JPWO2016059683A1 - Component mounter - Google Patents

Abstract

The present invention includes a plurality of feeder devices (2), a component transfer device (92), a control device (4) for controlling the component transfer device based on a predetermined mounting order of the plurality of components, and a component The component mounting machine (1) includes a remaining tape cutter device (3) that cuts the remaining tape (85) that is generated after the supply of the residual tape, and the control device performs a cutting operation of the remaining tape by the remaining tape cutter device. If the remaining tape (852) of the first feeder device that supplies the first part that is prohibited and scheduled to be reached has reached a specified length, the first part is skipped and the next part is skipped. The parts scheduled after that are collected, and the mounting order is changed so that the first part is collected after the cutting operation by the remaining tape cutter device is permitted and the remaining tape of the first feeder device is cut. According to this, when the remaining tape cutter device cannot be operated in a timely manner, it is possible to change the component mounting order and suppress a reduction in operating rate.

Description

  The present invention relates to a component mounter that mounts a plurality of components on a substrate, and more particularly to a component mounter that includes a remaining tape cutter device that cuts a remaining tape generated after a component is supplied by a feeder device.

  As equipment for producing a substrate on which a large number of components are mounted, there are a solder printer, a component mounting machine, a reflow machine, a board inspection machine, and the like. It has become common to configure a substrate production line by connecting these facilities. Among these, the component mounting machine includes a substrate transfer device, a component supply device, a component transfer device, and a control device. As a typical example of the component supply device, there is a feeder device that feeds out a tape holding a large number of components at a predetermined pitch. The feeder device has a thin shape with a small size in the width direction, and a plurality of feeder devices are mounted side by side. The remaining tape generated after the feeder device supplies the components is stored in the dust box and collected by the operator. Here, if the remaining tape is in a state of being connected for a long time, the tape may be entangled and a tape feeding failure may occur. As a countermeasure, a technique for appropriately cutting the remaining tape and managing it within a specified length has been developed. An example of the technique is disclosed in Patent Document 1.

  The tape collection method of Patent Document 1 includes a plurality of tape feeders, a blank tape (remaining tape) cutting mechanism, and a blank tape collection means, and operations until a component is taken out from the tape and mounted on a substrate (mounting group). ). In this tape collecting method, the first step for obtaining the first mounting group in which the leading end of the empty tape is expected to reach the cutting limit position, and the second mounting group executed before the first mounting group are empty in parallel. A second step of collectively cutting all of the tape by a cutting mechanism and collecting it by a collecting means. According to this, before the leading end of the empty tape reaches the cutting limit position, the empty tape can be cut and collected in a lump. As a result, the empty tape can be reliably and satisfactorily cut while suppressing the number of times the empty tape is cut.

JP 2010-118512 A

  By the way, the frequency with which a tape is fed out tends to increase with the recent high-speed operation of a component mounting machine, and the length of the remaining tape often reaches a specified length in a shorter time than before. For this reason, the remaining tape cutter device for cutting the remaining tape needs to operate frequently. Nevertheless, there are cases where the remaining tape cutter device cannot be operated in a timely manner for safety reasons. Then, the remaining tape that has reached the specified length cannot be cut by the specific feeder device, and the feeding of the tape is stopped so that the remaining tape does not exceed the specified length. As a result, parts cannot be collected from a specific feeder device, waiting time occurs, and the operation rate of the component mounting machine decreases. Regarding this problem, the technical example of Patent Document 1 does not disclose a countermeasure.

  The present invention has been made in view of the problems of the above-described background art, and when the remaining tape cutter device cannot be operated in a timely manner, a component in which a reduction in operating rate is suppressed by changing the mounting order of components. Providing a mounting machine is a problem to be solved.

  The invention of a component mounting machine according to claim 1 for solving the above-described problem is a plurality of feeder devices that sequentially feed out the components by feeding out a tape holding a plurality of components in a row, and collecting the components from the feeder device. Generated after the components are supplied to the board, the control device for controlling the component transfer device based on the scheduled mounting order of a plurality of components, and the feeder devices supplying the components A remaining tape cutter device for cutting the remaining tape to be cut, and the control device prohibits the operation of cutting the remaining tape by the remaining tape cutter device and is scheduled next. When the remaining tape of the first feeder device that supplies the first part has reached a specified length, the collection of the first part is skipped and the part scheduled for the next is collected, Previous Changing the placement order to collect the first component cutting operation by the residual tape cutter device is allowed after the remaining tape is cut the first feeder device.

