JPH07120879B2 - Board positioning device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to a board positioning device used in an electronic circuit board assembly process or the like.

(B) Prior Art In the process of assembling an electronic circuit board, it is important to hold the circuit pattern itself in a correct position in order to arrange the electronic components on the circuit pattern on the board without misalignment. For that purpose, a circuit pattern must be accurately formed with reference to one point on the substrate, and this reference point must be placed at the correct position in space. There are two methods for setting the reference point on the substrate. The first is
This method is widely used for relatively large-sized boards such as television boards, but a positioning hole is formed in the board and the reference point is determined based on this. At the key points of the process, a positioning pin is inserted into this hole to position it. An example of such a device can be found in, for example, JP-A-55-56685. The second method is a method in which a reference point is determined with reference to two sides of the board that are at right angles to each other, and is widely adopted for a small board which has a positioning hole and does not have room. The board is positioned by pressing two specific sides against a member serving as a position reference. Examples of the apparatus include those described in JP-B-62-13837 and JP-A-58-130596.

(C) Problems to be Solved by the Invention Recently, attempts have been made actively to increase mounting density by mounting electronic components on both surfaces of a substrate. In such a mounting process, it is naturally required to turn the substrate upside down. Regarding the positioning in the case of being inverted, in the case of having a positioning hole, the purpose can be achieved by merely inserting the positioning pin into the hole, and there is no problem. However, in the case of a side-referenced substrate, if the direction of travel is reversed in the pitching direction, the reference side will be reversed in the front-back direction, and it will not be possible to perform positioning with an apparatus that uses the front edge of the substrate as a reference as before. Disappear. The present invention has been made to solve such a problem, and an object of the present invention is to provide a device capable of coping with whether the reference side of the substrate comes forward or backward.

(D) Means for Solving the Problems The board positioning device of the present invention includes a pair of guide rail structures for supporting both side edges of the board, and the guide rail structure receives the board and then moves the board forward or backward. First and second pressing members that appear, a driving mechanism for both pressing members, a position reference member arranged between the pressing members, and a position reference for moving the position reference member to the advance position or the retreat position. And a member driving mechanism. The position reference member can change the set interval for both pressing members.

(E) Action When the rear side of the substrate is the reference side, the substrate is fed between the front pressing member (first pressing member) and the position reference member.
As a result, the substrate is pushed from the front, and the rear reference side comes into contact with the position reference member. When the front side of the substrate is the reference side, the substrate is fed between the rear pressing member (second pressing member) and the position reference member. As a result, the substrate is pushed from the rear, and the front reference side hits the position reference member. By changing the position of the position reference member, it is possible to accommodate various substrates having different lengths in the front-rear direction.

(F) Example First, an outline of the apparatus will be described with reference to FIG. In the figure, (1) is a substrate to be processed, (3) is a substrate positioning device for moving the substrate (1) to a processing position,
(5) is the unprocessed substrate (1) in the substrate positioning device (3)
And (7) is an unloading bridge for receiving the processed substrate from the substrate positioning device (3). The loading bridge (5) and the unloading bridge (7) are installed at a distance such that they fit into the substrate positioning device (3) and do not change their mutual distance. Substrate processing work, substrate positioning device (3)
The upper part of the is submerged below the loading bridge (5) and the unloading bridge (7).
After the work is completed, the upper part of the substrate positioning device (3) rises to connect the loading bridge (5) and the unloading bridge (7). This mechanism will be described later.

Next, the structure of the loading bridge (5) will be described. The loading bridge (5) is composed of a pair of parallel girder structures (10) (11). One-sided girder structure (11)
Can be opened and closed relative to the girder structure (10), that is, it can move by itself to change the distance between the girder structure (10). The electric motor (12) schematically shown in FIG. 6 constitutes a power source for changing the distance. The electric motor (12) rotates the screw shaft (13) to move the girder structure (11). In the above description, the girder structure (11) is particularly referred to as a movable girder structure.

