Apparatus for positioning substrates of different sizes of printed-wiring boards

An apparatus for positioning printed-wiring substrates of different sizes comprising: an X-Y table having a movable device movable along X and Y axes; a pair of Y-axis positioning members which are disposed on the movable device and relatively movably spaced from each other along the Y axis, so as to be engageable with opposite parallel sides of the substrate parallel to the X axis, for positioning the substrate along the Y axis; an X-axis positioning member provided on the movable device and engageable with the substrate to position the substrate along the X axis; a first engagement member provided on at least one of the the Y-axis positioning members; a second engagement member which is fixed in position in the Y-axis direction; and a driving device for moving the first and second engagement members toward each other along an axis perpendicular to the Y axis, and effecting engagement of the first and second engagement members with each other, to thereby hold the above-indicated at least one Y-axis positioning member fixed in the Y-axis direction, and permit a change in relative position between the at least one Y-axis positioning member and the movable device along the Y-axis through a movement of the movable device along the Y axis.

BACKGROUND OF THE INVENTION 
1. Field of the Art 
The present invention relates generally to an apparatus capable of 
positioning circuit substrates of different sizes of printed-wiring 
boards, and more particularly to such a positioning apparatus having a 
pair of positioning members for positioning the substrates, wherein a 
distance between the positioning members can be efficiently and accurately 
changed to suit the specific size of the substrate that is to be 
positioned. 
2. Related Art Statement 
In the art of drilling holes in a circuit substrate of a printed-wiring 
board, or performing other operations on the substrate, or placing various 
electronic circuit components on the substrate, it is a general practice 
to place the circuit substrate on an NC table (numerically-controlled 
table) which is movable along X and Y axes perpendicular to each other. 
Since the substrate must be positioned on the NC table with high 
precision, the NC table is usually equipped with a substrate positioning 
device for accurate positioning of the substrate on the table. 
An example of a substrate positioning device of the type indicated above 
comprises a mounting or support member disposed on the NC table and 
movable along X and Y axes perpendicular to each other, a pair of Y-axis 
positioning members which are disposed parallel to the X axis and at least 
one of which is movable toward and away from the other along the Y axis so 
as to be engageable with opposite parallel sides of the substrate parallel 
to the X axis to thereby position the substrate in the Y-axis direction, 
and an X-axis positioning member which is engageable with the substrate to 
position the substrate in the Y-axis direction. This type of positioning 
device is therefore capable of positioning different sizes of the circuit 
substrates. 
In the substrate positioning device indicated above, the distance between 
the Y-axis positioning members is changed depending upon the sizes of the 
substrates by the operator, by moving the positioning members toward or 
away from each other in the Y-axis direction, directly by hand, or by 
manipulating suitable mechanical means such as a screw-and-nut feed 
arrangement. 
PROBLEMS SOLVED BY THE INVENTION 
However, the above-indicated methods of changing the distance between the 
positioning members suffer inconveniences. More specifically, where the 
positioning members are moved directly by hand, considerable efforts and 
time are required to accurately establish an intended distance between the 
positioning members suitable for the specific size of a substrate to be 
positioned. Where a feed screw or other suitable mechanical means is 
employed, the substrate positioning device is complicated in construction 
due to additional components of the mechanical means, and expensive 
particularly when high positioning accuracy is required for establishing 
the desired spacing between the positioning members. 
SUMMARY OF THE INVENTION 
It is accordingly an object of the present invention to provide a substrate 
positioning apparatus capable of positioning circuit substrates of 
printed-wiring boards having different sizes, which apparatus comprises a 
simple arrangement for accurately and efficiently changing a distance 
between a pair of Y-axis positioning members to suit the specific size of 
the substrate to be positioned. 
According to the present invention, there is provided a substrate 
positioning apparatus for positioning circuit substrates of different 
sizes of printed-wiring boards, comprising an X-Y table having movable 
means movable along an X axis and a Y axis perpendicular to the X axis, a 
pair of Y-axis positioning members disposed on the movable means and 
spaced from each other in the Y-axis direction to position the substrate 
in the Y-axis direction, and an X-axis positioning member provided on the 
movable means and engageable with the substrate to position the substrate 
in the X-axis direction. At least one of the Y-axis positioning members is 
movable along the Y axis so that the Y-axis positioning members are 
movable toward and away from each other, so that the Y-axis positioning 
members are engageable with opposite parallel sides of the circuit 
substrate which are parallel to the X axis, thereby positioning the 
substrate in the Y-axis direction. The instant substrate positioning 
apparatus further comprises a first engagement member provided on the 
above-indicated at least one Y-axis positioning member, a second 
engagement member which is fixed in position in the Y-axis direction, and 
a first driving device for moving the first and second engagement members 
relative to each other in a direction perpendicular to the Y axis, and for 
effecting engagement of the first and second engagement members with each 
other, to thereby hold the at least one Y-axis positioning member fixed in 
the Y-axis direction, and permit a change in relative position between the 
at least one Y-axis positioning member and the movable means in the Y-axis 
direction through movement of the movable means in the Y-axis direction. 
