JP6830186B2 - Parts supply system and parts supply method - Google Patents

Description

The present invention relates to a parts supply system and a parts supply method for pitch-feeding a carrier tape containing parts.

A tape feeder is known as a component supply device in a component mounting device. The tape feeder supplies the component to the component suction position by the mounting head of the component mounting mechanism by pitch-feeding the carrier tape holding the component. As a method of continuously supplying parts without stopping the mounting operation in the tape feeder, a splicing tape is used to attach a new carrier tape (successor tape) to the end of the previously mounted carrier tape (preceding tape). Tape splicing to connect is used.

In this tape splicing method, the operator needs to perform complicated work every time the supply reel is replaced, and it has been desired to reduce these workloads. For this reason, as a tape replenishment method, an automatic loading type tape feeder is used in which the succeeding tape is set in the tape feeder, automatically loaded, and the carrier tape is pitch-fed without performing the tape splicing work (). For example, see Patent Document 1).

Further, the carrier tape has a structure in which the base tape for accommodating the parts is covered with the cover tape, and it is necessary to peel off the cover tape to expose the parts while the carrier tape is pitch-fed to the component suction position. The prior art shown in Patent Document 1 includes a component exposing means having a release blade, and the cover tape is peeled off from the carrier tape that is pitch-fed by inserting the release blade between the base tape and the cover tape. Is exposed.

Japanese Unexamined Patent Publication No. 2011-21169

However, it is not assumed that the tape-spliced carrier tape is put into the tape feeder of the automatic loading method in the prior art including Patent Document 1. Therefore, if the carrier tape spliced with tape is mistakenly put into the tape feeder of the automatic loading method, there is a problem that the peeling blade of the component exposing means may be damaged by the splicing tape.

Therefore, an object of the present invention is to provide a component supply system and a component supply method capable of preventing the occurrence of an abnormality in the transfer of carrier tape in an automatic loading type tape feeder.

The parts supply system of the present invention automatically transfers a carrier tape that stores parts and is covered with a cover tape, and supplies the parts exposed from the carrier tape by the parts exposing means, and the carrier tape. A joint determination unit for determining the presence or absence of a joint portion in which two front and rear carrier tapes are joined, and a control unit for controlling the transfer of the carrier tape in the component supply means are provided, and the joint determination unit is the joint. When it is determined that there is a joint portion, the control unit restricts the transfer of the carrier tape so that the joint portion is not transferred before the component exposing means.

The parts supply method of the present invention is a parts supply system including a parts supply means for storing parts, automatically transferring a carrier tape covered with a cover tape, and supplying the parts exposed from the carrier tape by the parts exposure means. In, when it is determined whether or not there is a joint portion in which two carrier tapes before and after the carrier tape are joined and it is determined that the joint portion is present, the joint portion is not transferred before the component exposing means. As described above, the transfer of the carrier tape is restricted.

According to the present invention, it is possible to prevent the occurrence of an abnormality in the transfer of the carrier tape in the tape feeder of the automatic loading type.

It is a block diagram of the component mounting line which concerns on one Embodiment of this invention. It is a top view of the component mounting apparatus which concerns on one Embodiment of this invention. It is a partial sectional view of the component mounting apparatus which concerns on one Embodiment of this invention. It is a block diagram of the tape feeder which concerns on one Embodiment of this invention. It is a functional explanatory view of the sprocket used for the tape feed mechanism in the tape feeder which concerns on one Embodiment of this invention. It is explanatory drawing of the cover tape peeling operation by the cover tape peeling part of the tape feeder which concerns on one Embodiment of this invention. It is explanatory drawing of the replenishment operation of the carrier tape in the tape feeder which concerns on one Embodiment of this invention. It is explanatory drawing of the detection process of the splicing part of the spliced carrier tape which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the control system of the component mounting line which concerns on one Embodiment of this invention. It is a block diagram of (a) supply reel information used in the component mounting line which concerns on one Embodiment of this invention, and (b) block diagram of component arrangement data. It is a flow chart of the component supply method of 1st Embodiment which concerns on 1st Embodiment of this invention. It is a flow chart of the component supply method of the 2nd Embodiment which concerns on 1st Embodiment of this invention. It is a process explanatory drawing of the component supply method of the 2nd Embodiment which concerns on 1st Embodiment of this invention.

An embodiment of the present invention will be described in detail below with reference to the drawings. The configuration, shape, etc. described below are examples for explanation, and can be appropriately changed according to the specifications of the component mounting line. In the following, the corresponding elements are designated by the same reference numerals in all the drawings, and duplicate description will be omitted. In FIG. 2 and a part described later, the two axial directions orthogonal to each other in the horizontal plane are the X direction of the substrate transport direction (horizontal direction in FIG. 2) and the Y direction orthogonal to the substrate transport direction (front-back direction in FIG. 2). Is shown. In FIG. 3 and a part described later, the Z direction is shown as a height direction orthogonal to the horizontal plane. The Z direction is the vertical direction or the orthogonal direction when the component mounting line is installed on the horizontal plane.