  In the invention of the component mounting machine according to claim 1, the remaining tape cutting operation by the remaining tape cutter device is prohibited, and the remaining tape of the first feeder device for supplying the first scheduled first component is defined. When the length has been reached, the collection of the first part is skipped, and the parts scheduled for the next and later are collected first. Then, after the cutting operation by the remaining tape cutter device is permitted and the remaining tape of the first feeder device is cut, the first component is collected. By changing the mounting order in this way, even if the remaining tape cutter device cannot be operated in a timely manner, no waiting time is generated for collecting the first component, and the operating rate is reduced. Can be suppressed. Further, since the cutting length of the remaining tape is properly managed, there is no possibility of problems such as tape feeding failure.

It is a perspective view which shows the whole structure of the component mounting machine of embodiment. It is a perspective view which shows the structure of a feeder apparatus. It is a perspective view which shows the state which mounted the feeder apparatus in the main body of the component mounting machine. It is the block diagram which showed the structure of control of the component mounting machine of embodiment. It is the figure which showed the processing flow of the component adsorption | suction routine which a control apparatus performs. It is a figure which shows the initial state of the schematic example explaining the effect | action of the component mounting machine of embodiment. FIG. 7 is a diagram illustrating a state in which mounting of parts has progressed from the initial state of FIG. 6 in a state where cutting operation of the remaining tape is prohibited. It is a figure which shows the condition where the cutting operation of the remaining tape was permitted and performed from the situation of FIG.

  A component mounter 1 according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a perspective view illustrating an overall configuration of a component mounter 1 according to the embodiment. The component mounter 1 according to the embodiment includes a board transfer device 91, a component transfer device 92, a plurality of feeder devices 2, a remaining tape cutter device 3, an imaging device 93 and a control device 4 (not shown in FIG. 1) (see FIG. 4). ) Etc. The upper part of the component mounting machine 1 is covered with a transparent cover 99 (shown by a broken line).

  The substrate transfer device 91 is a dual lane type device having two transfer lanes 911. Each transfer lane 911 carries in the substrate K, positions it at the component mounting position, and carries out the substrate K on which the component is mounted. The component transfer device 92 has a movable mounting head 921. The mounting head 921 has one or a plurality of suction nozzles that suction and collect components using negative pressure. The component transfer device 92 drives the mounting head 921 and controls the suction pressure of the suction nozzle. As a result, the component transfer device 92 sucks and collects the component from the feeder device 2 and mounts the component on the positioned mounting point on the substrate K. The imaging device 93 captures the situation in which the suction nozzle of the component transfer device 92 is sucking a component, and acquires image data. The result of the image processing of the image data is reflected in the control of the mounting operation of the component transfer device 92.

  FIG. 2 is a perspective view showing the configuration of the feeder device 2. The right side in FIG. 1 is the front side of the feeder device 2, and the left side is the rear side of the feeder device 2. The feeder device 2 has a thin shape with a substantially rectangular side view and a small width direction dimension. The feeder device 2 includes a cassette case 21, a tape loading unit 22, a tape feeding mechanism 23, a top tape peeling mechanism 24, a bottom tape discharge path 25, a control unit 26, and the like. The cassette case 21 is formed in a thin box shape having an internal space using a transparent or opaque plastic plate or metal plate. The side plate of the cassette case 21 is openable and closable so that the tape reel 81 around which the tape 8 is wound can be exchanged.

  The tape loading unit 22 is formed near the lower rear side in the cassette case 21. A reel holding shaft 221 that rotatably holds the tape reel 81 is provided at the center of the tape loading unit 22. The tape 8 includes a top tape 82 and a bottom tape 83 that sandwich and hold a plurality of components and that can be supplied to each other by being separated from each other. The bottom tape 83 is formed with a storage window for storing components and is relatively thick. On the other hand, the top tape 82 is affixed to the bottom tape 83 so that components do not fall off from the storage window, and is made of, for example, a film and relatively thin.

