JP4219140B2 - Printed circuit board manufacturing method and electrical component mounting system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a printed circuit board manufacturing method and an electrical component mounting system, and more particularly to a manufacturing method and system for a large printed circuit board.
[0002]
[Prior art]
In general, an electrical component mounting system generally includes a wiring board holding device that holds a printed wiring board in a predetermined position, a component supply device that supplies electrical components (including electronic components), and an electric power supplied by the component supply device. And a component mounting device for mounting the component on a printed wiring board held by the wiring board holding device. The component supply apparatus is configured by arranging a plurality of component feeders, for example, tape feeders, side by side on a table. Each tape feeder positions one electrical component at a component supply unit by feeding a carrier tape holding a large number of one type of electrical components at a constant pitch in the longitudinal direction. The component mounting device includes a component supply device, a printed wiring board, and a component holding head that relatively moves in a direction parallel to the surface of the printed wiring board, and a component holding tool such as a suction nozzle of the component holding head transfers electric components to a plurality of tape feeders. And are mounted at each of a plurality of mounting positions of the printed wiring board. The order in which a plurality of electrical components are mounted on the printed wiring board and the order in which the component feeders are arranged in the component supply apparatus are determined so that all the electrical components can be mounted on one printed wiring board in the shortest possible time. (See Patent Document 1). However, in the conventional electrical component mounting system, the mounting range of the electrical component is limited by the movable range of the component holding head or the movable range of the wiring board holding device, and a printed circuit board larger than that is manufactured. It was difficult to do. Therefore, when manufacturing printed circuit boards by mounting electrical components on a large printed wiring board, the electrical component mounting system is enlarged according to the size of the printed wiring board, and the component holding head or wiring board holding Enlarging the movable range of the apparatus has been performed.
[0003]
[Patent Document 1]
Japanese Patent Laid-Open No. 10-209681
[0004]
However, as the electrical component mounting system grows in size, its components increase, which not only lowers economics, such as increasing costs and increasing energy consumption due to larger drive sources, but also increases the processing accuracy of components. There are problems that it is difficult to maintain the accuracy of the system, such as aging, thermal deformation, and the like.
[0005]
[Problems to be solved by the invention, means for solving problems and effects]
  The present invention has been made with the above circumstances as a background to enable the production of a large printed circuit board without expanding the movable range of the component holding head or the wiring board holding device, According to the present invention, a mounting program creation method, a printed circuit board manufacturing method, and an electrical component mounting system according to the following aspects are provided.Etc.Is obtained. As with the claims, each aspect is divided into sections, each section is numbered, and is described in a form that cites the numbers of other sections as necessary. This is for the purpose of facilitating understanding of the present invention, and should not be construed as limiting the technical features described in the present specification and the combinations thereof to those described in the following sections. . In addition, when a plurality of items are described in one section, it is not always necessary to employ the plurality of items together. It is also possible to select and employ only some items.
[0006]
  In the following sections, (3)In each of the paragraphs (8) and (13), the following clarifications are made:4 and 5It corresponds to. Ie, (3)In each of the paragraphs (8) and (13), (i) the electrical component mounting system is provided with a wiring board transfer device, a component mounting device, and a control device, and (ii) the electrical component is mounted. The purpose is to make it possible to mount electrical components on a printed wiring board whose mounting area should be wider than the mounting area of the component mounting device.When, (iii)Mounting of electrical components to multiple partial areas is performed by a single electrical component mounting system,and (iv) A wiring board conveying device supports the printed wiring board from below by an endless belt, and a circuit board conveyor that conveys the printed wiring board by rotating the belt, and each of a plurality of partial areas of the component mounting device A wiring board conveyor control unit that stops the printed wiring board without using a stopper that contacts the printed wiring board by stopping the wiring board conveyor when moved to the mountable area;Are clarified in claims 1 and 2, respectively.4 and 5Equivalent toIs.
[0007]
(1) a design data storage step of storing the design data of the printed circuit board in the design data memory;
A partial mounting program creating step for creating a mounting program that divides a mounting region, which is a region where electrical components of a printed wiring board are to be mounted, into a plurality of partial regions, and determines a mounting order for each partial region;
An integration process for integrating the created partial mounting programs as one mounting program;
A mounting program creation method comprising:
As described in the next section, the printed wiring board mounting area is usually divided only in one direction, but can also be performed in each of two directions orthogonal to each other. In any case, for each of the plurality of partial areas, a mounting program in which the mounting order is determined so that the efficiency of component mounting work is as high as possible is created, and the mounting program for the entire printed wiring board is integrated as an integrated program. If created, it is possible to execute the mounting operation of the electrical component on one printed wiring board separately for each partial region while avoiding a decrease in mounting efficiency as much as possible. A large printed circuit board can be manufactured without expanding the movable range of the component holding head.
[0008]
(2) The printed wiring board is rectangular, and the mounting area of the printed wiring board is divided into the plurality of partial areas in a direction parallel to one side of the printed wiring board (1) The installation program creation method described in 1.
In general, the above-mentioned one side is a rectangular long side, but in special cases, such as when the dimension in the conveyance direction of the wiring board conveyance device of the component mounting device is short compared to the dimension in the direction perpendicular thereto, Division may be performed in a direction parallel to the short side.
[0009]
(3) Printed by an electrical component mounting system including a wiring board transport device that transports a printed wiring board along a straight line and a component mounting device that mounts an electrical component on the printed wiring board carried by the wiring board transport device. A method of manufacturing a circuit board, wherein a mounting region, which is a region where electrical components of the printed wiring board are to be mounted, is divided into a plurality of partial regions in the transport direction of the wiring board transport device, and mounting is performed for each of the partial regions. A storing step of storing in the program memory a whole mounting program including a plurality of partial mounting programs whose order is determined;
The wiring board transport device moves one of the partial areas of the printed wiring board to a mountable area of the component mounting apparatus, and the partial area of the plurality of partial mounting programs is moved to the moved partial area. A mounting process for mounting the electrical component on the entire printed wiring board by repeating the partial area mounting process for mounting the electrical component on the component mounting device according to the number corresponding to the number of the partial areas;
A printed circuit board manufacturing method including:
The wiring board transport device moves multiple partial areas of the printed wiring board one by one to the mountable area of the component mounting apparatus, and the component mounting apparatus performs electrical component mounting work according to the partial mounting program for each partial area. If it repeats, an electrical component can be mounted on a printed wiring board larger than the mountable area of the component mounting apparatus. A large printed wiring board can be manufactured without enlarging the mountable area of the component mounting apparatus. In addition, since the wiring board transport device originally transports the printed wiring board along a straight line, it is only necessary that the printed wiring board can be stopped at a plurality of positions along the straight line. Since the manufacturing cost hardly increases by changing the program, the object can be achieved at a low cost.
The entire mounting program is a set of a plurality of partial mounting programs. However, since the entire mounting program is a single mounting program, the program is performed except that the printed wiring board is moved by a predetermined distance each time mounting of each partial area is completed. No extra operation such as changing is required, and can be carried out in the same manner as a normal mounting program. Since the partial mounting program determines the mounting order for each partial area, if the mounting order is determined so that the mounting efficiency is as high as possible for each partial area, each partial area Thus, the mounting of the electric parts to the head can be performed efficiently, and a large printed circuit board can be manufactured while avoiding a decrease in the mounting efficiency.