At the edges of the girder structure (10) and the movable girder structure (11) facing each other, the step (1
4) is formed (Figs. 5 and 12). Step (14)
Most of the bottom part of the board is near the exit of the loading bridge (5), and most of it is on the substrate transfer belt (15).
It is composed by. A stopper (16) is arranged between the girder structure (10) and the movable girder structure (11) to prevent overrun of the substrate (1) carried by the substrate carrying belt (15). The stopper (16) is a lever-like member having a shape shown in FIG. 16, and is attached to a rotating shaft (17) horizontally supported on the outer surface of the girder structure (10) and has a claw (18) at the tip. ) Is advanced to the substrate locking position with the rotation of the rotation shaft (17) in one direction, and retracted from the substrate locking position with the rotation of the rotation shaft (17) in the opposite direction. (19) is an advance / retreat actuator of the stopper (16). The forward / backward actuator (19) is composed of an air cylinder, and has a girder structure (10).
The base end of the rod (21) is pivotally supported by a bracket (20) protruding from the crank (22) fixed to the rotating shaft (17). When the advancing / retreating actuator (19) moves the rod (21) in and out, the rotation shaft (17) is rotated. The output member (23) is fixed to the end of the rotating shaft (17) on the unloading bridge (7) side. The output member (23) is a lever-like member having a roller (24) at its tip.

Reference numeral (26) is a walking beam for feeding the substrate (1), and three claws (27), (28) and (29) are projected downward. The claw (27) is for pushing out the processed substrate (1) from the substrate positioning device (3), and the claws (28) (29) are for the substrate positioning device (3) from the loading bridge (5).
It is for feeding the unprocessed substrate (1) by sandwiching it from the front and back.

The unloading bridge (7) also consists of a pair of parallel girder structures (40) (41). The girder structure (41) located on the same side as the movable girder structure (11) is also capable of changing the distance with respect to the girder structure (40). Therefore, girder structure (41)
Is also called movable girder structure. The power source for changing the spacing of the movable girder structure (41) is an electric motor (42) schematically shown in FIG. 6 and a screw shaft (43) rotated by the electric motor (42). Electric motor (1
The control devices (44) control the movable girder structures (11) and (14) so that the movable girder structures (11) and (42) simultaneously move in the same direction, at the same speed, and by the same distance. At the edges of the girder structure (40) and the movable girder structure (41) that face each other, a step (45) is formed to drop and support the side edge of the substrate (1).
Most of the bottom portion of the substrate is constituted by the substrate transport belt (46) except for a small portion near the entrance of the unloading bridge (7).

The structure of the substrate positioning device (3) is as follows. The base (50) is a so-called XY table, 2 in the horizontal plane.
Move dimensionally. A frame (51) is installed on the top of the frame (51), and a pair of guide rail structures (52) ( 53) is installed. The guide rail structure (53) is movable with respect to the guide rail structure (52) and can be referred to as a movable guide rail structure. The guide rail structure (52) and the movable guide rail structure (53) have rail plates (54) (55). Further, it is further lowered from the rail plates (54) and (55) to form opposed step portions (56), which support the side edges of the substrate (1). In the rail plate (55), a large number of rollers (61) are arranged at the step (56). The rollers (61) are arranged in a row and guide the edge of the substrate (1), and each roller (61) is supported by one slide block (62). Each slide block (62) can move back and forth within a certain stroke range as shown in FIG. 7, and has a compression coil spring (63).
Thus, the roller (61) is pushed out to the maximum position.

The movable guide rail structure (53) will be described in more detail. Reference numeral (70) is a base plate which is a main part of the movable guide rail structure (53), and the rail plate (55) is placed thereon. At both ends of the rail plate (55), elongated holes (71) extending in a direction perpendicular to the flow direction of the substrate (1) are formed,
A guide pin (72) protruding from the base plate (70) is engaged with the elongated hole (71). Base plate (70)
A spring receiving plate (73) is fixed to the side surface of the rail, and a compression coil spring (74) is inserted between the spring receiving plate (73) and the rail plate (55) as shown in FIG. The plate (55) is pushed toward the rail plate (54). The stopper (75) for stopping the advance of the rail plate (55) is also the base plate (7
It is fixed to 0) (Fig. 7). Reference numeral (76) shown in FIGS. 4, 5, 6 and 8 is a retaining bolt having a greatly expanded head portion and extends in the same direction as the long hole (the long hole (71) formed in the rail plate (55). (4) is screwed into the base plate (70) to hold the rail plate (55) slidably and without being separated from the base plate (70).

