JPWO2014068691A1 - Substrate working system and viscous fluid supply method - Google Patents

Abstract

In an on-board working system comprising a viscous fluid transfer device for transferring a viscous fluid onto a circuit board by a transfer pin 78, and a viscous fluid printing device for printing the viscous fluid on a circuit board by a squeegee and a mask. The viscous fluid is printed by a squeegee and a mask at a predetermined position 144 of the circuit board, and the viscous fluid is transferred by a transfer pin to a position 148 different from the predetermined position of one circuit board. Thereby, it becomes possible to transfer the viscous fluid by the transfer pin to a place where printing of the viscous fluid by the squeegee is not suitable. In addition, the viscous fluid can be transferred to a plurality of locations on the circuit board by a single transfer operation. In addition, the transfer pin can transfer a very small amount of viscous fluid to the circuit board. Thus, according to the system of the present invention, it is possible to appropriately supply the viscous fluid to the circuit board.

Description

  The present invention relates to an on-board working system capable of supplying viscous fluid onto a circuit board, and a viscous fluid supply method for supplying viscous fluid onto a circuit board.

  The supply of viscous fluid onto the circuit board, specifically, for example, the supply of solder onto the circuit board is generally performed by a solder printer. In a solder printing machine, cream solder is applied onto a circuit board with a squeegee and a mask, and the solder is printed in a relatively large area. On the other hand, solder printing using a squeegee and a mask, that is, mask printing may not be appropriate. Specifically, for example, in a circuit board having a step, mask printing on a surface with a low step is difficult, and mask printing is not appropriate. For this reason, in the following patent document, solder is supplied to a surface with a low step by a dispenser, and mask printing is performed on a surface with a high step.

  Further, the mask printing may not be appropriate for a normal circuit board as well as a circuit board having a step. Specifically, for example, in mask printing, the thickness of solder depends on the thickness of the mask. For this reason, it is difficult to change the thickness of the solder, that is, the amount of solder supplied onto the circuit board, for each portion of the circuit board, which is not suitable for mask printing. However, by supplying solder to a predetermined portion of the circuit board with a dispenser and performing mask printing on other portions, it is possible to change the amount of solder supplied for each portion of the circuit board Become.

Japanese Patent Laid-Open No. 2-143860

  According to the system described in the above-mentioned patent document, even when mask printing is not appropriate, it is possible to supply solder to a place not suitable for mask printing by using a dispenser. However, in the dispenser, the solder is supplied onto the circuit board by discharging the viscous fluid, so that the solder is supplied to only one place on the circuit board by one discharge operation. For this reason, in order to supply solder to a plurality of locations, a plurality of discharge operations are required, and it may take a relatively long time to supply the solder.

  The dispenser can discharge a viscous fluid in an amount different from the amount of solder supplied by mask printing, but there is a limit to reducing the amount of discharge. For this reason, it is difficult to discharge a very small amount of viscous fluid. Further, in order to change the discharge amount of the viscous fluid, it is necessary for the operator to replace the dispenser manually. Furthermore, when changing the type of viscous fluid, it is necessary for the operator to manually change the dispenser.

  Thus, there is still a lot of room for improvement in supplying viscous fluid to the circuit board. For this reason, by making various improvements, it becomes possible to appropriately supply the viscous fluid to the circuit board. The present invention has been made in view of such circumstances, and an object of the present invention is to provide an on-board working system and a viscous fluid supply method capable of appropriately supplying viscous fluid to a circuit board.

  In order to solve the above-mentioned problem, the substrate working system according to claim 1 of the present application is configured such that the viscous fluid is transferred by the viscous fluid transfer tool having a transfer pin for transferring the viscous fluid attached to the tip to the circuit board. A viscous fluid transfer device for transferring onto a circuit board, a viscous fluid printing device for printing a viscous fluid on a circuit board by means of a squeegee and a mask, and a control for controlling the operation of the viscous fluid transfer device and the viscous fluid printing device A viscous fluid printing unit that prints the viscous fluid at a predetermined position on one circuit board by controlling the operation of the viscous fluid printing device, and the viscous fluid transfer device. It has a viscous fluid transfer section that transfers viscous fluid to a position different from the predetermined position of the one circuit board by controlling the operation.

  Further, in the anti-substrate working system according to claim 2, the viscous fluid printed by the viscous fluid printing unit and the viscous fluid transferred by the viscous fluid transfer unit in the anti-substrate working system according to claim 1. Are viscous fluids of the same type.

  Further, in the anti-substrate working system according to claim 3, in the anti-substrate working system according to claim 1 or claim 2, the viscous fluid transfer unit is configured so that the viscous fluid printing unit prints the viscous fluid. The viscous fluid is transferred to the one circuit board.