In the substrate positioning apparatus of the present invention constructed 
as described above, the distance between the Y-axis positioning members in 
the Y-axis direction can be changed or adjusted in a process which 
comprises the steps of: effecting engagement between the first and second 
engagement members by activating the first driving device, to hold the 
above-indicated at least one movable Y-axis positioning member fixed in 
position in the Y-axis direction; then moving the movable means in the 
Y-axis direction relative to the thus fixed movable Y-axis positioning 
member, to thereby change a relative position between the movable means 
and the fixed movable Y-axis positioning member, so that the distance 
between the pair of Y-axis positioning members is adjusted to suit the 
size of the substrate; and subsequently releasing the engagement of the 
first and second engagement members. 
As is apparent from the above description, the adjustment of the distance 
between the Y-axis positioning members in the instant positioning 
apparatus is carried out by utilizing accurate positioning capability of 
the movable means which is accurately positioned by the X-Y table provided 
for positioning the substrate. This manner of changing the distance 
between the Y-axis positioning members permits faster and more accurate 
positioning of the Y-axis positioning members, than the conventionally 
practiced manual positioning by hand or by means of a feed screw 
arrangement or other mechanical feed system. Further, the positioning 
steps for positioning the Y-axis positioning members in the present 
apparatus can be automated, without the provision of an expensive 
additional driving device for positioning the Y-axis positioning member in 
the Y-axis direction for the purpose of changing the distance between the 
positioning members. Thus, the present invention provides a simple and 
inexpensive arrangement for adjusting the above-indicated distance to meet 
various sizes of the substrates to be positioned. 
The at least one movable Y-axis positioning member is normally fixed to the 
movable means. For this end, suitable means such as frictional clamping 
means or a positive clamp mechanism may be provided. In the case where 
frictional clamping means is employed, a frictional force is applied 
between the movable Y-axis positioning member and the movable means, so 
that the frictional force does not permit a relative displacement between 
the movable Y-axis positioning member and the movable means when the 
movable means is moved in the Y-axis direction during normal positioning 
operations for positioning the substrate, but permits the relative 
displacement when the movable means is moved in the Y-axis direction with 
the movable Y-axis positioning member held fixed through the engagement of 
the first and second engagement members as previously described. Where a 
positive clamp mechanism is used, the movable Y-axis positioning member is 
normally positively clamped to the movable means by the clamp mechanism. 
Therefore, it is necessary to automatically or manually unclamp the 
movable Y-axis positioning member, before the movable means is moved 
relative to the movable Y-axis positioning member to change the distance 
between the Y-axis positioning members. 
In the above instance where the clamp mechanism is provided according to an 
advantageous embodiment of the invention, the clamp mechanism may be 
provided on the at least one movable Y-axis positioning member, such that 
the clamp mechanism is operable between a clamp position in which the 
movable Y-axis positioning member is fixed relative to the movable means, 
and an unclamp position in which the movable Y-axis positioning member is 
unclamped. The clamp mechanism is normally placed in the clamp position. 
In the present advantageous embodiment, the positioning apparatus further 
comprises an unclamping member which is fixed in position in the Y-axis 
direction, and a second driving device for moving the unclamping member 
and the clamp mechanism relative to each other, to cause the clamp 
mechanism to be brought into the unclamp position by the unclamping 
member. 
In the above advantageous embodiment wherein the clamp mechanism is 
provided, the at least one movable Y-axis positioning member is normally 
clamped by the clamp mechanism to the movable means. When the distance 
between the Y-axis positioning members is changed by moving the movable 
means, the second driving device is activated to move the unclamping 
member and the clamp mechanism toward each other so that the clamp 
mechanism is brought into its unclamp position by the unclamping member. 
In the meanwhile, the at least one movable Y-axis positioning member is 
fixed in the Y-axis direction due to the first and second engagement 
members engaging each other. Subsequently, the movable means is moved 
along the Y axis to change the Y-axis position of the at least one movable 
Y-axis positioning member relative to the movable means, so as to 
establish a suitable distance between the Y-axis positioning members 
corresponding to the size of the substrate. Then, the first driving device 
is activated to disengage the first and second engagement members away 
from each other, while the second driving device is activated to place the 
clamp mechanism in its clamp position. In this condition, the movable 
Y-axis positioning member and the movable means are movable together along 
the X and Y axes, with the former clamped to the latter, for normal 
positioning of the substrate. 