Loading bridge (5) on the base plate (70)
Also, a pair of connecting rollers (80) are mounted at predetermined intervals in the horizontal direction on the side surface facing the end of the unloading bridge (7). One cam follower roller (81) is attached to each side of the rail plate (55). The cam follower roller (81) is usually
That is, in the state where the rail plate (55) is in contact with the stopper (75), the rail plate (54) is slightly displaced from the pair of coupling rollers (80) farther from the rail plate (54). It is in the position (Fig. 9). The cam follower roller (81) is combined with a wedge-shaped cam plate (82) fixed to the movable girder structures (11) (41) of the loading bridge (5) and the unloading bridge (7) to form a cam device (83). ) Is composed.

Guide rail structure (52) and movable guide rail structure (5
3) is lifted and lowered by the lifting mechanism (90). (9
Reference numeral 1) is an elevating frame which is a main part of the elevating mechanism (90), which constitutes an upper structure of the frame (51), and is vertically moved by fitting a guide rod (103) to a bearing (not shown). The air cylinder (92) attached to the frame (51) serves as the lifting power source. The rod (93) of the air cylinder (92) faces directly above, and the push-up head (94) is attached to the tip thereof. The push-up head (94) pushes up the roller (96) at the tip of the lever (95) pivotally supported on the frame (51). Another roller (97) is attached to the back side of the lever (95), and this roller (97)
Ear pieces (98) protruding from one side of the lifting frame (91)
Push up. Thus, the lever (95) is fixed to one end of the rotating shaft (99), but another lever (100) is fixed to the other end of the rotating shaft (99). The roller (101) at the tip of this lever (100) is attached to the lifting frame (9
1) It has a mechanism to push up the ear piece (102) protruding from the other side. As a result, the force of the single air cylinder (92) can be evenly transmitted to both sides of the elevating frame (91).

The guide rail structure (5
2) is fixed, but movable guide rail structure (53)
Is slidably supported by a linear guide mechanism (110) (FIGS. 2 and 3). The sliding direction is perpendicular to the flow direction of the substrate (1). The brake mechanism (11) that stops the sliding of the movable guide rail structure (53) to the bracket (111) hanging from the movable guide rail structure (53).
2) is supported. The brake mechanism (112) is composed of an air cylinder (114) having a brake pad (113) attached to the tip of a rod. The brake pad (113) is constantly pressed against the lower surface of the elevating frame (91) by the force of the compression coil spring (115) to lock the movable guide rail structure (53). When the air cylinder (114) operates, the brake pad (113) is pulled away from the elevating frame (91), and the movable guide rail structure (53) can slide.

In the substrate positioning device (3), the positioning in the direction perpendicular to the substrate flow direction is configured by the rail plate (55) pressing the substrate (1) against the rail plate (54). We must take measures. The mechanism will be described below.

Reference numeral (120) is a position reference member that receives the front edge of the substrate (1) in the traveling direction (hereinafter simply referred to as “front edge”) or the rear edge of the substrate (1) (hereinafter simply referred to as “rear edge”). The position reference member (120) is provided at the tip of the lever (121), and the lever (121) is pivotally supported by the lifting frame (91) so as to be parallel to the guide rail structure (52). ) (13th
Attached). The base of the lever (121) is a slot (123), and the lever (121) can be slid in the axial edge direction of the rotating shaft (122) by loosening the tightening bolt (124). A key (125) is interposed between the lever (121) and the rotating shaft (122) so that the mounting angle of the lever (121) does not change. The rotation shaft (122) has a lever (126) fixed to one end thereof, and a spring (not shown) pushes the lever (126) between the rail plates (54) and (55) so that the position reference member (12) is provided.
0) is always held at the angular position where the face appears. A lever-like power transmission member (127) is fixed to the other end of the rotating shaft (122). This power transmission member (127) is transmitted with the movement from the output member (23) of the loading bridge (5). Forward / backward actuator (19), output member (2
3), the position reference member drive mechanism (128) is configured by combining the power transmission member (127). A bumper member (129) urged by a spring (not shown) projects from both sides of the position reference member (120). The spring force is weak, and if the substrate (1) hits it, the bumper member (129)
Easily retracts into the position reference plane.