First, the component mounting line will be described with reference to FIG. In FIG. 1, the component mounting line 1 has a function of mounting components on a board to manufacture a mounting board. The component mounting line 1 has a configuration in which the printing devices M1, the component mounting devices M2 to M4, and the reflow device M5 are connected and connected by a communication network 2, and the whole is controlled by the management computer 3. The printing apparatus M1 screen-prints paste-like solder on the electrode for joining parts formed on the substrate. The component mounting devices M2 to M4 perform component mounting work in which components are taken out from a component feeder such as a tape feeder arranged in a component supply unit by a mounting head and transferred to a board for mounting. The reflow device M5 melts the solder and solder-bonds the component terminals mounted on the substrate to the electrodes of the substrate.

Next, the configurations of the component mounting devices M2 to M4 will be described with reference to FIGS. 2 and 3. FIG. 3 partially shows the AA cross section in FIG. In FIG. 2, a substrate transfer mechanism 5 is arranged in the X direction at the center of the base 4. The board transfer mechanism 5 conveys the board 6 carried in from the upstream side, and positions and holds the board 6 on the mounting stage set for executing the component mounting work. Parts supply units 7 are arranged on both sides of the board transfer mechanism 5, and a plurality of tape feeders 8 are mounted in parallel on each component supply unit 7. The tape feeder 8 supplies the component to the component suction position by the mounting head of the component mounting mechanism described below by pitch-feeding the carrier tape containing the component in the tape feeding direction.

A Y-axis moving table 9 provided with a linear drive mechanism is arranged at one end of the upper surface of the base 4 in the X direction. Two X-axis moving tables 10 similarly provided with a linear drive mechanism are coupled to the Y-axis moving table 9 so as to be movable in the Y direction. A mounting head 11 is mounted on each of the two X-axis moving tables 10 so as to be movable in the X direction. The mounting head 11 is a multi-unit mounting head provided with a plurality of holding heads 11a, and as shown in FIG. 3, parts can be sucked and held at the lower end of each holding head 11a so that they can be raised and lowered individually. The suction nozzle 11b is mounted.

By driving the Y-axis moving table 9 and the X-axis moving table 10, the mounting head 11 moves in the X direction and the Y direction. As a result, the two mounting heads 11 suck and hold the parts from the parts suction positions of the tape feeders 8 arranged in the corresponding parts supply units 7 by the suction nozzles 11b, take them out, and position the boards on the board transfer mechanism 5. Transfer and mount at the mounting point of 6. The Y-axis moving table 9, the X-axis moving table 10, and the mounting head 11 constitute a component mounting mechanism 12 for transferring and mounting the components on the substrate 6 by moving the mounting head 11 holding the components.

A component recognition camera 13 is arranged between the component supply unit 7 and the substrate transfer mechanism 5. When the mounting head 11 that has taken out the parts from the parts supply unit 7 moves above the parts recognition camera 13, the parts recognition camera 13 takes an image of the parts held by the parts recognition camera 11 and recognizes the holding posture of the parts. To do. A substrate recognition camera 14 that moves integrally with the mounting head 11 is mounted on the lower surface of the X-axis moving table 10.

When the mounting head 11 moves, the board recognition camera 14 moves above the board 6 positioned by the board transfer mechanism 5, images the board 6, and recognizes the state of the board 6. In the component mounting operation of the mounting head 11 on the board 6, the mounting position correction is performed in consideration of the component recognition result by the component recognition camera 13 and the board recognition result by the board recognition camera 14.

As shown in FIG. 3, a carriage 15 in which a plurality of tape feeders 8 are previously mounted on the feeder base 15a is set in the component supply unit 7. Feeder addresses for specifying the position of the feeders to which the individual tape feeders 8 are mounted are set in the feeder base 15a, and in the component mounting work, each tape in the feeder base 15a is set via these feeder addresses. The feeder 8 is identified.

By clamping the feeder base 15a with respect to the base 4 by a clamping mechanism (not shown), the position of the carriage 15 is fixed in the component supply unit 7. The carriage 15 holds a supply reel 17 that stores the carrier tape 16 holding the parts in a wound state. The carrier tape 16 drawn from the supply reel 17 is pitch-fed by the tape feeder 8 to the component suction position by the suction nozzle 11b.

Next, the configuration and function of the tape feeder 8 will be described with reference to FIG. As shown in FIG. 4, the tape feeder 8 is configured to include a main body portion 8a and a mounting portion 8b projecting downward from the lower surface of the main body portion 8a. When the tape feeder 8 is mounted along the lower surface of the main body 8a along the feeder base 15a, the tape feeder 8 is fixedly mounted to the component supply section 7 and is built in to control the tape feed in the tape feeder 8. The feeder control unit 21 is electrically connected to the device control unit 22 of the component mounting devices M2 to M4.

Inside the main body 8a, a tape traveling path 8c for guiding the carrier tape 16 drawn out from the supply reel 17 and taken into the main body 8a is provided. The tape traveling path 8c is provided so as to communicate with the insertion port 8d into which the carrier tape 16 opened at the upstream end in the tape feeding direction is inserted in the main body 8a to the component suction position where the component is taken out by the mounting head 11. .. In the process of continuously executing the component mounting work, a plurality of carrier tapes 16 are sequentially inserted from the insertion port 8d and supplied to the tape feeder 8.