[0010]
(4) The mounting region, which is a region where the electrical components of the printed wiring board are to be mounted, is divided into two partial regions, a first partial region and a second partial region,
The mounting step is
The wiring board transport apparatus moves the first partial area of the printed wiring board to the mountable area of the component mounting apparatus, and the first partial area of the plurality of partial mounting programs is moved to the first partial area. A first mounting step of mounting an electrical component on the component mounting device according to the one corresponding to
The wiring board transport device moves the second partial area to a mountable area of the component mounting apparatus, and the second partial area corresponds to the second partial area of the plurality of partial mounting programs. A second mounting step of mounting an electrical component on the component mounting device according to
The printed circuit board manufacturing method according to item (3), comprising:
When moving the first and second partial areas to the mountable area, both the partial areas may be configured so that the positions of the front ends, which are the downstream ends in the transport direction of the printed wiring board, are the same. It is also possible to make the position of the front end different in the region. For example, the front end of the first partial region coincides with the front end of the mountable region, and the position of the rear end of the second partial region coincides with the rear end of the mountable region, or vice versa. In this case, the component supply apparatus is a feeder group in which a plurality of component feeders are arranged along a straight line parallel to the wiring board conveyance direction, and supplies an electrical component for the first partial region. And the feeder group that supplies electric parts for the second partial region are at least partially different from each other and determined by associating their arrangement with the difference in position between the first partial region and the second partial region In this case, the total moving distance of the component holding head during the mounting operation can be shortened, and the mounting efficiency can be improved. Further, when both the first partial area and the second partial area are smaller than the mountable area of the component mounting apparatus, for example, the front end of the first partial area is matched with the front end of the mountable area, If the rear end is matched with the rear end of the mountable region, when mounting to the first partial region is performed, a part of the second partial region exists in the mountable region, and the second partial region is moved to. When the attachment is performed, a part of the first partial region exists in the attachment possible region. A special electronic circuit component can be mounted on each of these parts. The electronic circuit components to be mounted on the first and second partial areas are mounted at different times in principle, but when the electronic circuit components are mounted on the first partial area or the second partial area, If it is particularly desirable to allow a part of the electronic circuit component to be mounted on a part of the other partial area within the mountable area, it is recommended that the special electronic circuit component be mounted. It is good. One example is the case where electronic circuit components located on or near the dividing line between the first partial region and the second partial region are mounted, and the mounting efficiency is improved by the relationship with the mounting position of the component feeder. This may be desirable from a point of view. These also apply when there are three or more partial areas.
[0011]
(5) The printed circuit board manufacturing method according to (3) or (4), wherein the division into the partial areas is substantially equal.
When the mounting area of the printed wiring board is divided into two, it is also possible to divide the printed wiring board into an area substantially equal to the mountable area of the component mounting apparatus and the remaining area. However, it is often the case that the overall mounting efficiency is higher when divided equally.
[0012]
(6) As the component mounting device, a component holding head that holds an electrical component, and a head moving device that moves the component holding head to an arbitrary position in a plane parallel to the surface of the held printed wiring board; The printed circuit board manufacturing method according to any one of (3) to (5), wherein the component holding head includes a lifting device that lifts and lowers the component holding head to approach and separate the stopped printed wiring board.
In the electrical component mounting system, a plurality of component holding heads are swung around a swing axis, and are transported by a swivel mounting device that stops at least at a component receiving position and a component mounting position, and a wiring board transport device. A printed wiring board holding device for holding the printed wiring board, and moving the printed wiring board holding device in a plane parallel to the surface of the printed wiring board held by the wiring board holding device. A plurality of component feeders arranged side by side in the moving direction of the moving table and mounted on a moving table movable in a direction parallel to the conveying direction of the wiring board conveying device. And a component supply device for positioning each component supply section of each component feeder at a component supply position corresponding to the component receiving position. There is. The present invention can also be applied to this type of electrical component mounting system. For example, the wiring board holding device is not only capable of holding a printed wiring board but also movable (for example, functions as a part of a wiring board transport device), and a plurality of wiring board holding devices can be moved by moving the printed wiring board. This partial area is moved to a position corresponding to the mountable area. In this case, it is inevitable that the size of the wiring board holding device is increased, but it is possible to avoid the expansion of the movement range of the wiring board holding device by the wiring board moving device. The shaping can be suppressed.
However, if the present invention is applied to an electrical component mounting system of the type including the component mounting device described in this section, a part of the wiring board transport device itself can be used as a wiring board holding device, and Since there is no need to move the wiring board holding device, even if the wiring board holding device is increased in size, the entire electrical component mounting system is hardly increased in size, and the effects of the present invention can be enjoyed particularly effectively. can do.
[0013]
(7) Two or more reference marks are provided for each of the plurality of partial areas of the printed wiring board, and the position error of the printed wiring board is acquired by detecting the positions of the reference marks. The head moving device moves the component holding head to a position corrected by at least the position error, and causes the lifting device to move the component holding head up and down to perform the mounting operation (3) to (6) A printed circuit board manufacturing method according to any one of the above.
According to the printed circuit board manufacturing method described in this section, even if the positioning accuracy when moving one of the partial areas of the printed wiring board to the mountable area of the component mounting apparatus is not high, the electrical component is highly accurately controlled. Can be installed. Note that even though “provide two or more reference marks for each of the plurality of partial areas”, all the reference marks need not be dedicated to each partial area. It may contain a dual-purpose reference mark.
[0014]
(8) a component supply device for supplying electrical components;
A component mounting device for mounting an electrical component supplied from the component supply device on a printed wiring board;
The printed circuit board is transported in a transportation direction parallel to a straight line, and each of a plurality of partial areas obtained by dividing the mounting area, which is an area for mounting electrical components on the printed wiring board, into a plurality of parts is mounted on the component mounting apparatus. A wiring board transfer device for sequentially stopping at a plurality of positions located within the possible area;
A program memory for storing an entire mounting program including a plurality of partial mounting programs in which the mounting order of electrical components is determined for each of the plurality of partial areas;
Each time the printed wiring board is stopped at each of the plurality of stop positions by the wiring board transport device, the component mounting apparatus causes each of the plurality of partial areas to be in accordance with each of the plurality of partial mounting programs. A mounting control unit for mounting
Electrical component mounting system including.
This electrical component mounting system is suitable for carrying out the printed circuit board manufacturing method described in (3) above.
[0015]
(9) The electrical component mounting system according to (8), wherein the wiring board transport device includes a stopping device that stops the printed wiring board at the plurality of stopping positions.
If the wiring board transport device itself can stop the printed wiring board at a plurality of positions, it is not necessary to provide a stopping device. Can be adopted.
(10) The electrical component mounting system according to (9), wherein the stop device is provided at each of the plurality of stop positions.
Although it is possible to use the same stop device by moving it to a position corresponding to each of a plurality of stop positions, it is preferable to provide a stop device corresponding to each of a plurality of stop positions as in this section. In many cases, the manufacturing cost of the device can be reduced. In the latter case, it is desirable to provide at least a part of the stop device so that the position can be adjusted.
(11) The stop device
A stopper that stops the printed wiring board by contacting the front end of the printed wiring board in the transport direction;
An arrival confirmation sensor for confirming that the printed wiring board has arrived at a position in contact with the stopper;
The electrical component mounting system according to (9) or (10).
It is desirable to provide a deceleration position sensor that detects that the printed wiring board has arrived at a position where deceleration should be started upstream of a certain distance from the arrival confirmation sensor. It is also possible to omit the stopper device. When both the deceleration position sensor and the arrival confirmation sensor are provided, it is particularly easy to omit the stopper. For example, the current position of the printed wiring board is estimated based on the operation time of the wiring board transport device, and the deceleration is performed. It is also possible to omit both the deceleration position sensor and the stopper, for example, by starting deceleration at the time when it is estimated that the position has been reached.
[0016]
(12) A plurality of groups of supporting devices that respectively support one or more predetermined positions of the printed wiring board stopped at each of the plurality of stopping positions from below, each of the supporting devices,
A support member;
A support member moving device for moving the support member between an operation position for supporting the printed wiring board and an unsupported retreat position;
The electrical component mounting system according to any one of (8) to (11).