  The tape feeding mechanism 23 includes a tape guide 231, a sprocket 233, a motor 234, and the like. The tape guide 231 extends from the tape loading unit 22 to the upper front side and forms a feeding path of the tape 8. The tip of the tape guide 231 is located at the front upper portion of the feeder device 2, and this position is a component supply position 232. A sprocket 233 is rotatably supported on the lower side near the front of the tape guide 231. The teeth of the sprocket 233 mesh with sprocket holes formed at a predetermined pitch on one side edge of the tape 8. The motor 234 is disposed adjacent to the sprocket 233 and drives the sprocket 233 to rotate intermittently. As a result, the sprocket 233 rotates intermittently and feeds the tape 8 to the component supply position 232 by a constant pitch.

  The top tape peeling mechanism 24 is disposed on the upper portion of the cassette case 21 and includes a tape presser 241, a top tape feeding mechanism 242, a motor 243, and the like. The tape presser 241 peels the top tape 82 from the bottom tape 83 before the component supply position 232 and guides the top tape 82 backward in a U-turn shape. The top tape feeding mechanism 242 disposed on the rear side of the tape presser 241 is rotationally driven by the motor 243 to feed the top tape 82 backward. As a result, the peeled top tape 82 becomes the remaining tape 84, and is sent to and stored in the top tape collecting portion 244 formed on the rear side near the upper portion in the cassette case 21. The remaining tape 84 of the top tape 82 is stored without being cut and is also collected when the tape reel 81 is replaced.

  On the other hand, the bottom tape 83 from which the top tape 82 has been peeled is in a state where components can be supplied from the storage window at the component supply position 232. The component transfer device 92 drives the mounting head 921 to move the suction nozzle to the component supply position 232 and picks up and picks up the component. After the parts are supplied, the bottom tape 83 becomes the remaining tape 85, further changes its direction from the front side to the lower side, and is fed out to the remaining tape discharge path 25.

  The remaining tape discharge path 25 is a path formed downward from the front side of the component supply position 232. A discharge port 251 at the lower end of the remaining tape discharge path 25 opens toward the front lower side. An air inlet (not shown) is provided near the upper portion of the remaining tape discharge path 25. The air that flows into the remaining tape discharge path 25 from the air introduction port flows downward and guides the remaining tape 85. As a result, the remaining tape discharge path 25 guides the remaining tape 85 of the bottom tape 83 downward and discharges it to the lower front side.

  The controller 26 is disposed at a substantially intermediate height near the front of the cassette case 21. The control unit 26 controls the motor 234 of the tape feeding mechanism 23 and the motor 243 of the top tape peeling mechanism 24. The control unit 26 includes a communication unit for exchanging information with the control device 4 on the main body side of the component mounter 1. Furthermore, the control unit 26 fulfills the function of a feed amount determination unit described later in cooperation with the control device 4.

  FIG. 3 is a perspective view showing a state where the feeder device 2 is mounted on the component mounting machine 1. As shown in the drawing, the component mounter 1 is integrally provided with a horizontally disposed feeder mounting table 94 and a vertically disposed feeder contact portion 95. The feeder device 2 is mounted on the feeder mounting table 94 and is mounted in contact with the feeder contact portion 95. In FIG. 3, one feeder device 2 is illustrated, and actually, a plurality of feeder devices 2 are mounted side by side as shown in FIG.

  An air outlet 951 for blowing out air is formed at a position corresponding to the air inlet near the upper portion of the remaining tape discharge path 25 of the feeder device 2 in the feeder contact portion 95. The remaining tape cutter device 3 is disposed at a position of the feeder contact portion 95 that faces the discharge port 251 of the remaining tape discharge path 25 of the feeder device 2. As a result, the remaining tape 85 of the bottom tape 83 discharged from the discharge port 251 is guided to the remaining tape cutter device 3. The tape cutting port 31 of the remaining tape cutter device 3 is formed in a slit shape extending in the lateral direction. The remaining tape cutter device 3 collectively cuts the remaining tape 95 discharged from the feeder device 2 on the feeder mounting table 94 with a common cutter.

  Below the remaining tape cutter device 3, a dust box 32 in which the remaining tape 85 to be cut is stored is provided so as to be put in and out. The tip of the remaining tape 85 before cutting that has passed through the tape cutting opening 31 of the remaining tape cutter device 3 hangs down toward the dust box 32. When many of the cut remaining tapes 85 are collected in the dust box 32, the operator appropriately pulls out the dust box 32 and collects the remaining tape 85. In addition, it can replace with the dust box 32 and can also be set as the structure which provided the conveyor apparatus which transfers the cut | disconnected residual tape 85, and implement | achieved automatic collection | recovery.