The tape feeder 8 shown in the present embodiment is a splicing-less method (automatic loading method) in which two carrier tapes 16 sent one after another are sequentially inserted into the insertion slot 8d in a separated state and supplied. Is adopted. Therefore, the carrier tape 16 (1) (hereinafter abbreviated as the preceding tape 16 (1)) that is already mounted on the tape feeder 8 and is the target of parts removal by the mounting head 11 is newly added at the end of the parts. It is not necessary to join the leading end portion of the carrier tape 16 (2) (hereinafter, abbreviated as the subsequent tape 16 (2)) to be attached by the bonding tape.

In FIG. 4, a first tape feeding mechanism 23A and a second tape feeding mechanism for tape feeding the preceding tape 16 (1) and the succeeding tape 16 (2) are on the downstream side and the upstream side of the tape traveling path 8c. 23B is arranged. The second tape feeding mechanism 23B provided on the upstream side has a function of continuously tape feeding the newly mounted succeeding tape 16 (2) from the insertion port 8d side to the first tape feeding mechanism 23A side. The sprocket 24B is rotationally driven by the second motor E2.

A tape pressing mechanism 25 and a tape stopper mechanism 26 are arranged on the lower side of the second tape feeding mechanism 23B. The succeeding tape 16 (2) inserted from the insertion port 8d is pressed against the sprocket 24B by the tape pressing mechanism 25, whereby the succeeding tape 16 (2) engages with the sprocket 24B and the second tape feeding mechanism. The tape can be fed by 23B. The tape stopper mechanism 26 has a function of temporarily stopping the leading end portion of the succeeding tape 16 (2) newly inserted with the preceding tape 16 (1) attached by the stopper member 26a. ..

The first tape feed mechanism 23A provided on the downstream side has a function of pitch-feeding the preceding tape 16 (1) to the component suction position by the mounting head 11 at a predetermined feed pitch, and feeds the sprocket 24A to the first component suction position. It is configured to be rotationally driven by the motor E1 of. Above the first tape feeding mechanism 23A, a pressing member 27 that presses the leading tape 16 (1) from above and exposes the parts housed in the leading tape 16 (1) is mounted. The component pitch-fed to the component suction position is picked up by vacuum suction by the suction nozzle 11b of the mounting head 11 via the component take-out opening 27a formed in the pressing member 27.

Here, the functions of these sprockets 24A and 24B will be described with reference to FIG. As shown in FIG. 5A, a plurality of feed pins 24a are provided on the outer peripheral surfaces of the sprockets 24A and 24B. The carrier tape 16 is composed of a component pocket 16a for accommodating a component D to be supplied, a base tape 16c in which feed holes 16b into which feed pins 24a are fitted are formed at a predetermined pitch, and a cover tape 16d covering the component pockets 16a. There is. That is, the carrier tape 16 houses the component D and is covered with the cover tape 16d. The carrier tape 16 is tape-fed by rotating the sprockets 24A and 24B with the feed pin 24a engaged with the feed hole 16b.

FIG. 5B shows the function of the sprocket 24B in the second tape feeding mechanism 23B. As described above, the sprocket 24B is rotationally driven by the second motor E2 to continuously tape feed the succeeding tape 16 (2). In this drive system, the sprocket 24B is allowed to idle in the non-excited state in which the second motor E2 is not driven and controlled (idling mode), and the succeeding tape 16 (in an engaged state with the sprocket 24B) ( The movement of 2) is also allowed. The sprocket 24B has a built-in encoder 28 as a rotation detecting means, and when the subsequent tape 16 (2) moves in the downstream direction (arrow a), the sprocket 24B rotates in the forward direction (arrow b), and this rotation occurs. A rotation detection signal according to the state is transmitted to the feeder control unit 21.

When the rotation of the sprocket 24B in the forward direction (direction of arrow b) is detected, the feeder control unit 21 determines that a new carrier tape 16 has been inserted, and starts driving the second motor E2 for tape feeding. To do. As a result, the inserted carrier tape 16 is sent to the downstream side along the tape running path 8c (forward rotation mode). Further, according to a command from the feeder control unit 21, the second tape feeding mechanism 23B can drive the second motor E2 in the opposite direction to rotate the sprocket 24B in the opposite direction (arrow c). As a result, the carrier tape 16 that engages with the sprocket 24B is sent to the upstream side (arrow d) (reverse rotation mode).

FIG. 5C shows the function of the sprocket 24A in the first tape feeding mechanism 23A. As described above, the sprocket 24A is intermittently driven by the first motor E1 to feed the preceding tape 16 (1) at a predetermined feed pitch (arrow e). As a result, the component D housed in the component pocket 16a of the carrier tape 16 is supplied to the component suction position.

In FIG. 4, a first detection position P1 for detecting the carrier tape 16 is set on the upstream side of the first tape feeding mechanism 23A and the pressing member 27 in the tape traveling path 8c. A second detection position P2 for detecting the carrier tape 16 is similarly set on the downstream side of the second tape feeding mechanism 23B and on the upstream side of the first detection position P1. The first sensor S1 and the second sensor S2 arranged at the first detection position P1 and the second detection position P2 are the carrier tapes 16 at the first detection position P1 and the second detection position P2, respectively. Detect the presence or absence.