  Further, in the anti-substrate working system according to claim 4, in the anti-substrate working system according to any one of claims 1 to 3, the viscous fluid transfer unit is configured such that the viscous fluid printing unit performs the first operation. The viscous fluid is transferred to the one circuit board so as to have a thickness different from that of the viscous fluid printed on the circuit board.

  Further, in the anti-substrate working system according to claim 5, in the anti-substrate working system according to any one of claims 1 to 4, the one circuit board is a cavity substrate. And

  Further, in the anti-substrate work system according to claim 6, in the anti-substrate work system according to claim 5, the viscous fluid transfer unit transfers the viscous fluid to the bottom surface of the recess formed in the cavity substrate. It is characterized by that.

  Further, in the anti-substrate working system according to claim 7, in the anti-substrate working system according to claim 5 or 6, the viscous fluid printing unit has a viscosity on the uppermost surface of the cavity substrate. It is characterized by printing a fluid.

  Further, in the anti-substrate work system according to claim 8, in the anti-substrate work system according to any one of claims 1 to 7, the viscous fluid transfer device can attach and detach the viscous fluid transfer tool. Holding the holding body, and a transfer tool container for receiving the plurality of viscous fluid transfer tools, and storing the viscous fluid transfer tool held by the holder and the transfer tool container. The viscous fluid transfer tool is automatically replaced.

  Further, in the anti-substrate working system according to claim 9, in the anti-substrate working system according to any one of claims 1 to 8, the viscous fluid transfer device includes a plurality of the viscous fluid transfer tools. It has the holding body to hold | maintain, It is characterized by the above-mentioned.

  Further, in the anti-substrate working system according to claim 10, in the anti-substrate working system according to any one of claims 1 to 9, the viscous fluid transfer device holds the viscous fluid transfer tool. In addition, it has a holding body that holds a component holder for holding the electronic component.

  Further, in the anti-substrate work system according to claim 11, in the anti-substrate operation system according to any one of claims 1 to 10, the viscous fluid transfer unit transfers the single circuit board. The transfer amount of the viscous fluid is changed according to the position.

  Further, in the anti-substrate work system according to claim 12, in the anti-substrate operation system according to any one of claims 1 to 11, the viscous fluid transfer unit transfers the single circuit board. The type of the viscous fluid is changed according to the position.

  The viscous fluid supply method according to claim 13 is a viscous fluid in which a viscous fluid is transferred onto a circuit board by a viscous fluid transfer tool having a transfer pin for transferring the viscous fluid attached to the tip to the circuit board. A viscous fluid supply method for supplying a viscous fluid onto a circuit board using a transfer device, and a viscous fluid printing apparatus for printing the viscous fluid on the circuit board with a squeegee and a mask, A viscous fluid printing step of printing a viscous fluid at a predetermined position of one circuit board, and a viscosity of transferring the viscous fluid to a position different from the predetermined position of the one circuit board by the viscous fluid transfer device. And a fluid transfer process.

  In the substrate working system according to claim 1 and the viscous fluid supply method according to claim 13, the viscous fluid is printed by mask printing at a predetermined position of one circuit board, and The viscous fluid is transferred to a position different from the predetermined position by the transfer pin. Thereby, it becomes possible to transfer the viscous fluid by the transfer pin to a place where printing of the viscous fluid by mask printing is not suitable. A plurality of transfer pins can be provided on the viscous fluid transfer tool. With a plurality of transfer pins, it is possible to transfer viscous fluid to a plurality of locations on the circuit board in a single transfer operation. Become. This makes it possible to shorten the supply time of the viscous fluid. Further, since the transfer pin transfers the viscous fluid attached to the tip to the circuit board, it is possible to transfer a very small amount of the viscous fluid to the circuit board. Furthermore, the viscous fluid transfer tool is usually attached to the work head, and there is also a viscous fluid transfer tool that can be attached to and detached from the work head. A mechanism for automatically exchanging the viscous fluid transfer tool mounted on the work head and the viscous fluid transfer tool not mounted on the work head has been developed. With such a mechanism, it is possible to automatically exchange viscous fluid. Thus, according to the substrate working system according to claim 1 and the viscous fluid supply method according to claim 13, it is possible to appropriately supply the viscous fluid to the circuit board.

  According to the second aspect of the present invention, the viscous fluid printed by mask printing and the viscous fluid transferred by the transfer pin are the same type of viscous fluid. That is, the same type of viscous fluid is supplied to one circuit board by two devices. Thereby, it becomes possible to supply viscous fluid according to the shape of a supply location, etc.