The pressing member for pressing the substrate (1) against the position reference member (120) is not the lifting frame (91) but the frame (51).
It is installed in the non-elevating part of. A first pressing member (140) and a second pressing member (14) are provided on the front edge side and the rear edge side of the substrate (1).
1) is provided symmetrically. First and second pressing members (140)
Reference numeral (141) is a lever-like member fixed to the vertical rotation shafts (142) (143), and has rollers (144) (145) contacting the substrate (1) at its tip. These pressing members (14
0) (141) is moved by a pressing member drive mechanism (147) configured as follows. Ie pivot (142)
(143) includes levers (1) so that they project toward each other.
48) Fix (149) (Fig. 15). Lever (148) (14
The rollers (150) (151) are fixed to the tip of 9), and the tension coil springs (152) (153) allow the lever (148) to rotate counterclockwise in FIG. 15 and the lever (149) to rotate the same. Around each of them. Laura (15
0 (151) hits the slide rods (154) (155) horizontally supported by the frame (51). Slide rod (15
4) The (155) is pushed out by the compression coil springs (156) (157) to the maximum advance position (the retaining ring (158) defines the limit). When the substrate positioning device (3) returns to the so-called origin between the loading bridge (5) and the unloading bridge (7), the slide rods (154) (155) hit the immobile stopper (159) provided at this position. The lever (148) (149) to the spring (152) (15
By pressing against 3), the pressing members (140) (141) are rotated in the direction away from the position reference member (120).

In the figure, (170) is an adhesive dispenser.

The device of the present invention operates as follows. In the present embodiment, the processing of the substrate (1) is a work of lowering the adhesive dispenser (170) to attach the adhesive to the surface of the substrate. At that time, the elevating frame (91) is lowered. In the position, the guide rail structure (52) and the movable guide rail structure (53) are lowered to a height that does not interfere with the loading bridge (3) and the unloading bridge (7) (Fig. 2). PCB processing work, guide rail structure (52)
The movable guide rail structure (53) is lowered, and the substrate positioning device (3) is separated from the immovable stopper (159). Therefore, the slide rods (154) (155) of the pressing member driving mechanism (147) are moved to the maximum advance position, the pressing members (140) (141) approach the position reference member (120), and the substrate (1 ) Is being positioned. In the illustrated example, the second pressing member (141) and the position reference member (120)
The substrate (1) is sandwiched between and. Further, the rail plate (55) is reinforced by the elastic force of the spring (74).
The substrate (1) is pressed against. As a result, the relative positions of the substrate positioning device (3) and the substrate (1) are determined in the two directions orthogonal to each other.

After the substrate processing is completed, the substrate positioning device (3) returns to the origin. When returning to the origin, slide rod (154) (15
5) is pressed against the immovable stopper (159), the pressing members (140) (141) rotate in a direction away from the position reference member (120), and the substrate (1) is unconstrained in the flow direction. Next, the air cylinder (92) operates to raise the elevating frame (91). The pressing members (140) (141) remain below and disappear from the front and back of the substrate (1). As the lifting frame (91) rises, the guide rail structure (52) fits between the girder structures (10) and (40) of the loading bridge (5) and the unloading bridge (7), and is lined up in a straight line. The movable guide rail structure (53) is also fitted between the movable girder structures (11) and (41) and arranged in a straight line. At that time, the rail plate (55) is movable girder structure (11) (41)
As shown in FIG. 9 to FIG. 11, contact is made between the cam plate (82) and the roller cam follower (81) as the rail plate (55) resists the spring (74). Then, the substrate (1) is released and released. In the state of FIG. 11 in which the movable guide rail structure (53) has reached the top of rising, the cam plate (82) is fitted between the connecting rollers (80) (80), and the movable guide rail structure (53) itself. Movable girder structure (11)
It will be connected to (14). On the other hand, guide rail structure (5
On the side of 2), the lever (127) is aligned with the output member (23), and the roller (24) of the output member (23) faces the upper surface of the power transmission member (127).

Here, the movement of the forward / backward actuator (19) occurs. 18th
As shown in the figure, when the advancing / retreating actuator (19) extends the rod (21), the stopper (16) pivots downward and separates from the substrate (1) stopped by hitting this. Output member (2
3) also rotates downward, and the power transmission member (1
27) Press. Therefore, the rotation shaft (122) rotates, and the position reference member (120) retracts from the board locking position (6th and 15th positions).
Figure). Along with this, the walking beam (26) moves, the processed substrate (1) is pushed out from the substrate positioning device (3) to the unloading bridge (7), and the unprocessed substrate (1) is discharged from the loading bridge (5). Transfer to the board positioning device. The substrate transfer belt (15) is stationary during the operation of the walking beam (26). Board (1)
After finishing the delivery of the rod, the retraction actuator (19) retracts the rod (21), and the stopper (16) and the position reference member (120) are restored to the old position. At the same time, the movement of the substrate carrying belt (15) is restarted, and the new unprocessed substrate (1) is carried to the stopper (16). The substrate transfer belt (46) of the unloading bridge (7) is always in operation, and when a part of the processed substrate (1) is over it, it is pulled in by a frictional force and carried away. Is.