Further, the tape stopper mechanism 26 is provided with a third sensor S3 for detecting that the succeeding tape 16 (2) is in contact with the stopper member 26a. The detection results of the first sensor S1, the second sensor S2, and the third sensor S3 are transmitted to the feeder control unit 21, and the feeder control unit 21 is based on these detection results and the rotation detection result of the encoder 28. The first tape feeding mechanism 23A and the second tape feeding mechanism 23B are controlled. As a result, the tape feed operation of the preceding tape 16 (1) and the succeeding tape 16 (2) in the tape feeder 8 is executed.

When the carrier tape 16 is inserted from the insertion port 8d while the tape travel path 8c of the tape feeder 8 is empty and the encoder 28 detects the insertion of the carrier tape 16, the feeder control unit 21 corrects the second motor E2. Start driving in rotation mode. As a result, the inserted carrier tape 16 is sent downstream. That is, the tape feeder 8 (parts supply means) automatically transfers the mounted carrier tape 16 (preceding tape 16 (1)) into the tape feeder 8. When the leading portion of the preceding tape 16 (1) sent downstream is detected by the first sensor S1 at the first detection position P1, the feeder control unit 21 stops driving the second motor E2. That is, the transfer of the preceding tape 16 (1) is stopped when the leading portion reaches the first detection position P1.

Further, the succeeding tape 16 (2) was inserted from the insertion port 8d with the rear end of the leading tape 16 (1) attached to the tape feeder 8 on the upstream side (insertion port 8d side) of the stopper member 26a. In this case, the leading portion of the succeeding tape 16 (2) comes into contact with the stopper member 26a. As a result, it is detected that the succeeding tape 16 (2) is prevented from entering the tape feeder 8 and that the leading portion of the succeeding tape 16 (2) is in contact with the stopper member 26a by the third sensor S3. Will be done.

In FIG. 4, an operation / display panel 29 connected to the feeder control unit 21 is arranged on the upper surface of the tape feeder 8 on the upstream side. The operation / display panel 29 is provided with an operation button for the operator to input a predetermined operation and a notification light for notifying the operator of the predetermined content. The operation / display panel 29 allows the operator to check the operating state of the tape feeder 8 and input operations for predetermined items.

Next, with reference to FIG. 6, the cover tape peeling mechanism 30 provided on the upper member 27b of the pressing member 27 will be described. The cover tape peeling mechanism 30 has a function of peeling the cover tape 16d from the base tape 16c of the carrier tape 16 to expose the component D in the component pocket 16a. The cover tape peeling mechanism 30 is interposed on the bonding surface between the base tape 16c and the cover tape 16d, so that the cover tape 16d is provided on one side of the component pocket 16a (on the right side when facing the downstream side in FIG. 6). Peel off from.

In FIG. 6A, a thin and pointed peeling edge portion 30a (part exposing means) is provided at the tip portion on the upstream side of the cover tape peeling mechanism 30. When the head of the carrier tape 16 being transferred to the downstream side reaches the peeling edge portion 30a, the peeling edge portion 30a enters the bonding surface between the base tape 16c and the cover tape 16d, and the tape peeling is started. Further, as shown in FIGS. 6 (b) and 6 (c), as the carrier tape 16 is tape-fed to the downstream side (arrows f and g), the peeling range of the cover tape 16d expands.

The peeled cover tape 16d is formed on the left side surface of the cover tape peeling mechanism 30 along the curved surface of the side end cutting edge portion 30b, and the other side portion on the opposite side of one side portion (left side toward the downstream side in FIG. 6). ) Is bent. Then, as shown in FIG. 6D, when the carrier tape 16 is further tape-fed (arrow h) and the component D to be sucked reaches the component take-out opening 27a provided corresponding to the component suction position, the cover is covered. The tape 16d is folded back on a flat surface with respect to the base tape 16c so that the component D is exposed. In this way, the tape feeder 8 (parts supply means) supplies the part D exposed from the carrier tape 16 by the peeling edge portion 30a (parts exposure means) to the part suction position.

The cover tape peeling mechanism 30 may be a mechanism that does not require a prior preparation operation by an operator and automatically peels the cover tape 16d from the carrier tape 16 to be tape-fed to expose the component D. For example, the cover tape peeling mechanism 30 may be configured to expose the component D by incising left and right with a blade portion provided with the cover tape 16d of the carrier tape 16 to be taped.

FIG. 7 shows an outline of the component replenishment work in the tape feeder 8 of the automatic loading method. In the automatic loading type tape feeder 8, the succeeding tape 16 (2) is inserted into the insertion port 8d of the tape feeder 8 with the leading tape 16 (1) attached (arrow j). Before inserting the succeeding tape 16 (2) to be replenished into the tape feeder 8, the operator reads the bar code label L (reel ID) previously attached to the prepared supply reel 17 by the bar code reader R.

The read result is transmitted to the management computer 3 via the wireless receiving device 31 (see FIG. 9), further transmitted from the management computer 3 to the component mounting devices M2 to M4, and the collation process described later is performed. As described above, the bar code reader R serves as a reading means for reading the reel ID (identification information) attached to the supply reel 17 (reel) for accommodating the carrier tape 16.