  According to the third aspect of the present invention, the viscous fluid is transferred by the transfer pin onto the circuit board on which the viscous fluid is printed by mask printing. That is, a viscous fluid printing apparatus for performing mask printing, specifically, for example, a viscous fluid transfer apparatus using a transfer pin is provided on the downstream side of a solder printer. In a general board-to-board working system, an electronic component mounting machine is provided on the downstream side of the solder printer. The electronic component mounting machine is usually provided with a mounting head, and a suction nozzle is mounted on the mounting head. Some recent mounting heads can be equipped with a viscous fluid transfer tool, and the electronic component mounting machine can function as a viscous fluid transfer device. In other words, according to the system of the third aspect, the system of the present invention can be easily applied to a general board-to-board working system.

  According to a fourth aspect of the present invention, the thickness of the viscous fluid printed on the circuit board by mask printing is different from the thickness of the viscous fluid transferred to the circuit board by the transfer pin. Thereby, according to the supply location of a viscous fluid, it becomes possible to change the supply amount of a viscous fluid appropriately.

  In the substrate-to-substrate working system according to the fifth aspect, the viscous fluid is supplied to the cavity substrate. This makes it possible to appropriately supply the viscous fluid to the cavity substrate.

  According to the sixth aspect of the present invention, the viscous fluid is transferred to the bottom surface of the recess formed in the cavity substrate by the transfer pin. Thereby, it becomes possible to supply viscous fluid appropriately to the location where printing of viscous fluid with a squeegee is difficult.

  According to the seventh aspect of the present invention, the viscous fluid is printed by mask printing on the uppermost surface of the cavity substrate. This makes it possible to collectively print the viscous fluid on the surface of the cavity substrate where no recess is formed.

  According to the eighth aspect of the present invention, the viscous fluid transfer tool is detachably held on the holding body. On the other hand, a container for accommodating the viscous fluid transfer tool is provided. And the viscous fluid transcription | transfer tool currently hold | maintained at the holding body and the viscous fluid transcription | transfer tool accommodated in the container are replaced | exchanged automatically. Accordingly, it is possible to easily cope with a change in the supply amount of the viscous fluid, a change in the type of the viscous fluid, and the like.

  In the substrate work system according to the ninth aspect, the plurality of viscous fluid transfer tools are held by the holding body. This makes it possible to attach multiple types of viscous fluid holders to the holder, making it easy to change the supply amount of viscous fluid, change the type of viscous fluid, etc. without attaching or removing the viscous fluid holder. It becomes possible to respond.

  In the substrate work system according to the tenth aspect, the viscous fluid transfer tool and the component holder for holding the electronic component are held by the holding body. Accordingly, the viscous fluid transfer device can perform the viscous fluid transfer operation and the electronic component mounting operation, and the number of operation devices constituting the system can be reduced.

  In the substrate work system according to the eleventh aspect, the transfer amount of the viscous fluid is changed according to the transfer position of one circuit board. The required amount of viscous fluid varies depending on the size, shape, etc. of the electronic components mounted on the circuit board. For this reason, according to the substrate work system described in claim 11, it is possible to deal with various electronic components.

  In the substrate work system according to the twelfth aspect, the type of viscous fluid is changed according to the transfer position of one circuit board. Accordingly, it is possible to cope with various operations such as a solder transfer operation and a flux transfer operation.

It is a figure which shows the electronic component mounting system which is an Example of this invention in the viewpoint from upper direction. It is a figure which shows the electronic component mounting machine with which an electronic component mounting system is provided in the viewpoint from upper direction. It is a perspective view which shows the working head with which an electronic component mounting machine is provided. It is a block diagram which shows the control apparatus which an electronic component mounting machine has, and the control apparatus which a solder printer has. It is a figure which shows the cavity board | substrate at the time of cream solder printing in a solder printer. It is a figure which shows the viscous fluid transfer tool of the state in which the front-end | tip part of the transfer pin was immersed in the cream solder in the electronic component mounting machine. It is a figure which shows the cavity board | substrate after cream solder was transcribe | transferred with the transfer pin in the electronic component mounting machine.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as modes for carrying out the present invention.

<Configuration of electronic component mounting system>
FIG. 1 shows an electronic component mounting system (hereinafter sometimes abbreviated as “mounting system”) 10 according to an embodiment of the present invention. The mounting system 10 is a system for mounting an electronic circuit component (hereinafter sometimes abbreviated as “electronic component”) on a circuit board. The mounting system 10 includes an electronic component mounting machine (hereinafter sometimes abbreviated as “mounting machine”) 12 and a solder printer 14.

  The mounting machine 12 and the solder printing machine 14 are arranged side by side, and the solder printing machine 14 is disposed on the upstream side of the mounting machine 12. In the following description, the direction in which the mounting machine 12 and the solder printer 14 are arranged is referred to as an X-axis direction, and a horizontal direction perpendicular to the direction is referred to as a Y-axis direction.