According to the above-described advantageous embodiment, therefore, the 
distance between the Y-axis positioning members can be changed readily and 
precisely, with a simple and inexpensive arrangement as previously 
described. In addition, the movable Y-axis positioning member is firmly 
clamped to the movable means by the clamp mechanism, whereby the 
positioning accuracy of the substrate is improved. Further, the clamp 
mechanism is automatically set in its unclamp position by the unclamping 
member by activating the second driving device, thus permitting a relative 
displacement of the movable means and the movable Y-axis positioning 
member for adjusting the distance between the Y-axis positioning members. 
Thus, it is not necessary to manually unclamp the movable Y-axis 
positioning member from the movable means 
According to a preferred form of the above embodiment, the first driving 
device is adapted to serve also as the second driving device for bringing 
the clamp mechanism into its unclamp position. More specifically, the 
first driving device is designed to move both of the first engagement 
member and the clamp mechanism, whereby the first and second engagement 
members engage each other while at the same time the clamp member is set 
to its unclamp position. In this form of the invention, the positioning 
apparatus is simplified. 
According to a further preferred form of the above embodiment, the second 
engagement member is adapted to serve also as the unclamping member, 
rather than a separate member is provided to exclusively serve as the 
unclamping member. In this case, too, the positioning apparatus is 
accordingly simplified. 
According to another advantageous embodiment of the invention, the X-axis 
positioning member is movable in the X-axis direction, and the positioning 
apparatus further comprises a third engagement member provided on the 
X-axis positioning member, a fourth positioning member which is fixed in 
position in the X-axis direction, and a third driving device for moving 
the third and fourth engagement members relative to each other in a 
direction perpendicular to the X axis, and for effecting engagement of the 
third and fourth engagement members with each other, to thereby hold the 
X-axis positioning member fixed in the X-axis direction, and permit a 
change in relative position between the X-axis positioning member and the 
movable means in the X-axis direction through a movement of the movable 
means in the X-axis direction. 
In the above embodiment, the relative X-axis position of the X-axis 
positioning member and the movable means can be changed when the movable 
means is moved along the X axis while the X-axis positioning member is 
fixed with the third and fourth engagement members in engagement with each 
other, as well as the relative Y-axis position of the movable Y-axis 
positioning member and the movable means can be changed when the movable 
means is moved along the Y axis while the movable Y-axis positioning 
member is fixed with the first and second engagement members in engagement 
with each other, as previously described. 
In the above embodiment, therefore, it is possible not only to change the 
distance between the Y-axis positioning members for Y-axis positioning of 
the substrate, but also to change the X-axis position of the X-axis 
positioning member for positioning the substrate in the X-axis direction. 
These positionings of the movable Y-axis positioning member and the X-axis 
positioning member are achieved by utilizing the movements of the movable 
means which are moved by the X-Y table along the X and Y axes. 
Accordingly, the positioning apparatus according to this embodiment is 
readily and accurately adaptable to not only the X-axis dimension but also 
the Y-axis dimension of the substrate to be positioned. 
Although the above embodiment includes the first and second engagement 
members and the first driving device for changing the distance between the 
Y-axis positioning members, it is possible that only the third and fourth 
engagement members and the second driving device for the X-axis 
positioning member may be provided without the previously described 
arrangement for changing the Y-axis distance of the Y-axis positioning 
members. 
Like the movable Y-axis positioning member, the X-axis positioning member 
may be normally fixed to the movable means by suitable clamp means similar 
to that used for the movable Y-axis positioning member.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
To further clarify the concept of the present invention, a preferred 
embodiment of the invention will be described, referring to the 
accompanying drawings. 
Referring first to an illustrative fragmentary perspective view of FIG. 1, 
there is shown a positioning apparatus for positioning a circuit substrate 
20 of a printed-wiring board. This substrate positioning apparatus is 
illustrated in greater detail in a plan view of FIG. 2, a fragmentary rear 
elevational view of FIG. 3, and a cross sectional view taken along line 
VI--VI of FIG. 2. In these figures, reference numeral 10 designates a 
support member in the form of a rectangular support plate which supports a 
pair of stationary bracket 12, 12 and a pair of movable brackets 16, 16. 
