference base 71 and the feeding device main body 72. The floating mechanism 73 is connected to the reference base 71 and the feeder main body 72 to operate according to the change in the distance between the reference base 71 and the feeder main body 72; It has a link mechanism (parallel link) having a connecting portion 102 for interlocking the operation of. Therefore, according to the tape cassette feeding device 1H and the tape cassette feeding method of the present embodiment, when the tape cassette feeding device 1H is connected to the component mounting device 1T, the feeding device body 72 pushes up from the component mounting device 1T. Even if it is received, the horizontal posture of the elevating base 72a, which is the bottom plate of the feeder main body 72, can be maintained, and the feeder main body 72 can maintain a stable posture.

Further, the tape cassette supply device 1H in the present embodiment moves the chuck device 121 as a gripping portion that grips the tape cassette 22 (storage cassette 22B) and the chuck device 121 that grips the storage cassette 22B to form a component mounting device. 1T is provided with a cassette transfer section 63 consisting of a chuck device moving mechanism 122 as gripping section moving means for transferring the storage cassette 22B. Therefore, according to the tape cassette supply device 1H and the tape cassette supply method of the present embodiment, the tape cassette (storage cassette 22B) can be automatically transferred to the component mounting device 1T without relying on the human power of the operator. .

Further, in the tape cassette supply device 1H in the present embodiment, the storage cassette 22B taken out from the cassette stock section 74 is provided in the component mounting device 1T with the leading portion of the carrier tape CT in the state of being pulled out from the storage cassette 22B. A cassette transfer section 63 is provided for transferring the storage cassette 22B to the component mounting apparatus 1T by moving it along a path passing through the tape feeding position facing the tape inlet 23G of the tape feeder 23, and the storage cassette 22B is tape-fed by the cassette transfer section 63. A tape feeder 64 that holds the leading end of the carrier tape CT pulled out from the storage cassette 22B when positioned at the position and then feeds the leading end of the carrier tape CT toward the tape inlet 23G. It's becoming Therefore, according to the tape cassette supply device 1H and the tape cassette supply method of the present embodiment, the storage cassette 22B is transferred to the component mounting device 1T and the carrier tape CT pulled out from the storage cassette 22B is transferred to the tape feeder 23. Insertion can be performed automatically without manual intervention by an operator.

In the component mounting system 1 according to the present embodiment, the mounting device main body 1A of the component mounting device 1T includes a carriage holding portion 11H that holds the carriage 21 on which the tape feeder 23 is mounted, and the tape cassette supply device 1H. Mounting device side connecting portions (left and right height direction alignment guides 11V and left and right horizontal direction alignment guides 11W) to be connected are provided, and the tape cassette feeding device 1H is supported by the mounting device main body 1A instead of the carriage 21. It's like For this reason, according to the component mounting system 1 (and the device connection method in the component mounting system 1) of the present embodiment, the components BH that may be sucked by connecting the heavy tape cassette supply device 1H to the carriage 21 are prevented. Mistakes can be prevented.

As described above, according to the tape cassette supply device 1H and the tape cassette supply method of the present embodiment, the storage cassette 22B is transferred to the component mounting device 1T and the carrier tape CT pulled out from the storage cassette 22B. The insertion into the feeder 23 can be automatically performed without human power of the operator.

Although the embodiments of the present invention have been described so far, the present invention is not limited to those described above, and various modifications and the like are possible. For example, in the transfer step of transferring the storage cassette 22B shown in the above-described embodiment to the mounting device main body 1A, the tape feeding is performed before the storage cassette 22B is mounted on the cassette mounting portion 33 of the mounting device main body 1A. Although the portion 64 feeds the carrier tape CT to the tape inlet 23G of the tape feeder 23, the tape feeding portion 64 feeds the carrier tape CT to the tape feeder 23 after the storage cassette 22B is mounted in the cassette mounting portion 33. It can be like this.

Further, in the above-described embodiment, the height alignment roller 114, which is the height adjustment section, is adjusted from the height direction alignment guide 11V of the component mounting device 1T when the tape cassette feeding device 1H is connected to the component mounting device 1T. The height of the supply device main body 72 with respect to the component mounting device (height direction alignment guide 11V) is adjusted by receiving an upward force (push-up force). The height of the supply device main body 72 with respect to the component mounting device (the height direction alignment guide 11V) may be adjusted by receiving a downward force (pushing force) from the direction alignment guide 11V.

In the above-described embodiment, the number of sets of gripping pins 133 provided on the two opening/closing blocks 132 is four. It can be 5 or more sets. If only one type of gripped block 45 can be attached to the tape cassette 22, the set of gripping pins 133 may be only one set having intervals corresponding to the one type of gripped block 45. FIG.