As shown in FIG. 8, in the splicing type tape feeder 8 (not shown), when the component D is consumed and the remaining amount of the preceding tape (1) supplied to the tape feeder 8 is reduced, the component is replenished by splicing. Will be. In splicing, the trailing end of the leading tape 16 (1) is abutted against the leading end of the newly refilled trailing tape 16 (2). Next, the splicing tape for joining is attached to the front and back surfaces of the carrier tape 16 in a predetermined range sandwiching the butt portion to form the joining portion T. As a result, the preceding tape 16 (1) and the succeeding tape 16 (2) are joined, and the carrier tape 16 is continuously pitch-fed without interruption.

At the time of splicing, the operator reads the bar code label L (reel ID) previously attached to the supply reel 17 in which the succeeding tape 16 (2) is stored by the bar code reader R. After that, a collation process described later is performed based on the read reel ID.

By the way, in the component mounting line 1, an automatic loading type tape feeder 8 and a splicing type tape feeder 8 may be used in a mixed manner. Further, the spliced carrier tape 16 may be removed from the tape feeder 8 and stored in a wound and stored state on the supply reel 17. If the spliced and stored carrier tape 16 is erroneously replenished to the tape feeder 8 of the automatic loading method, the cover tape 16d is not peeled off well by the joint portion T, and the peeling edge portion 30a of the cover tape peeling mechanism 30 May be damaged.

Further, the tape feeder 8 of the automatic loading method of the present embodiment is provided with a second sensor S2 for detecting the carrier tape 16 at the second detection position P2 on the upstream side of the peeling edge portion 30a. (See Fig. 4). As shown in FIG. 8, the second sensor S2 (sensor) is a transmissive sensor including an irradiation unit Sa that irradiates the light k and a detection unit Sb that detects the irradiated light k, and the light k is a feed hole 16b. It outputs a detection signal N consisting of a state in which light is transmitted and a state in which light is blocked without transmitting. In this way, the second sensor S2 detects the light-shielded state of the carrier tape 16.

The second sensor S2 detects the presence or absence of the carrier tape 16 depending on the presence or absence of a light-shielding state, and also performs a joint detection process on the output detection signal N by a joint detection unit 21a described later to perform a joint detection process. It is also possible to detect T. That is, the tape feeder 8 (parts supply means) has a joint portion T of the carrier tape 16 in the middle of the tape travel path 8c, which is a transfer path of the carrier tape 16, at a position in front of the peeling edge portion 30a (parts exposure means). It will have a second sensor (sensor) to detect. The second sensor S2 for detecting the joint portion T is appropriately changed according to the type of splicing tape forming the joint portion T. For example, when the splicing tape contains a metal thin film, a metal detection sensor may be used as the second sensor S2.

Next, with reference to FIG. 9, the configuration of the control system of the component supply system that restricts the transfer of the carrier tape 16 when the component mounting line 1 and the carrier tape 16 have a joint portion T will be described. FIG. 9A shows the overall configuration of the component supply system, and FIG. 9B shows the configuration of a plurality of tape feeders 8 mounted on the component supply units 7 of the component mounting devices M2 to M4.

In FIG. 9A, the management computer 3 is connected to the component mounting devices M2 to M4 by the communication network 2. The management computer 3 includes a wireless receiving device 31 that receives a signal from a mobile terminal such as a bar code reader R. The storage unit 3a included in the management computer 3 stores various data such as production data used for component mounting work in the component mounting devices M2 to M4. In the component mounting work by the component mounting devices M2 to M4, the production data is downloaded from the management computer 3 and stored in the device storage unit 32, and the operation information of the component mounting devices M2 to M4 is collected by the management computer 3. The barcode reader R may be connected to each of the component mounting devices M2 to M4 by wire.

The device control unit 22 included in the component mounting devices M2 to M4 is an arithmetic processing device having a CPU function, and by executing a processing program stored in the device storage unit 32, the component mounting mechanism 12 and the component supply unit 7 , Control each part of the display unit 18. Further, the device control unit 22 (control unit) controls the transfer of the carrier tape 16 in the tape feeder 8 (parts supply means). Further, the component mounting devices M2 to M4 include a feeder identification unit 33, a collation processing unit 34, and a determination unit 35, which are information processing units. In the control process by the device control unit 22, various production data such as mounting data 32a, supply reel information 32b, and component placement data 32c stored in the device storage unit 32 are referred to.

The mounting data 32a is data such as the component type of the component to be mounted and the mounting position coordinates of the board, and is stored for each board type to be produced. The supply reel information 32b is a component that identifies the reel ID (identification information) of the bar code label L attached to the supply reel 17 (reel) for winding and storing the carrier tape 16 and the component D stored in the carrier tape 16. It is the data corresponding to the ID. The component arrangement data 32c is data that defines the feeder address and feeder ID of the tape feeder 8 in the component supply unit 7, and the reel ID of the supply reel 17 that stores the carrier tape 16 in the supply state in the tape feeder 8.

Here, the configuration of the supply reel information 32b and the component arrangement data 32c will be described. FIG. 10A shows an example of the supply reel information 32b. In the supply reel information 32b, for each reel ID 41, the component ID 42 (1) or the component ID 42 (1) that specifies the component D stored in the preceding tape 16 (1) or the succeeding tape 16 (2) wound and stored in the supply reel 17 or Two component IDs 42 of the component ID 42 (2) are stored.