The stationary brackets 12, 12 are fixed to the front left and right 
corners of the rectangular support plate 10, and supports a stationary 
guide 14 attached thereto. The movable brackets 16, 16 slidably engage the 
left and right sides of the support plate 10, and supports a movable guide 
18 fixed thereto. Thus, the movable brackets 16, 16 and the movable guide 
18 are movable along a Y axis toward and away from the stationary brackets 
12, 12 and the stationary guide 14, whereby the stationary and movable 
guides 14, 18 are engageable with the opposite front and rear sides of the 
support plate 10 parallel to an X axis perpendicular to the Y axis. Thus, 
the stationary brackets 12, 12 and the stationary guide 14 constitute a 
stationary Y-axis positioning member while the movable brackets 16, 16 and 
the movable guide 18 constitute a movable Y-axis positioning member. That 
is, the stationary and movable Y-axis positioning member form a pair of 
Y-axis positioning members for positioning the substrate 20 in the Y-axis 
direction, as well as for supporting the substrate 20. The stationary and 
movable guides 14, 18 serve to guide the substrate 20 in the X-axis 
direction (left and right directions in FIG. 2). The stationary guide 14 
consists of an elongate guide bar 22 which has a rectangular shape in 
transverse cross section and extends parallel to the X-axis, and a 
retainer plate 24 attached to the top surface of the guide bar 22. 
Similarly, the movable guide 18 consists of an elongate guide bar 24 and a 
retainer plate 28 parallel to the guide bar 22. 
The guide bars 22, 24 are attached at their opposite ends to the top 
surfaces of the corresponding stationary and movable brackets 12, 12, 16, 
16, so that the guide bars 22, 24 are located a suitable distance above 
the top surface of the support plate 10. The opposed side surfaces of the 
guide bars 22, 24 have a pair of opposed cutouts 30, 32 at their upper 
parts. These cutouts 30, 32 cooperate with the retainer plates 26, 28, 
respectively, to define a pair of guide grooves which are engageable with 
the front and rear sides of the substrate 20 parallel to the X axis. Since 
the stationary and movable guides 14, 18 in this specific embodiment are 
adapted to permit the substrate 20 to be slidably moved in the X-axis 
direction, the substrate 20 is positioned roughly in the Y-axis direction. 
On the right and left sides of the support plate 10, there are disposed a 
feed-in device 34 and a feed-out device 36 for feeding the substrate 20 
along the X axis toward and away from the support plate 10. Each of the 
feed-in and feed-out devices 34, 36 has a pair of conveyer belts 38, 40 on 
which the substrate 20 is placed for loading and unloading via guide 
plates 42, 44. More specifically, the substrate 20 which has been conveyed 
to the feed-in end of the feed-in device 34 is slidably moved on the 
conveyer belts 38, 40 by a loader (not shown) and pushed in between the 
previously described stationary and movable guides 14, 18. In the 
meantime, the substrate 20 supported by the guides 14, 18 is slidably 
moved between the guides 14, 18 by an unloader (not shown), and pulled 
onto the conveyer belts 38, 40 of the feed-out device 36. 
The movable brackets 16, 16 are constructed and disposed in exact symmetric 
relation with each other with respect to the Y axis. For this reason, only 
the movable bracket 16 provided on the left side of the support plate 10 
will be described in detail referring to FIGS. 5 and 6, and no detailed 
description of the right bracket 16 will be given. 
The left movable bracket 16 has in its lower portion a rectangular groove 
46, so that the left-hand side end portion of the support plate 10 
slidably engages the rectangular groove 46, so as to support the movable 
bracket 16 along the left side edge of the support plate 10, that is, in 
the Y-axis direction (perpendicular to the X axis), i.e., in the vertical 
direction of FIG. 2. In the upper portion of the left movable bracket 16, 
there is formed a mounting surface 48 parallel to the rectangular groove 
46, so that the corresponding end of the movable guide 18 is fixed to the 
mounting surface 48. Further, the bottom portion of the movable bracket 16 
has a rectangular groove 50 which is formed across the groove 46 and so as 
to extend along the X axis. A clamp lever 52 is received within a portion 
of the groove 50 above the groove 46. The clamp lever 52 is supported 
pivotally about a pin 54 which extends along the Y axis. The clamp lever 
52 has an operating portion 56 at its one end, which engages one end of a 
spring 60. This spring 60 is accommodated in a round hole 58 which opens 
in the mounting surface 48 at its one end and communicates with the 
rectangular groove 50. With a biasing force of the spring 60, a friction 
surface 60 of the clamp lever 52 is normally held in pressed contact with 
the top surface of the support plate 10, whereby the movable bracket 16 is 
normally held fixed to the support plate, i.e., fixed in position in the 
Y-axis direction. Since the friction surface 62 is located near the pin 
54, the biasing force exerted on the operating portion of the clamp lever 
52 is boosed at the friction surface 62 with a predetermined advantage 
according to the principle of a lever, whereby the friction surface 62 is 
forced against the support plate 10 with a boosted force. The other end of 
the spring 60 bears on the lower surface of the movable guide 18 fixed to 
the mounting surface 48. 