  The work for loading and unloading the feeder device 2 and the work for checking the internal state by the operator are performed with the cover 99 opened. In order to ensure the safety of the operator, a safety device 51 (shown in FIG. 4) for monitoring the open / closed state of the cover 99 is provided. The safety device 51 outputs the safety signal Ss while the cover 99 is closed, and turns off the safety signal Ss when the cover 99 is opened. A dust box switch 52 (shown in FIG. 4) for detecting the presence or absence of the dust box 32 is disposed in the vicinity of the dust box 32. The dust box switch 52 turns on the permission signal As while the dust box 32 is present, and turns off the permission signal As when the dust box 32 is pulled out.

  Next, the control configuration of the component mounter 1 according to the embodiment will be described. FIG. 4 is a block diagram illustrating a control configuration of the component mounter 1 according to the embodiment. In the illustrated control configuration, the control device 4 plays a central role and advances the component mounting operation in cooperation with each unit. The control device 4 can be configured using, for example, an electronic control device that includes a CPU and operates by software, and can further include a communication function with each unit.

  The control device 4 receives job data relating to the production of the substrate K from the host computer 49 at a higher level, and notifies the host computer 49 of data relating to the production progress status. The control device 4 controls the loading / unloading and positioning of the substrate K by the substrate transfer device 91. The control device 4 causes the component supply positions 232 to sequentially supply components in cooperation with the control units 26 of the plurality of feeder devices 2. The control device 4 controls the component transfer operation of the component transfer device 92, and specifically controls a drive mechanism that drives the mounting head 921 and the suction nozzle, and a pressure mechanism that controls the suction pressure. Furthermore, the control device 4 moves the mounting head 921 above the imaging device 93 to control the imaging operation of the imaging device 93.

  The control device 4 includes an input device 41, a display device 42, and a storage device 43. Examples of the input device 41 include a keyboard, a mouse, and a touch panel operated by an operator. Examples of the display device 42 include a liquid crystal display and a CRT that are visually recognized by an operator. Examples of the storage device 43 include a hard disk device, a RAM, and a ROM. The storage device 43 stores various programs and various data. The storage device 43 holds a schedule of the mounting order of a plurality of components to be mounted on the board K, for example, in the form of job data described above.

  Further, the control device 4 acquires the safety signal Ss of the safety device 51 and the permission signal As of the dust box switch 52, and determines whether the cutting operation of the remaining tape 85 by the remaining tape cutter device 3 is permitted or prohibited. That is, when the safety signal Ss is off, the cover is opened and the operator's safety is not ensured, so that the cutting operation by the remaining tape cutter device 3 is prohibited. Further, when the permission signal As is off, the remaining tape 85 that has been cut without the dust box 32 is scattered, so that the cutting operation by the remaining tape cutter device 3 is prohibited. That is, the control device 4 permits the cutting operation by the remaining tape cutter device 3 only when both the safety signal Ss and the permission signal As are on.

  Here, the function of the feeding amount determination means realized by cooperation between the control device 4 and the control unit 26 of each feeder device 2 will be described. The control unit 26 determines whether or not the remaining tape 85 has reached the specified length L0 based on the amount of feeding of the tape 8 after being cut by the remaining tape cutter device 3. The specified length L0 is the allowable maximum length of the length L of the portion of the remaining tape 85 that hangs down from the tape cutting opening 31. An appropriate specified length L0 is set in advance so as not to cause problems such as a feeding failure of the tape 8. If the length L of the remaining tape 85 is longer than the specified length L0, the remaining tape 85 may be entangled and the tape 8 may not be fed out.

  The control unit 26 can receive the cutting execution information Inf from the control device 4 indicating that the remaining tape cutter device 3 has been operated. Since the control unit 26 controls the rotation amount of the motor 234 of the tape feeding mechanism 23, the rotation amount of the tape 8 can be obtained by sequentially adding the rotation amount after the remaining tape cutter device 3 operates. Since the feeding amount of the tape 8 substantially coincides with the length L of the remaining tape 85, the control unit 26 can determine whether or not the remaining tape 85 has reached the specified length L0. The control unit 26 sends a cutting request signal Req to the control device 4 when the remaining tape 85 has reached the specified length L0. In addition, the control apparatus 4 and the control part 26 can also implement | achieve the function of a feed amount determination means by performing function sharing other than the above.