Although it is desirable to support the printed wiring board from below, the supportable parts are usually limited. Therefore, when the printed wiring board is stopped at a plurality of stop positions, it is often necessary to change the position of the support member. For example, it is possible to change the position of the support member literally by moving the support member holding member that holds the support member or moving the support member relative to the support member holding member. It is a device to provide a plurality of support members that can be moved between the position and the retracted position, and to move the appropriate support member to the working position according to the stop position of the printed wiring board to support the supportable part of the printed wiring board. Often costs can be reduced.
[0017]
(13) a component supply device for supplying electrical components;
A component mounting device for mounting an electrical component supplied from the component supply device on a printed wiring board;
A printed circuit board that transports the printed circuit board in a transport direction parallel to a straight line, and the printed circuit board that can stop the printed circuit board at a plurality of stop positions; and
A control device for controlling the component mounting device and the wiring board transport device;
And the control device is
When the printed wiring board is brought into and stopped by the wiring board transport device, a plurality of electrical components are mounted on the component mounting device on the stopped printed wiring board, and when the scheduled mounting is completed, the wiring board transport is performed. A first mounting mode for causing the apparatus to carry out the printed wiring board;
A printed wiring board is brought into and stopped by the wiring board transport device, and a plurality of electrical components are mounted on the component mounting device on the stopped printed wiring board, and the printed wiring board on which the scheduled mounting is finished is the wiring board. It is once moved to the transport device and stopped again, and the restarted printed wiring board is made to mount a plurality of electrical components on the component mounting device at least once, and finally the printed wiring board is placed on the wiring board transport device. A second mounting mode for unloading
An electrical component mounting system characterized in that it can be selectively set to
The electrical component mounting system of this section is set to the first mode when the printed wiring board is smaller than the mountable area of the component mounting apparatus, and is set to the second mounting mode when it is larger than the mountable area. Thereby, it is possible to efficiently perform the mounting operation on a printed wiring board smaller than the mountable area of the component mounting apparatus and on a large printed wiring board.
The features described in the items (8) to (12) are also applicable to the electrical component mounting system of this item.
DETAILED DESCRIPTION OF THE INVENTION
[0018]
An embodiment of the present invention will be described with reference to the drawings. 1 to 4 show an electronic component mounting system 10. This type of electronic component mounting system is already known, for example, in Japanese Patent No. 2824378, and will be described briefly.
In FIG. 1, 12 is a base as a system main body. On the base 12, a wiring board conveyor 16 that conveys a printed wiring board 14, which is a kind of circuit board, in the X-axis direction (left-right direction in FIG. 1), and a wiring board holding device that is a board holding device that holds the printed wiring board 14. A device 18 (see FIG. 6), a component mounting device 22 for mounting the electronic component 20 (see FIG. 4) on the printed wiring board 14, and component supply devices 24, 26 for supplying the electronic component 20 to the component mounting device 22 are provided. ing.
[0019]
The wiring board conveyor 16 has a pair of rails 34 and 36 as shown in FIG. Endless belts 38 (see FIG. 6), which are winding members, are attached to the rails 34 and 36 along the longitudinal direction, respectively, and the printed wiring board 12 is placed on these belts 38. It is conveyed by being circulated by a wiring board conveying motor 40 as a driving source. The wiring board conveying motor 40 constitutes a belt driving device 42 in cooperation with a pulley around which the belt 38 is wound. The distance between the pair of rails 34 and 36 can be adjusted according to the dimensions of the printed wiring board 12.
[0020]
In the present embodiment, the printed wiring board 14 is conveyed in a horizontal posture by the wiring board conveyor 16, stopped at a predetermined working position by the stopping devices 48 and 50 (see FIG. 5), and the working position of the base 12. Is held by a wiring board holding device 18 provided at a portion corresponding to the. In the present embodiment, the printed wiring board 14 is supported in a horizontal posture on a mounted surface 52 (see FIG. 4) which is a surface or an upper surface on which the electronic component is mounted.
[0021]
As shown in FIG. 5, the stop devices 48 and 50 are provided apart from each other in the transport direction of the wiring board conveyor 16, and stop the printed wiring board 14 at two preset stop positions. As shown in FIG. 10, a mounting area 53 is set on the mounted surface 52 of the printed wiring board 14. In the present embodiment, the mounting region 53 is set as a rectangular region excluding the margin portion that is the peripheral portion of the mounted surface 52, and the mounting region 53 is divided into two parts along the transport direction of the printed wiring board. It is equally divided into areas. These partial areas 54 and 56 will be referred to as a first partial area 54 and a second partial area 56, respectively. The two stop positions are at the downstream end of the first partial area 54 in the printed wiring board conveyance direction. A first position where a certain front end coincides with the front end of the mountable area, which is an area where the electronic component 20 can be mounted by the component mounting apparatus 22, and a second position where the rear end of the second partial area matches the rear end of the mountable area. Two positions are set. A first stop device 48, which is an upstream stop device in the printed wiring board conveyance direction, is fixed to the wiring board holding device 18 and stops the printed wiring board 14 at the first position. The second stop device 50 is provided downstream of the first stop device 48 and on the base 14 so that the position in the conveyance direction can be adjusted. The second stopping device 50 is capable of adjusting the position in the conveyance direction according to the sizes of the printed wiring board 14 and the partial areas 54 and 56.
[0022]
Since the stop devices 48 and 50 have the same configuration, the first stop device 48 will be described as a representative. The stopping device 48 includes a stopper 60 that contacts the end surface of the printed wiring board 14 and prevents the printed wiring board 14 from moving in the transport direction. The stopper 60 is positioned on the movement locus of the printed wiring board 14 by an elevating device (not shown) and comes into contact with the printed wiring board 14 conveyed from the upstream, and located below the movement locus on the printed wiring board. It is possible to move to a non-operation position that allows 14 to pass. By positioning the stopper 60 of either the first or second stop device 48 or 50 at the operating position, the printed wiring board 14 is stopped at one of the two stop positions.
[0023]
The stopping device 48 further includes a pair of non-contact sensors 62 and 64 that detect the presence or absence of the printed wiring board 14. The sensors 62 and 64 are provided on the upstream side of the stopper 60 and separated from each other in the transport direction. Of these sensors 62, 64, the one positioned upstream is a deceleration sensor 62 that detects that the printed wiring board 14 has reached a position to be decelerated upstream of the stopper 60 by a set distance. What is provided adjacent to the stopper 60 on the downstream side is an arrival confirmation sensor 64 that detects that the printed wiring board 14 has arrived at the stop position. The arrival confirmation sensor 64 and the deceleration sensor 62 are provided below the movement locus of the printed wiring board 14. In the present embodiment, the sensors 62 and 64 are of a light detection type, and although not illustrated, a projector that projects visible light toward the back surface of the printed wiring board 14 and a reflected light of the light are received. And a light receiver. Each of the sensors 62 and 64 emits light from the light projector when the printed wiring board 14 reaches the upper side, and the light reflected on the lower surface of the printed wiring board 14 enters the light receiver. Is located above.
[0024]
When the printed wiring board 14 is conveyed from the upstream by the wiring board conveyor 16 at a constant speed, and when it is first detected that the deceleration sensor 62 has reached the deceleration position, the wiring board conveyor 16 decelerates because the stop position is approaching. Get started. Next, if it is detected that the printed wiring board 14 has reached above the arrival confirmation sensor 64, it is determined that the printed wiring board 14 has arrived at the stop position, and the wiring board conveyor 16 is stopped.