In the side surface of the movable bracket 16, there is formed an 
engagement groove 64 which extends in the vertical direction, i.e., along 
a Z axis perpendicular to the X and Y axes, and which terminates into the 
groove 50 discussed above. This engagement groove 64 is adapted to receive 
corresponding one of two downward extensions 68, 68 of an engagement 
member 66 (FIG. 1) which is fixed in the Y-axis direction. The thicknesses 
of the extension 68 and the engagement groove 64 are so determined that 
the extension 68 fit the groove 64 with only a slight clearance in the 
Y-axis direction, whereby the movable bracket 16 is fixed in place by the 
engagement member 66 along the Y axis. The extension 68 serves as a second 
engagement member which is engageable with the engagement groove 64 in 
order to hold the movable bracket 16 and the movable guide 18 fixed in 
position, while a portion of the movable bracket 16 in which the 
engagement groove 64 is formed serves as a first engagement member which 
is engageable with the second engagement member 68. 
The other end portion 70 of the clamp lever 52 remote from the operating 
portion 56 at said one end projects into the engagement groove 64, so that 
when the extension 68 is inserted into the engagement groove 64, the clamp 
lever 52 is pivoted by the extension 68 against the biasing force of the 
biasing spring 60 as shown in broken line in FIG. 6. As a result, the 
movable bracket 16 and the movable guide 18 are allowed to move relative 
to the support plate 10 in the Y-axis direction. Thus, the clamp lever 52, 
spring 60, etc. constitute a clamp mechanism for clamping the Y-axis 
positioning member (16, 18) to the support plate 10, while the extension 
68 of the engagement member 66 constitutes an unclamping member for 
bringing the clamp mechanism into its unclamp position from its clamp 
position. As is apparent from the above description, the extension 68 
serves not only as the second engagement member, but also as the 
unclamping member for the clamp mechanism. 
The support plate 10 which supports the stationary and movable brackets 12, 
12, 16, 16 and the stationary and movable guides 14, 18, is mounted on an 
NC (numerically controlled) table 72 which is moved in the X-Y plane. 
Described in greater detail referring to a plan view of FIG. 7 and a front 
elevational view of FIG. 8, the NC table 72 is a well known X-Y table 
which includes an X-axis slide 78 which is linearly moved along the X axis 
by a drive motor 76 attached to a base 74, and a Y-axis slide 82 which 
rests on the X-axis slide 78 and is linearly moved along the Y axis by a 
drive motor 80. The support plate 10 is supported on the Y-axis slide 82 
such that the plate 10 is not movable relative to the Y-axis slide 80 in 
the X- and Y-axis directions, but is movable relative to the Y-axis slide 
80 in the vertical direction, that is, along the Z axis normal to the X 
and Y axes. Referring back to FIG. 4, the Y-axis slide 82 has a pair of 
holes 84, 84 formed in the Z-axis direction through its thickness. Through 
these holes 86, 86 are inserted a corresponding pair of rods 86, 86 such 
that the rods 86, 86 are slidable relative to the Y-axis slide 82. The 
support plate 10 is fixed to the top ends of the rods 86, 86 which 
protrude above the upper surface of the Y-axis slide 82. The lower ends of 
the rods 86, 86 which protrude below the bottom surface of the Y-axis 
slide 82 are connected to each other by a connecting bar 88, which is held 
in biased contact with one end of a spring 92 received in a hole 90 formed 
in the Y-axis slide 82. With the connecting bar 88 biased downwardly by 
the spring 92, the support plate 10 is normally held in its lower position 
in which the bottom surface of the plate 10 abuts on stopper bosses 94 
formed on the Y-axis slide 82. Meanwhile, a cylinder 96 is attached to the 
base 74. A piston rod of the cylinder 96 has an adjusting bolt 98 fixed 
thereto, so that the adjusting bolt 98 is abutable on the bottom of the 
connecting bar 88 to elevate the support plate 10 to its upper position 
which is spaced a predetermined distance from the upper surface of the 
Y-axis slide 82. When the support plate 10 is placed in its upper 
position, the cutouts 30, 32 in the movable and stationary guides 14, 18 
are substantially aligned with the upper surfaces of the conveyer belts 
38, 40 of the feed-in and feed-out devices 34, 36 previously described. In 
this condition, the substrate 20 can be transferred from the feed-in 
device 34, and toward the feed-out device 36. When the support plate 10 is 
placed in its lower position, the support plate 10 and the substrate 20 
supported on the plate 10 are located below the level of the feed-in and 
feed-out devices 34, 36, so that the support plate 10 and the substrate 20 
can be moved along the X and Y axes by and together with the Y-axis slide 
82, without an interference with the feed-in and feed-out devices 34, 36. 