  When receiving the cutting request signal Req, the control device 4 can recognize that the remaining tape 85 has reached the specified length L0 in the feeder device 2 concerned. Here, if both the safety signal Ss and the permission signal As are on and the cutting operation is permitted, the control device 4 sends a cutting execution command Cut to the remaining tape cutter device 3. The remaining tape cutter device 3 that has received the cutting execution command Cut executes a cutting operation. If the cutting operation by the remaining tape cutter device 3 is prohibited, the control device 4 waits until the cutting operation is permitted and then sends a cutting execution command Cut.

  Further, the control device 4 notifies the control unit 26 of each feeder device 2 of the cutting execution information Inf to the effect that the cutting operation has been executed by the remaining tape cutter device 3. Each control unit 26 that has received the cutting execution information Inf resets the length L of the remaining tape 85 to zero. Note that the control device 4 prohibits component supply from the feeder device 2 that has sent the cutting request signal Req until the cutting operation is executed. This is because the length L of the remaining tape 85 exceeds the specified length L0 when the tape 8 is fed out for supplying components.

  When the cutting operation of the remaining tape 85 is prohibited, and the remaining tape 85 of the first feeder device 2 that supplies the first scheduled first component has reached the specified length L0, There was no change in the mounting order of the parts. For this reason, the component mounting machine 1 is in a standby state until the prohibition of the cutting operation is canceled and the remaining tape 85 that has reached the specified length L0 is cut. As a result, the operating rate of the component mounting machine 1 was reduced.

  On the other hand, in the embodiment of the present invention, this is dealt with by changing the suction order and mounting order of components. FIG. 5 is a diagram showing a processing flow of a component suction routine executed by the control device 4. In step S1 of the component suction routine, the control device 4 pays attention to the first component scheduled to be sucked to the suction nozzle next. In the next step S2, the control device 4 determines whether the cutting operation by the remaining tape cutter device 3 is prohibited or permitted.

  When the cutting operation is permitted, the control device 4 advances the execution of the component suction routine to step S7, performs control for sucking the first component, and ends the component suction routine. At this time, if the cutting request signal Req is received from any of the feeder devices 2, priority is given to the cutting operation by the remaining tape cutter device 3, and control is performed so that the first component is sucked after the cutting operation is completed. To do.

  When the cutting operation is prohibited in step S2, the control device 4 advances the execution of the component suction routine to step S3, and receives the cutting request signal Req from the first feeder device 2 that supplies the first component. Determine whether or not. When the cutting request signal Req is not received, the control device 4 determines that the first part can be picked up. And the control part 4 advances execution of components adsorption | suction routine to step S7, performs control which adsorb | sucks a 1st component, and complete | finishes a component adsorption routine. When receiving the cutting request signal Req, the control device 4 determines that the first part cannot be picked up, and advances the execution of the part picking routine to step S4.

  In step S4, the control device 4 skips the part that has been focused on up to the present time, and focuses on the next scheduled part. For example, in the first step S4, the control device 4 skips the first component and focuses on the second component scheduled next to the first component. In the next step S5, the control device 4 determines whether or not the cutting request signal Req is received from the second feeder device 2 that supplies the second component. When receiving the cutting request signal Req, the control device 4 determines that the second component cannot be picked up. Then, the execution of the component suction routine is returned to step S4, and attention is paid to the third component scheduled next to the second component. In this way, Steps S4 and S5 are repeatedly executed to obtain a feeder device 2 that has not received the cutting request signal Req, and it is scheduled to suck parts from the feeder device 2. Thereafter, the control device 4 advances the execution of the component suction routine to step S6.

  In step S <b> 6, the control device 4 determines whether or not a trouble occurs due to the change in the mounting order. That is, the control device 4 determines whether or not the component supplied from the feeder device 2 that has not received the cutting request signal Req can be mounted before the skipped component. When trouble occurs, the control device 4 returns the execution of the component suction routine to step S4. In this way, Steps S4 to S6 are repeatedly executed to search for a component that can be picked up within a range where no trouble occurs. When no trouble occurs in step S6, the control device 4 has found a part that can be picked up, and advances the execution of the part picking routine to step S7.

  In step S7, the control device 4 performs control for sucking the component found in the search, and ends the component sucking routine. After step S <b> 7, the control device 4 repeatedly executes a component suction routine to determine the order of components to be subsequently suctioned and to perform a suction operation. The number of repetitions of the component suction routine matches the number of suction nozzles at the maximum. When the series of suction operations is completed, the control device 4 proceeds to a routine for mounting components on the substrate K.