Further, the tape feeding section 64 holds the leading portion of the carrier tape CT pulled out from the storage cassette 22B when the storage cassette 22B is positioned at the tape feeding position by the cassette transfer section 63, and then moves the carrier tape CT. It is only necessary to have the function of sending the leading portion of the tape CT toward the tape entrance 23G. Therefore, the tape feeding portion 64 is not necessarily a tape engaging portion that engages with the feeding hole SH provided in the leading portion of the carrier tape CT pulled out from the storage cassette 22B as shown in the above-described embodiment. The configuration may not include the sprocket 142 and the support arm 144 as a support section that supports the carrier tape CT from below with the feed holes SH engaged with the sprocket 142 .

To provide a tape cassette supply device, a component mounting system, and a tape cassette supply method capable of automatically transferring a tape cassette to the component mounting device and inserting a carrier tape pulled out from the tape cassette into the component supply unit.

1 component mounting system 1T component mounting device 1A mounting device main body 1B component supply unit 1H tape cassette supply device 11H cart holder 11V height direction alignment guide 11W horizontal direction alignment guide 11C power supply connector 21 cart 22 tape cassette 23 tape feeder 23G Tape entrance 45 gripped block 45M depression 45a first gripped block 45b second gripped block 45c third gripped block 45d fourth gripped block 63 cassette transfer unit 64 tape feeding unit 71 reference base 71S wheel 72 supply device Body portion 73 Floating mechanism 74 Cassette stock portion 82 Spring member 101 Link portion 102 Connecting portion 111 Supply device side connection portion 114 Height alignment roller 121 Chuck device 122 Chuck device moving mechanism 132 Opening/closing block 133 Grip pin 133a First grip pin 133b Second 2 gripping pin 133c 3rd gripping pin 133d 4th gripping pin 142 sprocket (tape engaging portion)
144 support arm (support)
151 power receiving connector RB traveling robot (moving object)
CT Carrier tape BH Part SH Feed hole RT Roll body FL Floor

Claims (9)

A tape cassette supply device for supplying a tape cassette containing a carrier tape to a component mounting device,
a cassette stock section for stocking tape cassettes;
A path through which the tape cassette taken out from the cassette stock section passes through a tape feed position where the leading end of the carrier tape in a state of being pulled out from the tape cassette faces the tape entrance of the component supply unit provided in the component mounting device. a cassette transfer unit that moves the tape cassette with and transfers it to the component mounting device;
After holding the leading portion of the carrier tape pulled out from the tape cassette when the tape cassette is positioned at the tape feeding position by the cassette loading section, the leading portion of the carrier tape is fed toward the tape entrance. and a tape feeding unit. The tape feeding section includes a tape engaging section that engages with a feed hole provided in the leading portion of the carrier tape pulled out from the tape cassette, and a carrier tape that is in a state where the feed hole is engaged with the tape engaging section. 2. The tape cassette feeding device according to claim 1, further comprising a supporting portion for supporting from below. 3. After the leading portion of the carrier tape is inserted into the tape entrance by the tape feeding section feeding out the carrier tape, the supporting section moves downward to release the support of the carrier tape. The tape cassette supply device according to 1. 4. The tape cassette feeding device according to claim 3, wherein after said cassette transfer section transfers the tape cassette to said component mounting device, said tape feeding section feeds the leading portion of the carrier tape toward said tape entrance. 5. The tape cassette feeding device according to any one of claims 1 to 4, which has wheels for running on the floor. 6. The tape cassette feeding device according to claim 5, which is connected to said component mounting device by being moved on said floor by a moving body running on said floor. A component mounting system comprising: a component mounting device; a tape cassette supply device for supplying a tape cassette containing a carrier tape to the component mounting device; and a cassette transfer section for transferring the tape cassette,
The tape cassette supply device includes:
a cassette stock section for stocking tape cassettes;
A path through which the tape cassette taken out from the cassette stock section passes through a tape feed position where the leading end of the carrier tape in a state of being pulled out from the tape cassette faces the tape entrance of the component supply unit provided in the component mounting device. a cassette transfer unit that moves the tape cassette with and transfers it to the component mounting device;
After holding the leading portion of the carrier tape pulled out from the tape cassette when the tape cassette is positioned at the tape feeding position by the cassette loading section, the leading portion of the carrier tape is fed toward the tape entrance. A component mounting system comprising: a tape feeding section; 8. The component mounting system according to claim 7, wherein said cassette transfer section is provided in said tape cassette supply device. A tape cassette supply method by the component mounting system according to claim 7 or claim 8,
A tape cassette is taken out from the cassette stock part, and the leading end of the carrier tape pulled out from the taken out tape cassette passes through a tape feed position facing a tape entrance of a component supply unit provided in the component mounting device. a transfer step of moving the tape cassette along a path and transferring it to the component mounting device;
After holding the leading portion of the carrier tape pulled out from the tape cassette when the tape cassette is positioned at the tape feeding position, the leading portion of the carrier tape is held during or after the transferring step. toward the tape entrance; and
A tape cassette supply method comprising:

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