Hence, it is possible to position the substrate 20 at desired positions 
for drilling holes in the substrate 20 or placing electronic component 
chips at those desired positions. Indicated at A in FIG. 7, is the 
position at which such drilling or chip placing operations are performed. 
The upper opening of the hole 90 in the Y-axis slide 82 is closed by a 
covering member 100 on which the upper end of the spring 92 bears. The 
X-axis slide 78 is formed with a cutout 102 which extends in the Y-axis 
direction, so as to permit the lower portions of the rods 86, 86 below the 
Y-axis slide 82, the connecting bar 88 and other members to be moved with 
the Y-axis slide 82 in the Y-axis direction. 
As is apparent from the foregoing description, the substrate positioning 
apparatus is provided with movable means which comprises the X-axis slide 
78 for moving the substrate 20 along the X axis, the Y-axis slide 82 for 
moving the substrate 20 along the Y axis, and the support plate 10 for 
moving the substrate 20 along the Z axis. The NC table 72 provides the X- 
and Y-axis movements of the substrate 20, and the support plate 10 
provides the Z-axis movements of the substrate 20. 
In the front portion of the Y-axis slide 82, there is formed a rectangular 
groove 104 in the X-axis direction. At the right-hand side end portion of 
this rectangular groove 104 is fixedly disposed a primary positioning 
member 106. In the remaining portion of the groove 104, there is fixed a 
guide rail 108 of a U-shape in transverse cross section such that the 
opening of the U-shape is on the upper side, as clearly shown in FIG. 4. 
The guide rail 108 slidably supports a secondary positioning member 110 so 
that the latter is movable in the former in the X-axis direction. These 
primary and secondary positioning members 106, 110 serves to accurately 
position the substrate 20 along the X and Y axes, after the substrate 20 
has been roughly positioned along the Y-axis with the stationary and 
movable guides 14, 18. 
As illustrated in FIGS. 9 and 10, the primary positioning member 106 
comprises a positioning pin 114 which projects upward from a block 112 
fixed in the rectangular groove 104, and further comprises a dog plate 118 
which is supported pivotally about a pin 116 fixed to a side surface of 
the block 112. The positioning pin 114 is normally held by a spring 120 in 
its upper position of FIG. 10. In this upper position, the tip of the 
positioning pin 114 is lower than the upper surface of the substrate 20 
which is supported by the stationary and movable guides 14, 18 while the 
support plate 10 is in its upper position. When the support plate 10 is 
lowered to its lower position, the positioning pin 114 is inserted through 
a positioning hole formed in the substrate 20 if the substrate 20 
transferred from the feed-in device 34 is correctly positioned. However, 
if the substrate 20 is not correctly positioned, the positioning pin 114 
is pushed down by the substrate 20 into the block 112 against the biasing 
action of the spring 120, as indicated in broken line in FIG. 10, when the 
support plate 10 is lowered to its lower position. 
The positioning pin 114 is formed with a projection 122 at its lower 
portion. This projection 122 extends out of the block 112 through a cutout 
123 formed in the block 112, and engages an elongate hole 124 formed in an 
intermediate portion of the dog plate 118. The cutout 123 formed in the 
block 112 is dimensioned so that the projection 122 is movable in the 
vertical direction when the pin 114 is moved. When the pin 114 is pushed 
down by the substrate 20 into the block 112 due to misalignment of the 
positioning hole in the substrate 20 with the pin 114, the dog plate 118 
is pivoted about the pin 116 as the projection 122 is lowered. This 
pivotal movement of the dog plate 118 is used to activate a limit switch 
(not shown) which generates a signal to stop the operation of the 
positioning apparatus due to misalignment of the substrate 20. 