  It should be noted that there is no part that can be immediately picked up when the cutting request signal Req is received from all the feeder devices 2 at step S5, or when a trouble always occurs due to the change of the mounting order at step S6. Only at this time, the control device 4 stands by until the cutting operation is permitted. Thereafter, after the cutting operation by the remaining tape cutter device 3 is permitted and executed, the control device 4 performs control to suck the first part that is initially scheduled.

  Examples of problems that occur due to a change in the mounting order include a case of double mounting and a case of interference with mounted parts. For example, in a board on which large components are double-mounted across low-profile small components, it is necessary to mount the small components first and then mount the large components later, and this mounting order cannot be changed. Further, for example, even if there is no problem in the mounting order of the parts A and B, if the mounting order is reversed, the mounting head 921 that sucks the part A interferes with the mounted part B, causing a problem. There is a case.

  Next, the operation of the component mounter 1 according to the embodiment will be described with reference to a simple schematic example. FIG. 6 is a diagram illustrating an initial state of a schematic example for explaining the operation of the component mounter 1 according to the embodiment. In a schematic example, the 1st-5th components from the 1st to the 5th with the planned mounting | wearing order are supplied from the 1st-5th feeder apparatus 2, respectively. The number of components to be mounted on one board K is four for each of the first component and the second component, and eight for each of the third to fifth components. The first to fifth remaining tapes 851 to 855 after the components are supplied from the bottom tape 83 of each tape 8 of the first to fifth feeder devices 2, respectively.

  As shown in FIG. 6, the lengths L1 to L5 of the portions of the first to fifth remaining tapes 851 to 855 that hang down from the tape cutting opening 31 vary. That is, the length L1 of the first remaining tape 851 is zero, and the length L2 of the second remaining tape 852 has reached the specified length L0. The length L3 of the third remaining tape 853 is close to the specified length L0, the length L4 of the fourth remaining tape 854 is close to zero, and the length L5 of the fifth remaining tape 855 is zero.

  Consider a case in which the first to fifth parts are mounted in the number of the respective mounted parts from the initial state shown in FIG. However, there is no problem even if the mounting order is changed, and the cutting operation of the remaining tapes 851 to 855 by the remaining tape cutter device 3 is prohibited until a certain point. Further, the component transfer device 92 has a plurality of suction nozzles in the mounting head 921 and appropriately performs a mounting operation following the suction operation, and the description of the mounting operation is omitted hereinafter. FIG. 7 is a diagram illustrating a state in which mounting of components has progressed from the initial state of FIG. 5 in a state in which the cutting operation of the remaining tapes 851 to 855 is prohibited. FIG. 8 is a diagram showing a situation where the cutting operation of the remaining tapes 851 to 855 is permitted and executed from the situation of FIG.

  In the initial state, the length L1 of the first remaining tape 851 is zero, and the tape 8 can be fed out by the first feeder device 2 that supplies the first component in the first mounting order. Therefore, the control device 4 performs control so that the component transfer device 92 sucks the four first components. As a result, the length L1 of the first remaining tape 851 slightly increases from zero (shown in FIG. 7). Next, since the length L2 of the second remaining tape 852 reaches the specified length L0 and the cutting operation is prohibited, the second feeder device 2 for supplying the second component in the mounting order 2 is loaded with the tape 8. I can't pay it out. Therefore, the control device 4 skips the suction of the second component.

  Next, since the length L3 of the third remaining tape 853 does not reach the specified length L0, the tape 8 can be fed out by the third feeder device 2 that supplies the third component in the mounting order 3. Therefore, the control device 4 performs control so that the component transfer device 92 sucks the eight third components. However, when the five third parts are sucked, the length L3 of the third remaining tape 853 of the third feeder device 2 reaches the specified length L0 (shown in FIG. 7). For this reason, the control unit 26 of the third feeder device 2 sends a cutting request signal Req to the control device 4. Since the cutting operation is prohibited, the control device 4 skips the suction of the remaining three third parts.