[0025]
As schematically shown in FIG. 6, the wiring board holding device 18 includes a support base 70 and a plurality of support pin devices 72, and the lift base 74 is moved up and down by a lift drive device 76, thereby supporting pin devices. 72 contacts and supports the back surface of the printed wiring board 14. In this embodiment, the lifting platform driving device 76 is configured with an air cylinder 80, which is a kind of fluid pressure cylinder as a fluid pressure actuator, as a driving source, and constitutes a printed wiring board support device lifting device together with the lifting platform 74. Yes. The wiring board holding device 18 further includes an upward support surface 82 provided on the guide rails 34 and 36, and a clamp member 84 provided rotatably. The printed wiring board 14 includes the support surface 82 and the clamp member. 84 and clamped from both the upper and lower sides.
[0026]
Since the plurality of support pin devices 72 have a common configuration, one of them will be described as a representative. As shown in FIGS. 7 and 8, the support pin device 72 is detachably fixed on the support base 70. A plurality of female screw holes 90 are formed at equal intervals on the support base 70 and a bolt hole 94 is formed through the fixing member 92 of the support pin device 72 so that the support pin device 72 is fixed by the bolt 96. It has become. Since the female screw hole 90 is formed in the entire support base 70, the position of the support pin device 72 can be changed according to the shape of the printed wiring board 14.
[0027]
The support pin device 72 includes a support pin 98 supported by a fixing member 92 so as to be rotatable around a horizontal rotation axis. The shaft member 100 is fixed to the fixing member 92 so as to extend in the horizontal direction. When the support pin 98 is rotated around the shaft member 100, the longitudinal direction of the support pin 98 becomes vertical, which is the tip surface. The supporting surface 102 is switched between an operating position for supporting the printed wiring board 14 from below and a non-operating position where the longitudinal direction of the support pins 98 is horizontal and does not interfere with the printed wiring board 14. In the present embodiment, if the support pin device 72 is in an inoperative state, that is, if the support pin 98 is in a horizontal posture, not only the movement trace of the printed wiring board 14 but also the space below the movement trace. It is possible to ensure a large dimension. As a result, even if electronic components or the like are first mounted on the back surface of the printed wiring board 14, it is reliably avoided that the electronic components and the support pin device 72 come into contact with each other. Each of the plurality of support pin devices 72 includes a first support pin device 72a that is positioned at the operating position when the printed wiring board 14 is positioned at the first stop position, and the printed wiring board 14 is positioned at the second stop position. In this case, the second support pin device 72b is positioned at the operating position. Each of the support pin devices 72 is activated only when the printed wiring board 14 is positioned at either the first or second stop position, and is otherwise deactivated.
[0028]
The support pin 98 is connected to and driven by the air cylinder 110 serving as a drive source at the lower end opposite to the support surface 102 that supports the printed wiring board 14. In the vicinity of the lower end portion, a pair of engagement pieces 112 are formed so as to protrude in a direction perpendicular to the longitudinal direction of the support pin 110, and are connected to the air cylinder 110 there. The air cylinder 110 is horizontally provided on the support base 70 of the wiring board holding device 18, and a piston 116 is slidably fitted in the cylinder 114. A piston rod 118 extends from the piston 116 in the axial direction, protrudes from the cylinder 114, and is engaged with an engagement piece 112 of the support pin 98 at an end opposite to the piston 116.
[0029]
An engaging portion 120 that engages with the engaging piece 112 is integrally provided at a tip portion that is an end portion of the piston rod 118 that protrudes from the cylinder 114. The engaging portion 120 extends perpendicularly to the axial direction of the piston rod 118, is formed in a plate shape that is longer than the diameter of the piston rod 118 and thinner than the diameter of the piston rod 118, and penetrates it in the thickness direction. A long hole 122 extending in the direction is formed. The engaging portion 120 is sandwiched between the pair of engaging pieces 112 with almost no gap. An engaging pin 124 that extends in the horizontal direction passes through the pair of engaging pieces 112 so as not to be relatively movable, and the engaging pin 124 is slidably engaged with the elongated hole 122. As a result, the axial movement of the piston rod 118 is converted into the rotational movement of the support pin 98. As the support pin 98 rotates, the engagement pin 124 also moves along an arc centered on the shaft member 100, but the elongated hole 122 is formed longer than the length of the vertical component of the locus of the movement. Thus, the support pin 98 can be rotated while allowing the engagement pin 124 to move in the vertical direction. Here, a positioning convex portion 125 extending in the axial direction from the cylinder 114 is formed. The positioning convex portion 125 has a shape that does not interfere with the movement of the engaging portion 120, and is formed so as to contact the lower end when the support pin 98 is in a vertical posture. As a result, the support pin 98 is accurately positioned at the operating position, and the support surface 102 that supports the printed wiring board 14 is kept horizontal and at a constant height.
[0030]
A female screw hole 126 is formed in the opening of the cylinder 114, and the plug 128 is screwed to close the opening. A compression coil spring 130 (hereinafter simply referred to as a spring), which is a kind of spring member, is disposed between the plug 128 and the piston 116, and urges the piston 116 in a direction in which the piston rod 118 protrudes. On the other hand, in the cylinder 114, an air supply port is provided in an air chamber 132 formed on the side opposite to the spring 130 of the piston 116, so that compressed air can be supplied. An annular groove 134 is formed on the outer periphery of the piston 116, a seal member 136 is provided, and an annular groove 140 is also formed on the inner periphery of the guide portion 138 that guides the piston rod 118 with almost no gap. In addition, a seal member 142 is provided, and the air chamber 132 is kept airtight.
[0031]
When compressed air is supplied to the air chamber 132, the piston rod 118 is drawn into the cylinder 114, and the support pin 98 is rotated in the direction in which the longitudinal direction thereof is vertical, and is positioned at the operating position. . On the other hand, when the air chamber 132 communicates with the atmosphere, the piston 116 is moved in the direction in which the piston rod 118 protrudes by the biasing force of the spring 130, so that the support pin 98 is in a horizontal orientation. It is rotated and positioned at the non-operation position.
[0032]
In the present embodiment, an XY coordinate plane is set for the entire electronic component mounting system 10, and movement data and the like of a component holding head described later of the component mounting apparatus 22 are set on the XY coordinate plane. In this embodiment, as shown in FIG. 1, the XY coordinate plane is a plan view of the electronic component mounting system 10 from above, with the component supply device 26 on the upper side and the component supply device 24 on the lower side. Is a horizontal coordinate plane in which the left-right direction is the X-axis direction, the up-down direction is the Y-axis direction, and the rightward and upward directions are positive directions.
[0033]
As shown in FIGS. 1 and 2, the component supply devices 24 and 26 are provided on both sides of the wiring board conveyor 16 so as to be separated from each other in the Y-axis direction orthogonal to the X-axis direction in the XY coordinate plane. Yes. In the illustrated example, the component supply device 24 is a feeder-type component supply device, and the component supply device 26 is a tray-type component supply device.
[0034]
The feeder-type component supply device 24 includes a component supply table 164 in which a large number of component feeders 160 are arranged on a feeder support table 162 and each component supply is arranged in a straight line, specifically in a direction parallel to the X-axis direction. . Each component feeder 160 sequentially supplies the electronic components 20 to the component supply unit one by one by sending the taped electronic components held by the component holding tape (not shown).
[0035]
The tray-type component supply device 26 accommodates and supplies the electronic component 20 in the component tray 166 (see FIG. 4). One component tray 166 is supported in each of a plurality of component tray storage boxes 168 arranged in the vertical direction. Each of these component tray storage boxes 168 is supported by a support member (not shown), and is sequentially raised to a component supply position by an elevating device provided in the column 170. A component holding head to be described later is located above the component supply position. It is necessary to secure a space for taking out the electronic component 20. Therefore, the component tray storage box 168 that has finished supplying the electronic component 20 is raised by the above space in parallel with the next component tray storage box 168 being raised to the component supply position, and is retracted to the upper retreat area. Be made. In this way, the component holding head of the component mounting device 22 takes out the electronic components one by one from the component tray 166 in the component tray storage box 168 in which a space is formed above. The tray-type component supply device 26 is the same as the component supply device described in Japanese Patent Publication No. 2-57719, and detailed description thereof is omitted.