  As shown in FIG. 2, the mounting machine 12 includes a transport device 20, a work head moving device (hereinafter, may be abbreviated as “moving device”) 22, a work head 24, and a supply device 26.

  The conveyance device 20 includes a pair of conveyor belts 30 extending in the X-axis direction and an electromagnetic motor (see FIG. 4) 32 that rotates the conveyor belt 30. The circuit board 34 is supported by a pair of conveyor belts 30 and is conveyed in the X-axis direction by driving an electromagnetic motor 32. Further, the transfer device 20 includes a substrate holding device (see FIG. 4) 36. The substrate holding device 36 fixedly holds the circuit board 34 supported by the conveyor belt 30 at a predetermined position (a position where the circuit board 34 in FIG. 2 is illustrated).

  The moving device 22 includes an X-axis direction slide mechanism 50 and a Y-axis direction slide mechanism 52. The X-axis direction slide mechanism 50 has an X-axis slider 56 provided on the base 54 so as to be movable in the X-axis direction. The X-axis slider 56 is moved to an arbitrary position in the X-axis direction by driving an electromagnetic motor (see FIG. 4) 58. The Y-axis direction slide mechanism 52 has a Y-axis slider 60, and the Y-axis slider 60 is provided on the side surface of the X-axis slider 56 so as to be movable in the Y-axis direction. The Y-axis slider 60 is moved to an arbitrary position in the Y-axis direction by driving an electromagnetic motor (see FIG. 4) 62. The working head 24 is attached to the Y-axis slider 60. With such a structure, the work head 24 is moved to an arbitrary position on the base 54 by the moving device 22.

  The work head 24 performs various operations on the circuit board. As shown in FIG. 3, the work head 24 includes a plurality of shaft-like mounting units 70. At the tip of each mounting unit 70, a suction nozzle 72 or a viscous fluid transfer tool 74 is mounted. The suction nozzle 72 is connected to a positive / negative pressure supply device (see FIG. 4) 76. Accordingly, the suction nozzle 72 sucks and holds the electronic component using negative pressure, and detaches the electronic component using positive pressure. The viscous fluid transfer tool 74 has a transfer pin 78 extending downward. An operation is performed in which a viscous fluid is attached to the tip of the transfer pin 78 and the attached viscous fluid is transferred onto the circuit board.

  The suction nozzle 72 and the viscous fluid transfer tool 74 are detachable from the mounting unit 70. The structure of the engaging portion of the suction nozzle 72 to the mounting unit 70 and the structure of the engaging portion of the viscous fluid transfer tool 74 to the mounting unit 70 are common. The plurality of viscous fluid transfer tools 74 mounted on the plurality of mounting units 70 differ in the number of transfer pins 78, the arrangement pattern of the transfer pins 78, and the like.

  The plurality of mounting units 70 are held by the unit holder 80 so as to extend in the vertical direction, and the suction nozzle 72 and the viscous fluid transfer tool 74 extend downward from the lower surface of the unit holder 80. Yes. The unit holder 80 is intermittently rotated at predetermined angles by the holder rotating device 82. Then, in the work station that is one stop position of the mounting unit 70 during intermittent rotation, the mounting unit 70 is moved up and down by the unit lifting device 84. Further, the work head 24 has a unit rotation device 86, and the mounting unit 70 rotates by the unit rotation device 86.

  Further, as shown in FIG. 2, the supply device 26 is disposed on a side portion of the base 54 in the Y-axis direction. The supply device 26 has a plurality of tape feeders 88. The tape feeder 88 accommodates the taped component in a wound state. The taped component is a taped electronic component. Then, the tape feeder 88 sends out the taped parts by a feeding device (see FIG. 4) 90. Thereby, the tape feeder 88 supplies an electronic component in a supply position by sending out a taped component. The tape feeder 88 can be attached to and detached from the base 54.

  The mounting machine 12 further includes three viscous fluid trays 100, 102, 104 and two work implement stations 106, 108. The viscous fluid trays 100, 102, 104 and the work tool station 106 are provided on the opposite side of the supply device 26 so as to sandwich the transfer device 20.

  The three viscous fluid trays 100, 102, and 104 store viscous fluid in a thin film shape, and are arranged side by side in the X-axis direction. Cream solder is stored in the viscous fluid tray 100 in a thin film shape. The viscous fluid tray 102 also stores cream solder in a thin film shape, but a larger amount of cream solder than the cream solder of the viscous fluid tray 100 is stored. That is, the film thickness of the cream solder of the viscous fluid tray 102 is made larger than the film thickness of the cream solder of the viscous fluid tray 100. The viscous fluid tray 104 stores a flux in a thin film shape. The viscous fluid trays 100, 102, and 104 are configured to be detachable from the base 54, similarly to the tape feeder 88, and the viscous fluid trays 100, 102 are installed at the mounting position of the supply device 26 instead of the tape feeder 88. , 104 can be mounted.