  Next, since the length L4 of the fourth remaining tape 854 does not reach the specified length L0, the tape 8 can be fed out by the fourth feeder device 2 that supplies the fourth component in the mounting order No. 4. Therefore, the control device 4 performs control so that the component transfer device 92 picks up the eight fourth components. As a result, the length L4 of the fourth remaining tape 854 increases (shown in FIG. 7). Similarly, the length L5 of the fifth remaining tape 854 is zero, and the tape 8 can be fed out by the fifth feeder device 2 that supplies the fifth component in the mounting order No. 5. Therefore, the control device 4 performs control so that the component transfer device 92 sucks the eight fifth components. Thereby, the length L5 of the fifth remaining tape 855 increases from zero (shown in FIG. 7).

  At this point, the situation shown in FIG. 7 is reached. When the cutting operation is permitted, the control device 4 executes the cutting operation of the first to fifth remaining tapes 851 to 855 by the remaining tape cutter device 3. As a result, the situation shown in FIG. 8 is obtained, and the lengths L1 to L5 of the first to fifth remaining tapes 851 to 855 are all zero. Thereafter, the control device 4 controls to suck the four second parts skipped from the second feeder device 2, and then sucks the remaining three third components skipped from the third feeder device 2. To control. As a result, the actual mounting order is four first parts, five third parts, eight fourth parts, eight fifth parts, four second parts, and the remaining three third parts. It becomes the order of parts.

  When the cutting operation is permitted during the transition from the situation of FIG. 6 to the situation of FIG. 7, the control device 4 preferentially executes the cutting operation by the remaining tape cutter device 3 to obtain the situation of FIG. Transition to. In this case, the suction order of the first to fifth parts can be changed from the above description. For example, when the cutting operation is permitted when the mounting head 921 picks up the eight fourth components, the control device 4 gives priority to the cutting operation by the remaining tape cutter device 3 without proceeding to the suction of the fifth component. Run it. When the cutting operation is executed, all of the first to fifth parts can be picked up, and the control device 4 follows the initial mounting order. As a result, the actual mounting order is four first parts, five third parts, eight fourth parts, four second parts, the remaining three third parts, and eight fifth parts. It changes in the order of parts.

  The component mounter 1 according to the embodiment includes a first to fifth feeder device 2 that feeds out a tape 8 holding a plurality of components in a row and sequentially supplies the components, and collects components from the feeder device 2 and attaches them to the substrate K. The component transfer device 92, the control device 4 that controls the component transfer device 92 based on the scheduled mounting order of the first to fifth components, and the first to fifth feeder devices 2 after supplying the components. The component mounting machine 1 includes a remaining tape cutter device 3 that cuts the remaining tapes 851 to 855 of the generated bottom tape 83, and the control device 4 cuts the remaining tapes 851 to 855 by the remaining tape cutter device 3. When the operation is prohibited and the remaining tape 852 of the second feeder device 2 for supplying the next scheduled second part has reached the specified length L0, the second part is skipped and the subsequent parts are skipped. Scheduled to Taken third to fifth parts, to change the mounting order so that the second feeder device 2 of the remaining tape 852 is allowed a cutting operation by the residual tape cutter device 3 is collected second component after being cut.

  According to this, the cutting operation of the remaining tapes 851 to 855 by the remaining tape cutter device 3 is prohibited, and the remaining tape 852 of the feeder device 2 that supplies the second scheduled second component has reached the specified length L0. In this case, the collection of the second part is skipped, and the third to fifth parts scheduled after the next are collected first. Then, after the cutting operation by the remaining tape cutter device 3 is permitted and the remaining tape 852 of the second feeder device 2 is cut, the second part is collected. Similarly, the three third parts are collected once skipped and the remaining tape 853 of the third feeder device 2 is cut. By changing the mounting order in this way, even when the remaining tape cutter device 3 cannot be operated in a timely manner, no standby time is generated to collect the second part or the third part. Decrease in operating rate can be suppressed. Further, since the cutting lengths L1 to L5 of the remaining tapes 851 to 855 are appropriately managed within the range of the specified length L0, there is no possibility of problems such as feeding failure of the tape 8.

  Furthermore, in the component mounter 1 according to the embodiment, when the control device 4 skips the collection of the second component, the remaining tapes 853 to 855 do not reach the specified length L0 at that time, and the third to fifth feeders. The mounting order is changed so that parts are collected in the order in which the planned mounting order in the apparatus 2 is early. According to this, it is possible to suppress a decrease in the operation rate while reducing the planned change in the mounting order.

  Furthermore, in the component mounter 1 of the embodiment, the control device 4 changes the mounting order within a range in which all components to be mounted can be mounted on the board K without any problem. According to this, it is possible to suppress a decrease in the operation rate while preventing the adverse effects due to the change in the mounting order.