[0036]
The component mounting apparatus 22 transports the electronic component 20 by moving the component holding head 180 shown in FIG. 4 in a direction having components in the X-axis direction and the Y-axis direction orthogonal to each other, and the mounting surface of the printed wiring board 14 52 is attached. Therefore, as shown in FIG. 1, ball screws 184 as feed screws are provided in parallel to the X-axis direction on both sides of the wiring board conveyor 16 of the base 12 in the Y-axis direction, and are provided on the X-axis slide 186. In addition, each of the two nuts 188 (only one is shown in FIG. 3) is screwed, and each of these ball screws 184 is rotated by the X-axis slide drive motor 190, whereby the X-axis The slide 186 is moved to an arbitrary position in a direction parallel to the X axis. As described above, the nut 188, the ball screw 184, the X-axis slide drive motor 190, and the like constitute the X-axis slide moving device 196.
[0037]
As shown in FIG. 1, the X-axis slide 186 has a length extending from the feeder-type component supply device 24 over the wiring board conveyor 16 to the tray-type component supply device 26. On the base 12, guide rails 192 (see FIG. 3) as guide members are provided below the two ball screws 184, respectively. The X-axis slide 186 is a guide rail in the guide block 194 as a member to be tested. 192 is slidably fitted to guide the movement.
[0038]
A ball screw 200 (see FIG. 3) as a feed screw is provided on the X-axis slide 186 in parallel with the Y-axis direction, and the Y-axis slide 202 is screwed with a nut 204. When this ball screw 200 is rotated by gears 208 and 210 by a Y-axis slide drive motor 206 (see FIG. 1), the Y-axis slide 202 is guided by a pair of guide rails 212 as guide members. It can be moved to any position parallel to the direction. As described above, the nut 204, the ball screw 200, the Y-axis slide driving motor 206, and the like constitute the Y-axis slide moving device 214, and as the relative moving device together with the X-axis slide 186, the X-axis slide moving device 196, and the Y-axis slide 202. The component holding head 180 is moved to an arbitrary position in the horizontal plane by the XY moving device 216.
[0039]
As shown in FIGS. 3 and 4, the support portion 222 provided on the Y-axis slide 202 includes a component holding head 180, a head lifting / lowering device 224 that is a head axis direction moving device that moves the component holding head 180 up and down, and a component holding A rotation device 226 that rotates the head 180 about its axis is provided, and the component holding head 180 and the like constitute a component mounting unit 228. In the present embodiment, one set of component mounting units 228 is provided, but a plurality of sets may be provided. For example, the Y-axis slide 202 is provided with a plurality of component mounting units 228 arranged in a line parallel to the Y-axis direction, or the Y-axis slide 202 is provided with an intermittent rotating disk that can rotate intermittently around the rotation axis. A plurality of component holding heads 180 can be provided at equiangular intervals around the periphery of the board.
[0040]
The component mounting unit 228 of this embodiment is configured in the same manner as the component mounting unit described in Japanese Patent No. 3093339, and will be briefly described.
The support portion 222 is provided with a shaft 230 that can move in a direction parallel to the Z-axis direction and that can rotate about the axis, and a suction nozzle 234 is detachably held by a holder 232 provided at a lower end portion thereof. In the present embodiment, the shaft 230 and the holder 232 constitute the component holding head 180. The suction nozzle 234 can also be considered as a component of the component holding head.
[0041]
The head elevating device 224 uses the elevating motor 240 as a drive source, and the rotation of the elevating motor 240 is transmitted to the nut 246 by the rotation transmission device including the gears 242 and 244, and the nut 246 is rotated, whereby the nut 246 The screwed shaft 230 is raised and lowered, and the component holding head 180 is raised and lowered. The head lifting device 224 constitutes an approach / separation device. The rotation device 226 uses a rotation motor 250 (see FIG. 11) as a drive source, and the rotation is transmitted to the shaft 230 by a rotation transmission device including the gear 252, and the shaft 230 is rotated around the axis line, and the component holding head. 180 is rotated about a vertical axis of rotation. At this time, the raising / lowering motor 240 is rotated at the same angle as the rotation motor 250, and the raising / lowering of the shaft 230 is avoided.
[0042]
The suction nozzle 234 sucks the electronic component 20 with a negative pressure and attaches it to the printed wiring board 14. Therefore, the suction nozzle 234 is connected to a negative pressure source, a positive pressure source (not shown), and the atmosphere, and the suction pipe 260 is switched to a negative pressure source and a positive pressure source by switching an electromagnetic direction switching valve device (not shown). Or alternatively, it is communicated to the atmosphere. The suction tube 260 includes a downward suction surface 262 that sucks the electronic component 20.
[0043]
The Y-axis slide 202 is also provided with a reference mark camera 270 (see FIGS. 1 and 4) that is an imaging device that images a plurality of reference marks 268 provided on the printed wiring board 14 so as not to move. In the present embodiment, the reference mark camera 270 is configured by a CCD camera that is a surface imaging device. An illumination device 272 is provided corresponding to the reference mark camera 270, and illuminates the reference mark 268 and its surroundings. In the present embodiment, a plurality of reference marks 268 are provided so that a plurality of reference marks 268 are located in an area that can be imaged by the reference mark camera 270 regardless of the position at which the printed wiring board 14 is located. . In the illustrated example, each stop position is provided at two corners located on a diagonal line in the imaging region.
[0044]
The X-axis slide 186 is located between the feeder-type component supply device 24 and the wiring board conveyor 16 and between the tray-type component supply device 26 and the wiring board conveyor 16, and just moves the X-axis slide 186. The imaging systems 330 are attached so as not to move at positions corresponding to the two ball screws 184, respectively. These imaging systems 330 have the same configuration, and one imaging system 330 will be described as a representative.
[0045]
As shown in FIG. 3, the imaging system 330 includes a component camera 332 and a light guide device 334 as an imaging device that images the electronic component 20, and the light guide device 334 includes reflecting mirrors 336 and 338 as reflection devices. Have. The reflecting mirrors 336 and 338 are fixed to the lower part of the X-axis slide 186 by a bracket (not shown), and one reflecting mirror 336 is located at the center of the suction nozzle 234 just below the movement path of the component holding head 180 in the Y-axis direction. It has a reflecting surface 340 which is inclined about 45 degrees with respect to a vertical plane including the line and has an end portion close to the X-axis slide 186 positioned below.
[0046]
On the other hand, the other reflecting mirror 338 has a reflecting surface 342 inclined symmetrically with respect to the reflecting surface 340 and the vertical surface of the reflecting mirror 336 on the opposite side across the X-axis slide 186. A component that images the electronic component 20 held by the suction nozzle 234 at a position opposite to the side where the component holding head 180 of the X-axis slide 186 is provided and facing the reflecting surface 340 of the reflecting mirror 336. The camera 332 is held downward by the holding member 346.
[0047]
Therefore, when the component holding head 180 is moved by the XY moving device 216 and reaches a position located on the reflecting mirror 336 in the Y-axis direction, the image forming light is refracted by the reflecting mirrors 336 and 338 and is transmitted to the component camera 332. The component camera 332 can pick up an image of the electronic component 20. The imaging system 330 is disposed at a position where an image of the electronic component 20 can be captured on the movement locus of the electronic component 20 when the Y-axis slide 202 moves relative to the X-axis slide 186. In the present embodiment, the component camera 332 is a CCD camera that is a surface imaging device, like the reference mark camera 270. It is also possible to omit the reflecting mirror 338 and arrange the component camera 332 at a position facing the reflecting mirror 336 in a horizontal posture.