As depicted in FIGS. 11 through 13, the secondary positioning member 110 
comprises a positioning pin 128 protruding above a block 126 which 
slidably fits the guide rail 108. This positioning pin 128 is normally 
held by a spring 130 in its upper position. Like the upper position of the 
positioning pin 114 of the primary positioning member 106, the upper 
position of the positioning pin 128 is determined such that the tip of the 
positioning pin 128 is lower than the upper surface of the substrate 20 
supported by the support plate 10 in its upper position. When the support 
plate 10 is lowered to its lower position, the positioning pin 128 is 
inserted through another positioning hole formed in the substrate 20, thus 
cooperating with the positioning pin 114 of the primary positioning member 
106 to position the substrate 20 with high precision. However, if the 
substrate 20 is not correctly positioned, the positioning pin 128 is 
pushed down by the substrate 20 into the block 126 against the biasing 
action of the spring 130. 
In the front portion of the block 126, i.e., on the right side of the block 
126 as viewed in FIG. 13, there is formed a vertical groove 132 in which 
is supported a clamp lever 134 pivotally about a pin 136. A hole 140 is 
formed in the block 126 such that the hole 140 opens in the groove 132. 
One end portion 138 of the clamp lever 134 is held in engagement with one 
end of a spring 142 the other end of which bears on the bottom of the hole 
140. With the above one end portion 138 biased by the spring 142, the 
other end portion 144 of the clamp lever 134 is normally held in pressed 
contact with the guide rail 108. In this arrangement, the secondary 
positioning member 110 is normally clamped to the guide rail 108. As 
indicated in FIG. 14, a cylinder 147 is provided to actuate an unclamping 
member 146 which is supported by a stationary member such as the base 74, 
such that the unclamping member 146 is movable in the Y-axis direction but 
not in the X-axis direction. The unclamping member 146 is adapted so as to 
abut on the previously-indicated on end portion 138 of the clamp lever 134 
when the unclamping member 146 is advanced by the cylinder 147. As a 
result, the clamp lever 134 is pivoted by the unclamping member 146 
against the biasing force of the spring 142, whereby the secondary 
positioning member 110 is unclamped with respect to the guide rail 108, 
and to the support plate 10. Thus, the secondary positioning member 110 is 
allowed to move in the X-axis direction. The free end of the unclamping 
lever 146 has substantially the same width as the groove 132, so that the 
free end may fit the groove 132 in the block 126. In this manner, 
therefore, the secondary positioning member 110 is held fixed in the 
X-axis direction by the unclamping lever 146. The block 126 has, at its 
bottom portion, a pair of flanges 148, 148 which extend in the opposite 
directions along the Y axis. In the meantime, a pair of retainer plates 
150, 150 are attached to the upper surfaces of the guide rail 108. These 
retainer plates 150, 150 cooperate with the guide rail 108 to define a 
pair of guide grooves in which the flanges 148, 148 of the block 126 are 
slidably received to guide the block 126 along the X axis. In this 
arrangement, the block 126 is prevented from tilting when it is clamped to 
the guide rail 108 by the clamp lever 134. As indicated in FIG. 2, the 
support plate 10 has a cutout 152 in its front portion so as to 
accommodate a portion of the guide rail 108 on the Y-axis slide 82, and 
portions of the primary and secondary positioning members 106, 110, so 
that the previously described positioning pins 114, 128 are located at the 
rear of the stationary guide 14. 
In the substrate positioning apparatus which is constructed as described 
hitherto, the previously indicated engagement member 66 is fixed to a 
suitable stationary member such as the base, such that the engagement 
member 66 is located at a predetermined position above the NC table 72, 
and is aligned with the movable guide 18. When the support plate 10 is 
elevated by the cylinder 96 to its upper position, the movable brackets 
16, 16 are moved to their upper position in which the extensions 68, 68 of 
the engagement member 66 engages the engagement grooves 64, 64 in the 
movable brackets 16, 16. At the same time, the movement of the support 
plate 10 to its upper position causes the clamp levers 52, 52 in the 
movable brackets 16, 16 to be pivoted by the extensions 68, 68. In this 
manner, the movable brackets 16, 16 are fixed in position in the Y-axis 
direction, and at the same time the brackets 16, 16 are unclamped with 
respect to the support plate 10. In this condition, therefore, it is 
possible to move the support plate 10 in the Y-axis direction relative to 
the movable brackets 16, 16, by moving the Y-axis slide 82. Hence, for 
example, when it is desired to position a substrate 154 (FIGS. 2 and 4) 
which is smaller in size than the substrate 20, the Y-axis slide 82 is 
moved along the Y axis until the distance between the stationary and 
movable guides 14, 18 is reduced to a value corresponding to the Y-axis 
dimension of the small substrate 154, as indicated in two-dot chanin line 
in FIGS. 2 and 4. Thus, the stationary and movable guides 14, 18 can be 
readily and accurately moved relative to each other along the Y axis, 
whereby the distance between the two guides 14, 18 can be adjusted to a 
desired value that suits the Y-axis dimension of any substrates of 
different sizes. 