  The two work implement stations 106 and 108 are arranged next to the viscous fluid tray 104 side by side in the X-axis direction. The work tool station 106 is for storing the suction nozzle 72. In the work tool station 106, the suction nozzle 72 mounted on the mounting unit 70 and the suction nozzle 72 stored in the work tool station 106 are provided. Can be automatically replaced. On the other hand, the work tool station 108 is for housing the viscous fluid transfer tool 74, and the viscous fluid transfer tool 74 mounted on the mounting unit 70 and the viscous fluid transfer tool stored in the work tool station 108. 74 can be automatically exchanged.

  As described above, the work tool station 106 and the work tool station 108 are separately installed, so that the suction nozzle 72 can be accommodated separately from the viscous fluid transfer tool 74 that is contaminated by the viscous fluid. The work tool station 108 incorporates a cleaning mechanism (not shown), and the tip of the transfer pin 78 of the viscous fluid transfer tool 74 housed in the work tool station 108 is cleaned by the cleaning mechanism.

  The solder printer 14 arranged upstream of the mounting machine 12 includes a transport device (see FIG. 1) 110 having the same structure as the transport device 20 of the mounting machine 12 and a printing device (see FIG. 4) 112. Yes. The printing device 112 is a device that prints cream solder on a circuit board held by the transport device 110 with a squeegee (see FIG. 5) 116. Thereby, the solder printer 14 prints the cream solder on the circuit board, and conveys the circuit board on which the cream solder is printed toward the mounting machine 12.

  Further, as shown in FIG. 4, the mounting system 10 includes a control device 120 corresponding to the mounting machine 12 and a control device 122 corresponding to the solder printer 14. The control device 120 corresponding to the mounting machine 12 includes a controller 124 and a plurality of drive circuits 126. The plurality of drive circuits 126 are connected to the electromagnetic motors 32, 58, 62, the substrate holding device 36, the positive / negative pressure supply device 76, the holding body rotating device 82, the unit lifting / lowering device 84, the unit rotation device 86, and the feeding device 90. Yes. The controller 124 includes a CPU, a ROM, a RAM, and the like, mainly a computer, and is connected to a plurality of drive circuits 126. Thereby, the operations of the transport device 20 and the moving device 22 are controlled by the controller 124.

  The control device 122 corresponding to the solder printer 14 includes a controller 130 and a plurality of drive circuits 132. The plurality of drive circuits 132 are connected to the transport device 110 and the printing device 112. The controller 130 includes a CPU, a ROM, a RAM, and the like, mainly a computer, and is connected to a plurality of drive circuits 132. Thereby, the operations of the transport device 110 and the printing device 112 are controlled by the controller 130. Note that the controller 124 of the control device 120 and the controller 130 of the control device 122 are connected, and information, commands, and the like are transmitted and received between the controller 124 and the controller 130.

<Control of mounting system>
With the above-described configuration, in the mounting system 10, the circuit board is carried into the solder printer 14 and conveyed from the solder printer 14 to the mounting machine 12. Then, the electronic components are mounted on the circuit board by sequentially performing the operations by the solder printer 14 and the mounting machine 12 on the conveyed circuit board. In the mounting system 10, electronic components can be mounted on various circuit boards, and the mounting operation of the electronic components on the cavity board will be specifically described below. The cavity substrate is a substrate having a recess formed on the surface, and electronic components are mounted on the bottom surface of the recess and the surface where the recess is not formed.

  First, in the solder printer 14, the cavity substrate is transported to the working position according to a command from the controller 130 of the control device 122, and the cavity substrate is fixedly held at that position. Then, a mask is placed on the cavity substrate, and cream solder is printed on the mask by the printing device 112.

  Specifically, as shown in FIG. 5, the mask 142 placed on the cavity substrate 140 has a flat plate shape. The mask 142 is in close contact with the upper surface 144 located on the uppermost side of the cavity substrate 140. A plurality of through holes 146 are formed at locations where the mask 142 is in close contact with the upper surface 144, corresponding to the printing locations on the upper surface 144. On the other hand, the mask 142 covers the recess 148 in a state where it does not contact the recess 148 of the cavity substrate 140, and the through hole 146 is not formed at a location covering the recess 148 of the mask 142.

  The mask 142 having the above structure is placed on the cavity substrate 140, and cream solder is printed on the mask 142 using the squeegee 116. As a result, cream solder is filled into the plurality of through holes 146, and the cream solder is printed on the upper surface 144 of the cavity substrate 140. Then, after the mask 142 is removed from the cavity substrate 140, the cavity substrate 140 on which the cream solder is printed is conveyed toward the mounting machine 12. A viscous fluid printing unit (see FIG. 4) 160 is provided in the controller 130 of the control device 122 as a functional unit for printing cream solder on the upper surface 144 of the cavity substrate 140 by the squeegee 116.