[0048]
Above the reflecting mirror 336, a strobe 350 as an ultraviolet irradiation device is provided so as to irradiate the light emitting plate 352 of the suction nozzle 234 with ultraviolet rays. The light emitting plate 352 absorbs ultraviolet rays and emits visible light, and the component camera 332 captures a silhouette image of the electronic component 20 from below. Further, another strobe 354 that irradiates visible light at a position far from the suction nozzle 234 as compared with the strobe 350 is provided, and is provided from the bottom surface of the electronic component 20 (the mounting surface that is mounted on the printed wiring board 14). With the reflected light, the component camera 332 captures a front image of the electronic component 20 from below. As described above, the strobe 350 and the light emitting plate 352 constitute the silhouette image acquisition illumination device 356, and the strobe 354 constitutes the front image acquisition illumination device 358. The two lighting devices 356 and 358 constitute an imaging system 330 in cooperation with the component camera 332 and the light guide device 334.
[0049]
The electronic component mounting system 10 configured as described above is controlled by the control device 300 shown in FIG. The control device 300 is mainly composed of a CPU 302, a ROM 304, a RAM 306, and a computer 310 having a bus connecting them. An input / output interface 312 is further connected to the bus. Various actuators such as an X-axis slide drive motor 190 are connected to the input / output interface 312 via a drive circuit 316. Each of these motors 190 and the like constitutes a drive source, and is constituted by an electric rotary motor which is a kind of electric motor, particularly a servo motor which is an electric rotary motor capable of controlling the rotation angle with high accuracy. A step motor may be used instead of the servo motor. In addition, the rotation angle of each motor such as the X-axis slide drive motor 190 is detected by an encoder as a rotation angle detection device, and the motor 190 and the like are controlled based on the detection result. FIG. 9 representatively shows an encoder 320 provided for the X-axis slide drive motor 190.
[0050]
The reference mark camera 270 and the component camera 332 are also connected to the input / output interface 312 via the control circuit 318. The drive circuit 316, the control circuit 318, and the computer 310 constitute a control device 300. Furthermore, the control device 300 is connected to a host computer 360 and a parts data generator (PDG) 362 serving as a database, and can acquire various programs and data stored therein. The RAM 306 includes a main program and the like, a program and data acquired from the host computer 360 and the PDG 362, a program for mounting the electronic component 38 on the printed wiring board 60, a program for detecting the rotation axis of the holding head 130, and an adsorption Various programs such as a program for detecting a position error of the suction surface 201 of the tube 200, data, and the like are stored. In addition, data acquired by executing each program is also stored in the RAM 306.
[0051]
Hereinafter, an electronic component mounting operation by the electronic component mounting system 10 will be described. Since the electronic component mounting operation itself is already known in Japanese Patent No. 2824378 and the like, it will be briefly described, and only the portion closely related to the present invention will be described in detail.
[0052]
First, a mounting program creation work for creating a mounting program for controlling the mounting work of the printed wiring board 14 will be described.
As shown in FIG. 10, the host computer 360 stores CAD data 400 including the type, orientation, and mounting position of the electronic component 20 to be mounted according to the type of the printed wiring board 14. The CAD data 400 relating to the printed wiring board 14 to be mounted by the electronic component mounting system 10 this time is selected.
[0053]
Normally, not all of the electronic components 20 to be mounted on one printed wiring board 14 are mounted by a single electronic component mounting system, but by a joint of a plurality of electronic component mounting systems. Accordingly, first, the electronic component 20 to be mounted in each electronic component mounting system is determined based on the CAD data 400. Here, for simplification, the electronic component 20 should be mounted on one printed wiring board 14. It is assumed that all the electronic components 20 are mounted by one electronic component mounting system 10. First, the size of the entire mounting area 53 of the mounting surface 52 is compared with the size of the mountable area that can be mounted by the system 10, and if the mounting area 53 is larger, it is divided into a plurality of partial areas. Dividing work is equally performed. In the present embodiment, the mounting area 53 is equally divided into two in the X-axis direction to be a first partial area 54 and a second partial area 56, and the electronic component 20 included in the CAD data 400 is based on the respective X coordinates. The first process electronic component 20a to be mounted on the first partial region 54 and the second process electronic component 20b to be mounted on the second partial region 56 are divided. Next, in each step, the mounting order is determined so that all the electronic components 20a and 20b can be mounted most efficiently. In each process, as in the conventional mounting program creation work, an optimization work for optimizing the mounting order is performed, and a first process program 402 and a second process program 404, which are partial mounting programs, are created. . Since the optimization work is not directly related to the present invention, the description thereof will be omitted. However, in the second process program 404, it is considered that the printed wiring board 14 is moved to the second position. The coordinates of the mounting position of the electronic component 20 are shifted by the amount of movement from the first position to the second position.
[0054]
The first and second process programs 402 and 404 created as described above are transmitted from the host computer 360 to the control device 300 as shown in FIG. 11, and the above-described parts data generator (PDG). From 362, component-related information including the size, shape, supply form, and the like of each electronic component 20 is transmitted to the control device 300. In the control device 300, these two process-specific mounting programs 402 and 404 are combined to create a mounting program 406 that is an entire mounting program for mounting the electronic component 20 in the entire mounting area 53. The mounting program 406 moves the printed wiring board 14 from the first position to the second position between the mounting operation of the electronic component 20 in the first mounting region 54 and the mounting operation in the second mounting region 54. Other than that, including the imaging of the reference mark 268 by the reference mark camera 270 after the movement, etc., it is the same as the conventional mounting program. By executing the mounting program 406, the electronic component mounting system 10 follows the mounting order determined for each of the first and second mounting areas 54 and 56, which are partial mounting areas, in accordance with the first and second mounting areas 54 and 56. The electronic component 20 can be mounted on the.
[0055]
The electronic component mounting operation is executed in accordance with the mounting program 406 created as described above. First, a brief description will be given. When a new printed wiring board 14 is carried into the electronic component mounting system 406, the stopper 60 of the first stop device 48 is positioned in the operating position in advance. When the printed wiring board 14 is conveyed by the wiring board conveyor 16 and reaches the vicinity of the first stop position, the printed wiring board 14 is detected by the deceleration sensor 62 and the wiring board conveyor 16 is decelerated. Thereafter, the printed wiring board 14 is stopped by coming into contact with the stopper 60, and the arrival confirmation sensor 64 confirms the arrival of the printed wiring board 14 at the first position, and the wiring board conveyor 16 is stopped. Subsequently, the support base 70 is raised, and the printed wiring board 14 is supported from below by the plurality of first support pin devices 72 a in an activated state, and is clamped by the support surface 82 and the clamp member 84. In this state, after the detection of the holding position error of the printed wiring board 14 by the wiring board holding device 18 by the imaging of the reference mark 268 by the reference mark camera 270 and the image processing of the imaging result, the first of the mounting program 406 is performed. In accordance with the part corresponding to the process program 402, the first process electronic component 20a is mounted in the first mounting area. Specifically, the mounting program is such that the imaging system 330 detects the holding position error of the electronic component 20 by the component holding head 180 and eliminates the holding position error and the holding position error of the printed wiring board 14. The electronic component 20 is mounted while the mounting position of 406 is corrected.
[0056]
In the support pin device 72 in the present embodiment, the direction of the load from the upper part of the printed wiring board 14 is orthogonal to the direction of the driving force and the air cylinder 110 as a driving source. Therefore, the driving source can be reduced in size. A load from the upper part of the printed wiring board 14 is received by the fixing member 92 via the shaft member 100.