In FIG. 10A, the supply reel 17 having the reel ID 41 of Raaaa, Rbbbb, and Rdddd has a carrier tape 16 wound and stored in which the component ID 42 (1) stores the component D of T1aa, T1bbb, and T1ddd, respectively. .. Further, the supply reel 17 having the reel ID 41 of Rcccc houses the preceding tape 16 (1) containing the part D having the part ID 42 (1) of T1cccc, and the part D having the part ID 42 (2) of T2cccc. The carrier tape 16 spliced to the succeeding tape 16 (2) is wound and stored.

That is, from the supply reel information 32b, the carrier tape 16 in which the supply reel 17 whose reel ID 41 is Raaaa, Rbbbb, and Rdddd is wound and stored does not have a joint portion T, and the carrier in which the reel ID 41 is wound and stored by the supply reel 17 of Rcccc. It can be seen that the tape 16 has a joint portion T. As described above, the supply reel information 32b is stored in association with the reel ID 41 (identification information) of the supply reel 17 (reel) and the presence / absence of the joint portion T of the stored carrier tape 16.

FIG. 10B shows an example of component placement data 32c. A tape feeder 8 having a feeder ID 44 of Faaaa and Fcccc is attached to a position where the feeder addresses 43 are f1 and f3, and a carrier tape 16 housed in a supply reel 17 of Raaa and Rcccc is supplied with a reel ID 41 (1). .. Further, a tape feeder 8 having a feeder ID 44 of Fbbbb is mounted at a position where the feeder address 43 is f2, and a carrier tape 16 having a reel ID 41 (1) stored in a supply reel 17 of Rbbbb is used as a leading tape 16 (1). The carrier tape 16 in which the reel ID 41 (2) is stored in the supply reel 17 of Rdddd is supplied as the succeeding tape 16 (2).

In FIG. 9, the feeder identification unit 33 inserts the carrier tape 16 based on the operation input information of the operation / display panel 29 of the tape feeder 8 by the operator or the rotation detection result of the encoder 28 included in each tape feeder 8. The feeder address 43 in the tape feeder 8 and the component supply unit 7 is specified. The collation processing unit 34 performs collation processing for collating the reel ID 41 of the supply reel 17 read by the bar code reader R with the reel ID 41 of the supply reel information 32b.

Further, the collation processing unit 34 makes the collated reel ID 41 correspond to the tape feeder 8 specified by the feeder identification unit 33, and performs an arrangement data update process for updating the component arrangement data 32c. Specifically, when the carrier tape 16 is replenished while the tape feeder 8 is empty, the “preceding tape reel ID 41 (1)” corresponding to the specified tape feeder 8 feeder ID 44 in the component placement data 32c Is overwritten and updated with the collated reel ID 41. When the carrier tape 16 is replenished while the preceding tape 16 (1) is supplied to the tape feeder 8, the "reel ID 41 (2) of the succeeding tape" corresponding to the feeder ID 44 of the specified tape feeder 8 is provided. Is overwritten and updated with the collated reel ID 41.

Further, the collation processing unit 34 performs reel information update processing for updating the supply reel information 32b based on the reel ID 41 of the collated leading tape 16 (1) and the succeeding tape 16 (2) at the time of splicing. Specifically, in the supply reel information 32b, the "part ID 42 (2) of the succeeding tape" corresponding to the reel ID 41 of the collated succeeding tape 16 (2) is stored in the currently recorded "part ID 42 of the preceding tape (2). Overwrite and update with "1)". After that, the "part ID 42 (1) of the preceding tape" is overwritten and updated with the "part ID 42 (1) of the preceding tape" of the collated leading tape 16 (1), and the reel ID 41 of the collated leading tape 16 (1) is updated. To delete.

In FIG. 9, the determination unit 35 performs a joint determination process for determining the presence or absence of the joint portion T of the carrier tape 16 housed in the collated supply reel 17 based on the supply reel information 32b. Specifically, the reel ID 41 (identification information) read by the bar code reader R (reading means) and the supply reel information 32b (stored information) stored in the device storage unit 32 (storage unit) are used. The presence / absence of the joint portion T is determined from the presence / absence of the part ID 42 of the “preceding tape part ID 42 (1)” and the “successor tape part ID 42 (2)” corresponding to the reel ID 41. That is, the determination unit 35 is a joint determination unit that determines the presence or absence of a joint portion in which two carrier tapes 16 before and after the carrier tape 16 are joined.

Although a configuration example in which the feeder identification unit 33, the collation processing unit 34, and the determination unit 35 are used as the processing functions of the component mounting devices M2 to M4 is shown here, these processing functions are provided as the processing functions of the management computer 3. You may do so. The display unit 18 displays various screens required for executing the component mounting work by the component mounting devices M2 to M4. These display screens are notification units that visually notify the operator of a warning when it is determined in the joint determination process that the joint portion T is present. In addition to the display unit 18, the component mounting line 1 may be provided with notification means such as an indicator light or a buzzer for notifying a warning.