  The cavity substrate 140 carried into the mounting machine 12 is transported to a work position in accordance with a command from the controller 124 of the control device 120, and is held by the transport device 20 at the work position. Further, the controller 124 moves the work head 24 above the viscous fluid tray 100 by the moving device 22. At the work station of the work head 24, the mounting unit 70 on which the viscous fluid transfer tool 74 is mounted is positioned by intermittent rotation of the unit holder 80. Then, the mounting unit 70 located at the work station is lowered by the unit lifting device 84. As a result, the tip of the transfer pin 78 of the viscous fluid transfer tool 74 is immersed in the cream solder stored in the viscous fluid tray 100 as shown in FIG. Adhere to.

  Subsequently, the controller 124 moves the work head 24 above the recess 148 of the cavity substrate 140 by the moving device 22. Then, the mounting unit 70 is lowered by the unit lifting device 84. As a result, the tip of the transfer pin 78 comes into contact with the bottom surface of the recess 148 of the cavity substrate 140, and the cream solder adhering to the tip of the transfer pin 78 appears on the bottom surface of the recess 148 as shown in FIG. Is transcribed. A viscous fluid transfer unit (see FIG. 4) 162 is provided in the controller 124 of the control device 120 as a functional unit for transferring cream solder to the bottom surface of the recess 148 of the cavity substrate 140 by the transfer pin 78.

Incidentally, the thickness L ₁ of the cream solder 150 transferred by the transfer pin 78 is thinner than the thickness L ₂ of the cream solder 152 printed by the printing device 112. Specifically, the thickness L ₂ of the cream solder 152 printed on the upper surface 144 is a thickness corresponding to the thickness of the mask 142. On the other hand, the thickness L ₁ of the cream solder 150 transferred to the bottom surface of the recess 148 is a thickness corresponding to the film thickness of the cream solder stored in the viscous fluid tray 100. That is, the film thickness of the cream solder of the viscous fluid tray 100 is adjusted so that the thickness L ₁ of the cream solder 150 is thinner than the thickness L ₂ of the cream solder 152. The thickness L ₁ of the cream solder 150 is made thinner than the depth of the recess 148.

  When solder is supplied to the upper surface 144 of the cavity substrate 140 and the bottom surface of the recess 148 by the above processing, an electronic component is mounted on the supplied solder. Specifically, the controller 124 moves the work head 24 above the supply position of the tape feeder 88 by the moving device 22. At the work station of the work head 24, the mounting unit 70 to which the suction nozzle 72 is mounted is positioned by intermittent rotation of the unit holder 80. On the other hand, the tape feeder 88 sends the electronic component to the supply position by the feeding device 90.

  Then, the mounting unit 70 is lowered by the unit lifting device 84. At this time, negative pressure is supplied to the suction nozzle 72 by the positive / negative pressure supply device 76. Thereby, the electronic component is sucked and held by the suction nozzle 72. Subsequently, the working head 24 is moved above the solder supply position of the cavity substrate 140 by the moving device 22. Then, the mounting unit 70 is lowered by the unit lifting device 84. At this time, positive pressure is supplied to the suction nozzle 72 by the positive / negative pressure supply device 76. As a result, the electronic component is detached from the suction nozzle 72 and mounted on the solder supply position of the cavity substrate 140.

  As described above, in the mounting system 10, cream solder is collectively printed on the upper surface 144 of the cavity substrate 140 by the squeegee 116 and the mask 142. As a result, it is possible to shorten the time for supplying solder to the upper surface 144 of the cavity substrate 140. However, since the bottom surface of the recess 148 of the cavity substrate 140 is located at a position lower than the top surface 144, it is difficult to appropriately print solder on the bottom surface of the recess 148 by the squeegee 116.

  Therefore, in the mounting system 10, cream solder is transferred to the bottom surface of the recess 148 of the cavity substrate 140 by the viscous fluid transfer tool 74. Thereby, it is possible to appropriately supply the solder to the bottom surface of the recess 148 of the cavity substrate 140. The arrangement pattern of the plurality of transfer pins 78 of the viscous fluid transfer tool 74 corresponds to the arrangement pattern of the pads on the circuit board, and the cream solder can be transferred to a predetermined number of pads by one transfer. . As a result, the time for supplying solder to the bottom surface of the recess 148 can be shortened.