[0057]
When the mounting operation in the first partial region 54 is completed, the holding of the printed wiring board 14 by the wiring board holding device 18 is released. The support base 70 is lowered and the stopper 60 of the first stop device 48 is positioned at the non-operating position so that the printed wiring board 14 can be conveyed by the wiring board conveyor 16 and the stopper 60 of the second stop device 50 is moved. Positioned at the operating position, preparation is made to stop the printed wiring board 14 at the second stop position. Thereafter, the printed wiring board 14 is conveyed by the wiring board conveyor 16 toward the second stop position. When the printed wiring board 14 arrives at the second stop position, the wiring board holding device 18 in which the second support pin device 72b is activated holds the printed wiring board 14. At the second stop position, the electronic component 20 is mounted in the same manner as at the first stop position.
[0058]
Hereinafter, it will be described in more detail based on the flowchart shown in FIG. This flowchart is obtained by extracting a portion deeply related to the present invention from the mounting control program, and is the same as the conventional one except for the portion shown here. In a portion of the mounting control program that is not shown, it is determined whether or not the mounting of the electronic component 20 to the predetermined number of printed wiring boards 14 has been completed. Following the instruction to carry in the printed wiring board 14 on which the electronic component 20 is to be mounted, the part represented by the flowchart of FIG. 12 is executed.
[0059]
First, in step S1 (hereinafter simply referred to as S1, the same applies to other steps), it is determined whether or not the flag F1 is zero. Initially, since the flag F1 is 0, the determination in S1 is YES, and the process proceeds to S2 where the first stop device 48 is activated. The stopper 60 of the first stopping device 48 is positioned at the operating position, and the light emitters of the deceleration sensor 62 and the arrival confirmation sensor 64 are caused to emit light so that the presence or absence of the printed wiring board 14 can be detected. . In this state, in S3, the wiring board conveyor 16 is instructed to start transporting the printed wiring board 14, and in S4, the printed wiring board 14 is awaited to reach the deceleration position. If the printed wiring board 14 is detected by the deceleration sensor 62, the determination in S4 is YES, and the process proceeds to S5 to instruct the wiring board conveyor 16 to start deceleration. In S6, the flag F1 is set to 1, and thereafter the execution of S1 to S6 is skipped.
[0060]
Next, in S7, it is determined whether or not the flag F2 is 0. Here, since the flag F2 is 0, the determination in S7 is YES, and the process proceeds to S8 to wait for the printed wiring board 14 to arrive at the first stop position. If the printed wiring board 14 is detected by the arrival confirmation sensor 64, the determination in S8 is YES, and in S9, the first support pin device among the support pin devices 72 provided on the support base 70 of the wiring board holding device 18 is determined. 72a is activated. In this state, in S10, the wiring board holding device 18 is instructed to support the printed wiring board 14, and the printed wiring board 14 is supported from below by the first support pin device 72a and clamped by the clamp member 84. The Proceeding to S11, the electronic component 20a is mounted on the first mounting region 54. Specifically, the fiducial mark 268 is imaged by the fiducial mark camera 270 to acquire a holding position error (parallel position error and rotational position error) of the printed wiring board 14, and the imaging device 330 performs electronic processing by the component holding head 180. The holding position error (parallel position error and rotational position error) of the component 20a is acquired, and the stop position (component mounting position) of the component holding head 180 is corrected based on these holding position errors, and the mounting operation is executed. If all the electronic components 20 to be mounted in the first mounting area 54 are mounted, the flag F2 is set to 1 in S12, and thereafter the execution of S7 to S12 is skipped.
[0061]
Thereafter, in S13, it is determined whether or not the flag F3 is zero. Here, since the flag F3 is 0, the determination in S13 is YES, and the process proceeds to S14 where the holding of the printed wiring board 14 by the wiring board holding device 18 is released. Clamping by the clamp member 84 is released, and the support base 70 is lowered, and in S15, the first support pin device 72a on the support base 70 is inactivated. Next, in S16 and S17, the first stop device 48 is deactivated and the second stop device 50 is activated, and in S18, the wiring board conveyor 16 is instructed to start transporting the printed wiring board 14. . In S19, it is waited for the printed wiring board 14 to reach the deceleration position, and if the deceleration sensor 62 detects the printed wiring board 14, the determination in S19 is YES, and the process proceeds to S20, where the wiring board conveyor 14 is decelerated. Instructed. In S21, the flag F3 is set to 1, and the execution of S14 to S21 is skipped in the subsequent execution of this program.
[0062]
Thereafter, the second process in which the printed wiring board 14 is stopped at the second stop position and the electronic component 20 is mounted in the second partial region 56 is substantially the same as the work in S7 to S12 in the first process described above. Therefore, explanation is omitted. If all the electronic components 20b to be mounted in the second partial region 56 are mounted, the holding of the printed wiring board 14 by the wiring board holding device 18 is released in S22, and the second stopping device 50 is in an inoperative state in S23. In step S24, an instruction to carry out the printed wiring board 14 with the electronic component 20 mounted on the wiring board conveyor 16 is instructed. In S25, all the flags are reset to 0, which is the initial value, one execution of this program is completed, and one mounting operation is completed.
[0063]
As is apparent from the above description, in the present embodiment, the first process program 402 and the second process program 404 correspond to the “partial mounting program”, and the mounting program 406 corresponds to the “whole mounting program”. It corresponds.
[0064]
According to the electronic component mounting system 10, it is possible to mount an electronic component on a printed wiring board having a mounting area larger than the size of the system mountable area. Further, by controlling the mounting operation with one mounting program 406, the downtime associated with the program change is eliminated as compared with the case where the two mounting programs 402 and 404 are executed in sequence, so that the production efficiency is reduced. Can be improved.
[0065]
In the present embodiment, the mounting area 53 is divided into two equal parts to set the two partial areas 54 and 56 to perform the mounting work. However, the mounting area 53 may be divided into any number of parts. The mounting operation may be performed by dividing into three or more partial areas. In that case, S13 to S23 in the above program are repeatedly executed while the stop device is changed to one corresponding to each partial area.
[0066]
In the present embodiment, the stop devices 48 and 50 are provided with a stopper 60 and an arrival confirmation sensor 64, and a deceleration for detecting that the printed wiring board has reached a position to start deceleration at a certain distance upstream of the arrival confirmation sensor. Although the sensor 62 is provided, the stopper 60 can be omitted. When both the deceleration position sensor 62 and the arrival confirmation sensor 64 are provided, it is easy to omit the stopper 60. For example, the current position of the printed wiring board 14 is determined based on the operation time of the wiring board conveyor 16. It is also possible to omit both the deceleration position sensor 62 and the stopper 60, for example, by starting deceleration at a time when it is estimated that the deceleration position has been reached.
[0067]
Further, for example, a stopper device including at least one of a deceleration sensor 62, an arrival confirmation sensor 64, and a stopper 60 is provided on a movable member movable in a direction parallel to the conveying direction of the wiring board conveyor 16, and this movable member. It is also possible to make the printed wiring board stop at a plurality of stop positions by the same stopper device by allowing the stopper device moving device to move it to an arbitrary position.
[0068]
As mentioned above, although some embodiment of this invention was described, these are only illustrations, and this invention is the aspect described in the above-mentioned section of [the subject which invention intends to solve, a problem-solving means, and an effect]. First, the present invention can be implemented in various modifications and improvements based on the knowledge of those skilled in the art.
[Brief description of the drawings]
FIG. 1 is a plan view showing an electronic component mounting system used for carrying out a printed circuit board manufacturing method according to an embodiment of the present invention.
FIG. 2 is a front view of the electronic component mounting system.
FIG. 3 is a side view (partial cross section) showing a component mounting apparatus of the electronic component mounting system.
FIG. 4 is a front view showing the component mounting apparatus.
FIG. 5 is a diagram illustrating a state in which a printed wiring board is held by a wiring board holding device of the electronic component mounting system.
FIG. 6 is a front view showing the wiring board holding device.
FIG. 7 is a front sectional view showing a support pin device of the wiring board holding device.
8 is a front view showing the support pin device of FIG. 7. FIG.