Next, the cylinder (92) lowers the lifting frame (91). When the cam follower roller (81) is separated from the cam plate (82), the rail plate (55) advances by the force of the spring (74) and presses the substrate (1) against the rail plate (54). When the elevating frame (91) is fully lowered, the pressing members (140) (141) appear in front of and behind the substrate (1). When the substrate positioning device (3) moves horizontally and moves away from the immovable stopper (159), the pressing members (140) (141) approach the position reference member (120) and the second pressing member (141). Is the substrate (1)
Is pressed from the rear side against the position reference member (120) to make the substrate (1) obtain a predetermined reference position.

When the substrate (1) uses the rear side as the reference side, the substrate (1) is fed in front of the position reference member (120). This time, the first pressing member (140) moves the rear edge of the substrate (1) to the position reference member (12).
0) will be forced. By moving the lever (121) along the rotating shaft (122), the distance between the position reference member (120) and the pressing members (140) (141) is set to the substrate (1).
It can be freely set according to the length in the front-back direction.
In order to change the feeding depth of the substrate (1) in this way, the walking beam (26) can be changed in its moving stroke. It is desirable that the positions of the claws (28) (29) are also variable.

The transfer width of the substrate (1) is adjusted as follows. When the board positioning device (3) is placed at the origin and the lifting frame (91) is raised, the connecting rollers (80) (80) sandwich the cam plate (82) and the movable girder structures (11) (41) as described above. ) And the movable guide rail structure (53) are connected. When the movable guide rail structure (53) is unlocked by the brake mechanism (112) and the electric motors (12) (42) are driven, the movable girder structures (11) (41) and the movable guide rail structure (53) are separated. The substrates are moved together in a direction in which the substrate transfer width is widened or narrowed. When the desired transfer width is obtained, the electric motor (12) (4
2) is stopped and the movable guide rail structure (53) is locked again by the brake mechanism (112), then the substrate (1) having that width is received and transported.

(G) Effect of the Invention According to the present invention, since the positioning can be performed regardless of whether the front side or the back side of the substrate is the reference side, the line configuration is extremely effective in the double-sided mounting process that necessarily involves the reversal of the position of the reference side. It's easy. For boards with different lengths in the front-back direction,
It can be easily handled by changing the position of the position reference member, can be widely used, and is easy to use.

[Brief description of drawings]

FIG. 1 shows an embodiment of the present invention. FIG. 1 is a perspective view showing a schematic structure of the apparatus, and FIGS. 2 and 3 are sectional front views of a main part of a substrate positioning apparatus showing different operating states. FIG. 4 is a perspective view showing a lifting mechanism having a guide rail structure, and FIG.
FIGS. 6 and 6 are top views of different operating states, FIGS. 7 and 8 are cross-sectional views and partial top views of the movable guide rail structure,
9 to 11 are side views for explaining the interaction between the movable guide rail structure and the cam plate, FIG. 12 is a partial perspective view of the movable girder structure on the loading bridge side, and FIG. 13 is a stationary guide rail structure. FIG. 14, FIG. 14 is an enlarged top view of the substrate positioning device, FIG. 15 is an enlarged top view of the substrate positioning device in which the main part is broken, and FIG. 16 is a perspective view of the position reference member drive mechanism. 17 and 18 are operation explanatory views of the position reference member drive mechanism. (1) ... Board, (3) ... Board positioning device, (52)
(53) …… Guide rail structure, (140) (141) …… First
And the second pressing member, (147) ... pressing member driving mechanism, (1
20) ... position reference member, (128) ... position reference member drive mechanism.

Claims (1)

[Claims] 1. A substrate positioning device having the following configuration. (A) A pair of guide rail structures that play a role of supporting both side edges of the substrate (b) After the guide rail structure receives the substrate,
First and second pressing members appearing in front of or behind this substrate (c) Pressing member drive that gives movement to the first and second pressing members and applies pressure to the substrate between them from the front or rear Mechanism (d) is disposed between the first and second pressing members,
A position reference member that plays a role of receiving a rear edge or a front edge of the substrate and is capable of changing a set interval for the first and second pressing members. (E) A position for moving the position reference member to an advanced position or a retracted position. Reference member drive mechanism.