  In addition, a plurality of types of viscous fluid transfer tools 74 are mounted on the work head 24, and the arrangement patterns of the transfer pins 78 are different in the plurality of types of viscous fluid transfer tools 74. In other words, a plurality of types of viscous fluid transfer tools 74 are mounted on the work head 24 in accordance with a plurality of types of pad arrangement patterns. Therefore, by changing the viscous fluid transfer tool 74 of the mounting unit 70 located at the work station by the intermittent rotation of the unit holder 80, the cream solder can be transferred corresponding to the arrangement pattern of a plurality of types of pads. It becomes possible.

  More specifically, the work tool station 108 stores a plurality of viscous fluid transfer tools 74, the viscous fluid transfer tool 74 mounted on the mounting unit 70, and the viscous fluid stored in the work tool station 108. It is possible to automatically replace the transfer tool. As a result, the cream solder can be transferred in correspondence with more types of pad arrangement patterns.

  However, it is difficult to prepare a plurality of types of viscous fluid transfer tools 74 corresponding to all the pad arrangement patterns. Therefore, a viscous fluid transfer tool 74 having only one transfer pin 78 is prepared (see FIG. 3). Thereby, the transfer of cream solder by one transfer pin 78 is repeated a plurality of times, so that the cream solder can be transferred corresponding to the arrangement pattern of all pads.

  In addition, the work head 24 is equipped with not only the viscous fluid transfer tool 74 but also a suction nozzle 72. For this reason, it is possible to perform a solder transfer operation and an electronic component mounting operation in one mounting machine 12. Thereby, it is possible to reduce the number of mounting machines 12 constituting the mounting system 10.

  Further, in the mounting system 10, the transfer amount of cream solder by the transfer pin 78 can be easily changed. Specifically, the transfer amount of the cream solder is an amount corresponding to the film thickness of the cream solder stored in the viscous fluid tray. The cream solder 150 shown in FIG. 7 is obtained by transferring the cream solder of the viscous fluid tray 100 to the circuit board. On the other hand, a larger amount of cream solder than that of the viscous fluid tray 100 is stored in the viscous fluid tray 102. That is, the film thickness of the cream solder of the viscous fluid tray 102 is made larger than the film thickness of the cream solder of the viscous fluid tray 100. Therefore, when the cream solder on the viscous fluid tray 102 is transferred to the circuit board, it is possible to transfer a larger amount of cream solder to the board than the amount of cream solder 150 shown in FIG.

  In the mounting system 10, a viscous fluid tray 104 in which flux is stored is prepared. For this reason, it is also possible to transfer the flux to the circuit board using the viscous fluid transfer tool 74. That is, in the mounting system 10, it is possible to transfer a plurality of types of viscous fluid to the circuit board, and it is possible to cope with various operations.

  In the mounting system 10, the cream solder is transferred to the circuit board on which the cream solder is printed. That is, the mounting machine 12 is arranged on the downstream side of the solder printer 14, and this arrangement order is the arrangement order in a general mounting system. Therefore, it is possible to easily apply the solder supply method in the mounting system 10 to a general mounting system.

  Incidentally, in the above-described embodiment, the mounting system 10 is an example of an on-board working system. The mounting machine 12 is an example of a viscous fluid transfer device. The solder printer 14 is an example of a viscous fluid printing apparatus. The suction nozzle 72 is an example of a component holder. The viscous fluid transfer tool 74 is an example of a viscous fluid transfer tool. The transfer pin 78 is an example of a transfer pin. The unit holder 80 is an example of a holder. The work tool station 108 is an example of a transfer tool container. The squeegee 116 is an example of a squeegee. The control devices 120 and 122 are examples of control devices. The cavity substrate 140 is an example of a cavity substrate. The mask 142 is an example of a mask. The recess 148 is an example of a recess. The viscous fluid printing unit 160 is an example of a viscous fluid printing unit, and the process processed by the viscous fluid printing unit 160 is an example of a viscous fluid printing step. The viscous fluid transfer unit 162 is an example of a viscous fluid transfer unit, and the process processed by the viscous fluid transfer unit 162 is an example of a viscous fluid transfer step. The method of supplying the viscous fluid to the circuit board by the mounting system 10 is an example of a viscous fluid supply method.

  In addition, this invention is not limited to the said Example, It is possible to implement in the various aspect which gave various change and improvement based on the knowledge of those skilled in the art. Specifically, for example, in the above embodiment, the solder transfer operation by the transfer pin 78 is performed in the mounting machine 12, and the solder print operation by the squeegee 116 and the mask 142 is performed in the solder printer 14. Two operations can be performed on one working machine.