FIG. 9 is a block diagram showing a control device of the electronic component mounting system.
FIG. 10 is a diagram conceptually illustrating an example of an arrangement of electronic components to be mounted on a printed wiring board by the electronic component mounting system.
FIG. 11 is a diagram for explaining a process of creating a mounting program in the electronic component mounting system.
FIG. 12 is a flowchart showing a main part of a mounting program executed by the control device.
[Explanation of symbols]
10: Electronic component mounting system 12: Base 14: Printed circuit board 16: Circuit board conveyor 18: Printed circuit board support device 48: First stop device 50: Second stop device 52: Mounted surface 54: First mounted surface 56: Second mounting surface 72a: First support pin 72b: Second support pin 300: Control device 302: CPU 304: ROM 306: RAM 310: Computer 312: I / O interface 360: Host computer 362: Parts data generator 400: CAD data 402: First process program 404: Second process program 406: Production program

Claims (9)

A wiring board transport device that transports a printed wiring board along a straight line, a component mounting device that mounts electrical components on a printed wiring board carried by the wiring board transport device, and controls the wiring board transport device and the component mounting device Printed circuit board having a mounting area that is an area in which an electrical component is to be mounted larger than a mountable area that is an area in which the electrical component of the component mounting apparatus can be mounted. A method of manufacturing a printed circuit board by attaching to
Whole mounting including a plurality of partial mounting programs in which the mounting area is divided into a plurality of partial areas having a size equal to or smaller than the mountable area in the transport direction of the wiring board transport device, and the mounting order is determined for each of the partial areas. A storing step of storing the program in a program memory;
The wiring board transport apparatus moves one of the partial areas of the printed wiring board to the mountable area of the component mounting apparatus, and the partial area of the plurality of partial mounting programs is moved to the moved partial area. A partial area mounting step for mounting an electrical component on the component mounting apparatus according to the one corresponding to the above is repeated by the number of the partial areas, and is a set of the partial mounting areas of the printed wiring board. look including a mounting step of mounting the electrical component to the entire large attachment area, and, as the wiring board conveying device,
A printed wiring board conveyor that supports the printed wiring board from below by an endless belt and conveys the printed wiring board by rotating the belt;
By stopping the wiring board conveyor when each of the plurality of partial areas moves to the mountable area of the component mounting apparatus, the printed wiring board is stopped without using a stopper that contacts the printed wiring board. Wiring board conveyor controller
The printed circuit board manufacturing method characterized by using what contains . The mounting area is divided into two partial areas, a first partial area and a second partial area, and the plurality of partial mounting programs are two partial mounting programs;
The mounting step is
Move the first partial area of the printed wiring board to the mountable area in the wiring board transport device, and according to the first partial area corresponding to the first partial area of the two partial mounting programs, A first mounting step of mounting an electrical component on the component mounting device;
The component mounting apparatus moves the second partial area to the mountable area in the wiring board transport device, and the second partial area is moved to the second partial area according to the second partial area corresponding to the second partial area. The printed circuit board manufacturing method according to claim 1 , further comprising a second mounting step of mounting an electrical component on the printed circuit board. Printed circuit board manufacturing method according to claim 1 or 2 divided is equally divided substantially into the partial region of the mounting region. A component supply device for supplying electrical components;
A component mounting device for mounting an electrical component supplied from the component supply device on a printed wiring board;
A printed wiring board in which a mounting area, which is an area where electrical components are to be mounted, is larger than a mountable area where electric components of the component mounting apparatus can be mounted is transported in a transport direction parallel to a straight line, and the printed wiring A wiring board transport device for sequentially stopping each of a plurality of partial areas in which the mounting area of the board is divided into a size equal to or smaller than the mountable area in the transport direction at a plurality of positions located in the mountable area; ,
A program memory for storing an entire mounting program including a plurality of partial mounting programs in which the mounting order of electrical components is determined for each of the plurality of partial areas;
Each time the printed wiring board is stopped at each of the plurality of stop positions by the wiring board transport device, the component mounting apparatus is provided with an electrical component in each of the plurality of partial regions according to each of the plurality of partial mounting programs. look including a mounting control portion for mounting, and said wiring board conveying device,
The endless belt to support the printed circuit board from below, and a wiring-board conveyor for conveying a more printed circuit board that is orbiting the belt,
By stopping the wiring board conveyor when the printed wiring board reaches each of the plurality of stop positions, the printed wiring board is moved to each of the plurality of stop positions without using a stopper that stops in contact with the printed wiring board. An electrical component mounting system, comprising: a wiring board conveyor control unit to be stopped . A component supply device for supplying electrical components;
A component mounting device for mounting an electrical component supplied from the component supply device on a printed wiring board;
A printed circuit board that transports the printed circuit board in a transport direction parallel to a straight line, and the printed circuit board that can stop the printed circuit board at a plurality of stop positions; and
A control device for controlling the component mounting device and the wiring board transport device, and the wiring board transport device,
A printed circuit board that supports the printed circuit board from below by an endless belt, and conveys the printed circuit board by rotating the belt; and
By stopping the wiring board conveyor when the printed wiring board reaches each of the plurality of stop positions, the printed wiring board is moved to each of the plurality of stop positions without using a stopper that stops in contact with the printed wiring board. The wiring board conveyor control unit
And the control device includes:
When the printed wiring board is brought into and stopped by the wiring board transport device, a plurality of electrical components are mounted on the component mounting device on the stopped printed wiring board, and when the scheduled mounting is completed, the wiring board transport is performed. A first mounting mode for causing the apparatus to carry out the printed wiring board;
A printed wiring board having a mounting area which is an area where an electrical component is to be mounted is larger than a mountable area which is an area where the electrical component of the component mounting apparatus can be mounted is transported to the wiring board transport device, and the printed wiring board Each of the plurality of partial areas divided into a size equal to or smaller than the mountable area in the transport direction is sequentially stopped at a plurality of positions located in the mountable area, and the printed wiring board Each time the vehicle is stopped at each of a plurality of stop positions, the component mounting apparatus performs mounting a plurality of times by causing an electrical component to be mounted in a partial area within the mountable area of the plurality of partial areas. When the operation is completed, the electrical component mounting system can be selectively set to the second mounting mode in which the printed circuit board is carried out by the circuit board transport device. Beam. The component mounting device is
A component holding head for holding electrical components;
A head moving device for moving the component holding head to an arbitrary position in a plane parallel to the surface of the printed wiring board;
The electric component mounting system according to claim 4 , further comprising an elevating device that elevates and lowers the component holding head to approach and separate the printed wiring board being stopped. By detecting the positions of two or more reference marks provided for each of the plurality of partial areas of the printed wiring board, a position error of the printed wiring board is obtained, and at least the head moving device has The electric component mounting system according to claim 6 , further comprising means for moving the component holding head to a position corrected by the position error and causing the lifting device to raise and lower the component holding head to perform a mounting operation. A plurality of support devices that respectively support one or more predetermined positions of the printed wiring board stopped at each of the plurality of stop positions from below, each of the support devices,
A support member;
The electrical component mounting system according to any one of claims 4 to 7 , further comprising a support member moving device that moves the support member to an operation position that supports the printed wiring board and a retracted position that does not support the printed wiring board. Wiring board conveyor controller
A deceleration position sensor that detects the printed wiring board in a non-contact manner when the printed wiring board reaches a position where deceleration should be started;
An arrival confirmation sensor for detecting the printed wiring board in a non-contact manner when the printed wiring board arrives at a position to be stopped;
5. The apparatus includes: decelerating the conveyance board conveyor in response to detection of the printed wiring board by the deceleration position sensor, and stopping the conveyance board conveyor in response to detection of the printed wiring board by the arrival confirmation sensor. The electrical component mounting system in any one of thru | or 8 .

Images