In FIG. 9B, the feeder control unit 21 (control unit) executes the processing program stored in the feeder storage unit 36 and controls the first tape feed mechanism 23A and the second tape feed mechanism 23B. , Controls the transfer of the carrier tape 16 in the tape feeder 8 (parts supply means). This control includes control signals from the component mounting devices M2 to M4, operation inputs from the operation / display panel 29, an encoder 28 built in the sprocket 24B, a first sensor S1, a second sensor S2, and a third sensor. It is performed based on the signal from S3. The feeder control unit 21 includes a joint detection unit 21a as an internal processing function. The splicing detection unit 21a processes the detection signal N detected by the second sensor S2, and performs a splicing detection process for detecting the presence or absence of the splicing unit T by splicing.

In the joint detection process, the joint detection unit 21a calculates the light-shielding length U (see FIG. 8) in which the feed hole 16b is not continuously detected from the tape feed condition of the carrier tape 16 and the duration of the light-shielding state of the detection signal N. Obtained by. That is, the joint detection unit 21a is a calculation unit that calculates the light-shielding length U when the light-shielding state is detected by the second sensor S2 (sensor). Further, the splicing detection unit 21a determines that the splicing unit T is present when the light shielding length U exceeds the threshold length of the splicing tape. That is, the joint detection unit 21a (joint determination unit) determines the presence or absence of the joint unit T based on the detection signal N (detection information) of the second sensor S2, and when the shading length U exceeds the threshold value. It is a joint determination unit that determines that there is a joint unit T.

(First Embodiment)
Next, according to the flow of FIG. 11, a component supply process (component supply) that limits the transfer of the carrier tape 16 when there is a joint portion T by the component mounting line 1 (component supply system) of the first embodiment. Method) will be described. In the present embodiment, the presence / absence of the joint portion T is determined based on the reel ID 41 read by the barcode reader R. First, when the reel ID 41 of the supply reel 17 for winding and storing the carrier tape 16 to be replenished in the tape feeder 8 is read by the bar code reader R (Yes in ST1), the collation processing unit 34 stores the read reel ID 41. A collation process for collating with the reel ID 41 of the supplied reel information 32b is executed (ST2: collation process step).

Next, the determination unit 35 performs a joint determination process for determining the presence or absence of the joint portion T of the collated carrier tape 16 based on the component ID 42 corresponding to the reel ID 41 of the collated supply reel information 32b (ST3: Joint judgment process). When the determination unit 35 (joint determination unit) determines that the joint unit T is present (Yes in ST3), the device control unit 22 (control unit) notifies the display unit 18 (notification unit) of a warning (ST4: Notification process). Further, when the carrier tape 16 having the joint portion T is inserted into the tape feeder 8, the device control unit 22 sends a control signal so that the sprocket 24B is driven in the reverse rotation mode, and the tape feeder 8 sends a control signal. The carrier tape 16 is ejected (ST5). That is, the joint portion T is transferred to the visually visible position V (see FIG. 13B).

When the determination unit 35 (joint determination unit) determines that there is no joint unit T (No in ST3), the collation processing unit 34 performs an arrangement data update process for updating the component arrangement data 32c (ST6), and controls the device. The unit 22 transfers the replenished carrier tape 16 to the component suction position according to a preset control pattern (ST7).

As described above, in the present embodiment, when it is determined that the joint portion T is present, the device control unit 22 (control unit) is notified of a warning, the carrier tape 16 is discharged, or the like, and the joint portion T is a cover tape peeling mechanism. The transfer of the carrier tape 16 is restricted so that the carrier tape 16 is not transferred to the peeling edge portion 30a (parts exposing means) of the 30. As a result, it is possible to prevent an abnormality in the transfer of the carrier tape 16 such as breakage of the peeling cutting edge portion 30a due to the joint portion T of the carrier tape 16.

Even if the carrier tape 16 is inserted before the collation processing step (ST2) and automatically transferred into the tape feeder 8, the leading portion reaches the first detection position P1 on the upstream side of the peeling cutting edge portion 30a. At that point, the transfer of the carrier tape 16 is suspended. Therefore, when it is determined that there is a subsequent joining portion T, the carrier tape 16 is transferred due to damage to the peeling cutting edge portion 30a by the joining portion T by restricting the transfer beyond the first detection position P1. It is possible to prevent abnormalities in.

(Second Embodiment)
Next, referring to FIG. 13 according to the flow of FIG. 12, the transfer of the carrier tape 16 is restricted when there is a joint portion T by the component mounting line 1 (component supply system) of the second embodiment. The parts supply process (parts supply method) will be described. In the present embodiment, the presence / absence of the joint portion T is determined based on the detection signal N (detection information) of the second sensor S2. In FIG. 13A, the tape feeder 8 is a component D in which the preceding tape 16 (1) of the carrier tape 16 is pitch-fed (arrow m) and exposed by the peeling edge portion 30a of the cover tape peeling mechanism 30. It is supplied to the suction position (ST11).

In this state, each time the carrier tape 16 is pitch-fed, the joint detection unit 21a calculates the detection signal N of the second sensor S2 to obtain the light-shielding length U (ST12), and determines the presence or absence of the joint T. The joint detection process for detection is performed (ST13: joint detection step). When the splicing detection unit 21a (joint determination unit) determines that the splicing unit T is present (Yes in ST13), the feeder control unit 21 stops the pitch feed of the carrier tape 16 (ST14). Next, the feeder control unit 21 controls the second tape feeding mechanism 23B to transfer the joint portion T to the visually visible position V visible to the operator (ST15: joint portion transfer step). At this time, the operation / display panel 29 or the display units 18 of the component mounting devices M2 to M4 may indicate that the carrier tape 16 has the joint portion T to notify the operator of the warning.