  Furthermore, in the component mounting machine 1 of the embodiment, the control device 4 determines that the remaining tapes 851 to 855 have reached the specified length L0 based on the amount of feeding of the tape 8 after being cut by the remaining tape cutter device 3. There is a feed amount determination means for determining whether or not there is. According to this, the accuracy of management of the cutting lengths L1 to L5 of the remaining tapes 851 to 855 is improved.

  Further, in the component mounter 1 of the embodiment, the tape 8 includes a top tape 82 and a bottom tape 83 that sandwich and hold a plurality of components and that can be supplied to each other by being separated from each other. The cutter device 3 cuts the remaining tape 85 generated from the bottom tape 83. According to this, the remaining tape 85 of the relatively thick bottom tape 83 can be cut and collected, and problems such as the bottom tape 83 becoming entangled can be prevented.

  In the embodiment, the remaining tape 84 generated from the relatively thin top tape 82 is stored in the top tape collecting unit 244 in the cassette case 21 without being cut, but the present invention is not limited to this. In other words, in addition to the remaining tape 85 of the bottom tape 83, the remaining tape 84 of the top tape 82 may be guided to the remaining tape cutter device 3, and both the remaining tapes 84 and 85 may be cut together. Further, instead of the feeding amount determination means that cooperates between the control device 4 and the control unit 26, a sensor that detects whether or not the remaining tape 85 has reached the specified length L0 may be provided. This sensor is disposed below the tape cutting opening 31 of the remaining tape cutter device 3 by a specified length L0. Further, in place of the safety device 51 that monitors the open / closed state of the cover 99, a proximity sensor or the like that contributes to ensuring safety by determining the approach of the worker by detecting light shielding may be used. Various other applications and modifications are possible for the present invention.

  INDUSTRIAL APPLICABILITY The present invention can be used in a component mounting machine including a remaining tape cutter device that cuts a remaining tape generated after a component is supplied by a feeder device.

1: Component mounter 2: Feeder device 21: Cassette case 22: Tape loading unit 23: Tape feeding mechanism 24: Top tape peeling mechanism 25: Bottom tape discharge path 3: Remaining tape cutter device 31: Tape cutting opening 32: Dust box 4: Control device (including feed amount judgment means)
51: Safety device 52: Dust box switch 8: Tape 82: Top tape 83: Bottom tape 84: Remaining tape on top tape 85: Remaining tape on bottom tape 91: Substrate transport device 92: Component transfer device 93: Imaging device 94: Feeder mounting table 95: Feeder contact part 99: Cover

Claims (5)

A plurality of feeder devices for feeding out the parts sequentially by feeding out a tape holding a plurality of parts in a row;
A component transfer device that collects the component from the feeder device and mounts the component on a substrate;
A control device for controlling the component transfer device based on a scheduled mounting order of a plurality of components;
A residual tape cutter device for cutting a residual tape generated after the plurality of feeder devices supply the component, and a component mounting machine comprising:
The controller is
When the operation of cutting the remaining tape by the remaining tape cutter device is prohibited, and the remaining tape of the first feeder device that supplies the first scheduled first component has reached a specified length, After the collection of the first part is skipped, the part scheduled for the next and subsequent parts is collected, and the cutting operation by the remaining tape cutter device is allowed and the remaining tape of the first feeder device is cut A component mounter that changes the mounting order so as to collect the first component.   When the controller skips the collection of the first part, the parts are collected in the order in which the scheduled mounting order is early among the feeder apparatuses in which the remaining tape has not reached the specified length at that time. The component mounting machine according to claim 1, wherein the mounting order is changed as described above.   The component mounting machine according to claim 1, wherein the control device changes the mounting order within a range in which all components to be mounted can be mounted on the board without any problem.   The control device is configured to detect whether the remaining tape has reached the specified length or the remaining tape based on a feeding amount of the tape that has been fed after being cut by the remaining tape cutter device. The component mounting machine according to any one of claims 1 to 3, further comprising a feed amount determination unit that determines whether or not a predetermined length has been reached. The tape is composed of a top tape and a bottom tape that sandwich and hold the plurality of components and are capable of supplying the components by being separated from each other.
The component mounting machine according to claim 1, wherein the remaining tape cutter device cuts a remaining tape generated from the top tape or the bottom tape.

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