  In the above embodiment, the cavity substrate is employed as the circuit substrate to be worked. However, it is also possible to employ a substrate having only a step instead of the cavity. In this case, the height of the substrate surface may be three or more types, and the solder printing operation with the squeegee 116 and the mask 142 is performed on the uppermost substrate, and with respect to the other substrate surfaces, It is possible to transfer the solder by the transfer pin 78. Furthermore, it is also possible to employ a circuit board in which no recesses, steps or the like are formed, that is, a flat circuit board. When a flat circuit board is used, for example, a transfer operation of the solder with the transfer pin 78 is performed on a portion that requires a small amount of solder, and the solder with the squeegee 116 and the mask 142 is applied to the other portion. It is possible to perform printing operations.

  In the above-described embodiment, the mounting devices 12 and the solder printer 14 are provided with the control devices 120 and 122. However, the overall control device that controls the mounting device 12 and the solder printer 14 in an integrated manner is provided. It may be provided. When the overall control device is employed, the viscous fluid printing unit 160 and the viscous fluid transfer unit 162 are provided in the overall control device.

  10: Electronic component mounting system (to-board work system) 12: Electronic component mounting machine (viscous fluid transfer device) 14: Solder printer (viscous fluid printing device) 72: Adsorption nozzle (component holder) 74: Viscous fluid transfer device 78: transfer pin 80: unit holding body (holding body) 108: work tool station (transfer tool container) 116: squeegee 120: control device 122: control device 140: cavity substrate 142: mask 148: recess 160: viscous fluid printing 162: Viscous fluid transfer unit

Claims (13)

A viscous fluid transfer device that transfers the viscous fluid onto the circuit board by a viscous fluid transfer tool having a transfer pin for transferring the viscous fluid attached to the tip to the circuit board;
A viscous fluid printing apparatus for printing a viscous fluid on a circuit board by a squeegee and a mask;
A control device for controlling the operation of the viscous fluid transfer device and the viscous fluid printing device;
The control device is
A viscous fluid printing unit that controls the operation of the viscous fluid printing apparatus to print the viscous fluid at a predetermined position on one circuit board;
And a viscous fluid transfer unit that transfers the viscous fluid to a position different from the predetermined position of the one circuit board by controlling the operation of the viscous fluid transfer device.   2. The substrate working system according to claim 1, wherein the viscous fluid printed by the viscous fluid printing unit and the viscous fluid transferred by the viscous fluid transfer unit are the same kind of viscous fluid. The viscous fluid transfer section is
The on-board working system according to claim 1, wherein the viscous fluid is transferred to the one circuit board after the viscous fluid is printed by the viscous fluid printing unit. The viscous fluid transfer section is
The viscous fluid is transferred to the one circuit board so as to have a thickness different from the thickness of the viscous fluid printed on the one circuit board by the viscous fluid printing unit. The board | substrate work system as described in any one of Claim 3.   The on-board working system according to any one of claims 1 to 4, wherein the one circuit board is a cavity board. The viscous fluid transfer section is
6. The substrate working system according to claim 5, wherein the viscous fluid is transferred to a bottom surface of the recess formed in the cavity substrate. The viscous fluid printing section is
The on-board working system according to claim 5 or 6, wherein a viscous fluid is printed on the uppermost surface of the cavity substrate. The viscous fluid transfer device comprises:
A holder for detachably holding the viscous fluid transfer tool;
A transfer tool container for receiving a plurality of the viscous fluid transfer tools, the viscous fluid transfer tool held by the holding body, and the viscous fluid transfer stored in the transfer tool container. 8. The substrate work system according to claim 1, wherein the tool is automatically exchanged. The viscous fluid transfer device comprises:
The system for working with a substrate according to any one of claims 1 to 8, further comprising a holding body that holds the plurality of viscous fluid transfer tools. The viscous fluid transfer device comprises:
The counter substrate according to any one of claims 1 to 9, further comprising a holding body that holds the viscous fluid transfer tool and also holds a component holder for holding an electronic component. Work system. The viscous fluid transfer section is
The on-board working system according to any one of claims 1 to 10, wherein a transfer amount of the viscous fluid is changed according to a transfer position of the one circuit board. The viscous fluid transfer section is
The on-board working system according to any one of claims 1 to 11, wherein the type of viscous fluid is changed according to a transfer position of the one circuit board. A viscous fluid transfer device that transfers the viscous fluid onto the circuit board by a viscous fluid transfer tool having a transfer pin for transferring the viscous fluid attached to the tip to the circuit board;
In a viscous fluid supply method for supplying a viscous fluid on a circuit board using a viscous fluid printing apparatus that prints the viscous fluid on the circuit board using a squeegee and a mask,
A viscous fluid printing step of printing the viscous fluid on a predetermined position of one circuit board by the viscous fluid printing apparatus;
A viscous fluid transfer method comprising: transferring a viscous fluid to a position different from the predetermined position of the one circuit board by the viscous fluid transfer device.

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