The visual position V may be any position as long as the joint portion T is in front of the peeling edge portion 30a of the cover tape peeling mechanism 30 and the operator can visually confirm the joint portion T. In the example of FIG. 13B, the carrier tape 16 is transferred to the upstream side in the reverse rotation mode (arrow n), and the joint portion T is transferred to the visual position V1 on the upstream side from the insertion port 8d. In the example of FIG. 13C, the carrier tape 16 is transferred to the downstream side in the forward rotation mode (arrow p), and is transferred to the visual position V2 in front of the peeling cutting edge portion 30a at the upper part of the tape feeder 8. When it is determined in the joint detection step (ST13) that there is no joint portion T (No in ST13), the process returns to ST11 and component supply is continued.

As described above, in the present embodiment, when the joint detection unit 21a (joint determination unit) determines that the joint portion T is present, the feeder control unit 21 (control unit) has the joint portion T at the peeling edge portion 30a. The transfer of the carrier tape 16 is stopped at a position in front of (parts exposing means). As a result, it is possible to prevent an abnormality in the transfer of the carrier tape 16 such as breakage of the peeling cutting edge portion 30a due to the joint portion T of the carrier tape 16. Further, by automatically moving the joint portion T to the visual position V, the operator can easily visually confirm the presence or absence of the joint portion T without performing an additional operation.

As described above, the parts supply system and the parts supply method of the present embodiment determine the presence or absence of the joint portion T of the carrier tape 16, and if it is determined that the joint portion T is present, the transfer of the carrier tape is restricted. I try to let you. As a result, it is possible to prevent an abnormality in the transfer of the carrier tape 16 such as breakage of the peeling cutting edge portion 30a due to the joint portion T of the carrier tape 16.

The parts supply system and parts supply method of the present invention have an effect of being able to prevent an abnormality in the transfer of carrier tape in an automatic loading type tape feeder, and parts taken out from a tape feeder arranged in a parts supply unit. It is useful in the field of component mounting where the device is transferred and mounted on a board.

8 Tape feeder (parts supply means)
16 Carrier tape 16d Cover tape 17 Supply reel (reel)
18 Display unit (notification unit)
21 Feeder control unit (control unit)
21a Joint detection unit (joint determination unit, calculation unit)
22 Device control unit (control unit)
30a Peeling edge (parts exposed means)
32 Device storage unit (storage unit)
32b Supply reel information (stored information)
35 Judgment unit (joint judgment unit)
41 Reel ID (identification information)
D Parts R Bar code reader (reading means)
S2 Second sensor (sensor)
T Joint part U Shading length V Visual position (visible position)

Claims (9)

A component supply means that automatically transfers the carrier tape that stores the components and covers them with the cover tape, and supplies the components exposed from the carrier tape by the component exposure means.
A splicing determination unit for determining the presence or absence of a splicing portion in which two carrier tapes before and after the carrier tape are spliced together.
A control unit for controlling the transfer of the carrier tape in the component supply means is provided.
It said engagement when the determination section determines that the connecting portion is present, the control unit parts supply system for limiting the transfer of the carrier tape such that the engagement portion is not transferred to the parts exposed section. The parts supply system according to claim 1, wherein when the joint determination unit determines that the joint portion is present, the control unit transfers the joint portion to a visible position. The component supply means has a sensor that detects a joint portion of the carrier tape in the middle of the transfer path of the carrier tape at a position in front of the component exposure means.
The parts supply system according to claim 1 or 2, wherein the joint determination unit determines the presence or absence of the joint based on the detection information of the sensor. The sensor is a transmissive sensor that detects the light-shielding state of the carrier tape.
The component supply means further includes a calculation unit that calculates the light-shielding length when the light-shielding state is detected by the sensor.
The parts supply system according to claim 3, wherein the joint determination unit determines the presence or absence of the joint portion when the light-shielding length exceeds a threshold value. It also has a notification unit that notifies that an abnormality has occurred.
The component supply system according to any one of claims 1 to 4, wherein when the joint determination unit determines that the joint portion is present, the notification unit notifies that the carrier tape has the joint portion. In a parts supply system provided with a parts supply means for storing parts, automatically transferring a carrier tape covered with a cover tape, and supplying the parts exposed from the carrier tape by the parts exposure means.
The presence or absence of a joint portion in which two carrier tapes before and after the carrier tape are joined is determined.
If it is determined that the engagement portion is present, the component supply method of the engagement portion to limit the transport of the carrier tape so as not to be transferred to the part exposing means. The component supply method according to claim 6, wherein when it is determined that the joint portion is present, the joint portion is transferred to a visible position. The component supply means has a sensor that detects a joint portion of the carrier tape in the middle of the transfer path of the carrier tape at a position in front of the component exposure means.
The component supply method according to claim 6 or 7, wherein the presence or absence of the joint portion is determined based on the detection information of the sensor. The component supply method according to any one of claims 6 to 8, wherein when it is determined that the joint portion is present, the notification unit notifies that the carrier tape has the joint portion.

Images