Subsequently, the piston rod of the cylinder 96 is retracted to permit the 
support plate 10 to be lowered to its lower position under the biasing 
action of the spring 92. As a result, the engagement of the engagement 
grooves 64, 64 with the extensions 68, 68 is released, whereby the clamp 
levers 52 are pivoted to clamp the movable brackets 16, 16 to the support 
plate 10. In this embodiment, the cylinder 96, spring 92 and other 
components for moving the support plate 10 cooperate to constitute a first 
driving device for moving the movable brackets 16, 16 (first engagement 
member) and the extensions 68, 68 (second engagement member) relative to 
each other in the vertical directions, for effecting engagement of the 
first and second engagement members to hold the movable brackets 16, 16 
fixed in position in the Y-axis direction. Further, this first driving 
device serves also as a second driving device for moving the extensions 
68, 68 (unclamping member) and the clamp levers 52, 52 (clamp mechanism) 
relative to each other in the Y-axis direction, to cause the clamp 
mechanism to be brought into the unclamp position by the unclamping 
member. In connection with the adjustment of the Y-axis position of the 
movable guide 18, it is noted that the conveyer belts 40 and the guide 
plates 44 of the feed-in and feed-out devices 34, 36 are adapted to be 
moved relative to the opposite conveyer belts 38 and guide plates 42, to 
adjust the distance between the conveyer belts 38, 40 and the distance 
between the guide plates 42, 44, depending upon the Y-axis dimension of 
the substrate. More specifically, these distances may be changed by 
operating a handwheel 160 which are connected to one of a plurality of 
adjusting screws 160 (only one screw 160 for the feed-in device 34 is 
shown in FIG. 2) which are operatively connected to each other by a chain 
156 and sprockets 158. 
While the primary positioning member 106 to preciselly position the 
substrate is always fixed in position irrespective of the size of the 
substrate, the secondary positioning member 110 is readily and accurately 
positioned at a suitable location along the X axis, which location is 
determined depending upon the X-axis dimension of the substrate. To adjust 
the position of the secondary positioning member 110, the X-axis slide 78 
is first moved along the X axis so that the groove 132 in the secondary 
positioning member 110 is aligned with the unclamping member 146. Then, 
the cylinder 147 is activated to advance the unclamping member 147 into 
the groove 132, for pivoting the clamp lever 134 to unclamp the secondary 
positioning member 110 with respect to the guide rail 108, and for holding 
the secondary positioning member fixed in position in the X-axis 
direction. In this condition, the X-axis slide 78 is moved along the X 
axis to move the secondary positioning member 110 relative to the guide 
rail 108, i.e., relative to the support plate 10, for example, to the 
position indicated in two-dot chain line in FIG. 2, which corresponds to 
the X-axis dimension of the small substrate 154 previously indicated. 
Then, the unclamping member 146 is retracted for disengagement thereof 
from the groove 132 in the block 126, whereby the secondary positioning 
member 110 is again clamped to the guide rail 108 by the clamp lever 134. 
Thus, the secondary positioning member 110 is fixed in position in the 
X-axis direction, with respect to the support plate 10. As is apparent 
from the foregoing description, the unclamping member 146 serves as a 
fourth engagement member which is fixed in position in the X-axis 
direction and which engages the groove 132 to hold the secondary 
positioning member 110 fixed in the X-axis direction. Meanwhile, the block 
126 having the groove 132 serves as a third engagement member engageable 
with the fourth engagement member 146. Further, the cylinder 147 for 
operating the unclamping member 146 in the Y-axis direction serves as a 
third driving device for moving the third and fourth engagement members 
relative to each other along the Y axis, to effect engagement of the third 
and fourth engagement members, for holding the secondary positioning 
member 110 fixed in the X-axis direction. 
According to the illustrated embodiment of the substrate positioning 
apparatus of the invention, the Y-axis position of the movable guide 18 
(Y-axis positioning member) and the X-axis position of the secondary 
positioning member (X-axis positioning member) can be changed to meet 
various sizes of a substrate to be handled, by utilizing accurate 
positioning capability of the NC table 72 the X and Y movements of which 
are precisely controlled by a numerical control unit. Therefore, the 
movable guide 18 and the secondary positioning member 110 can be 
positioned more rapidly and precisely, than the corresponding components 
in the conventional apparatus wherein the positioning of those components 
is made by the operator, directly by hand or by operating a screw-and-nut 
feed system or other mechanical means. Further, the movable guide 18 and 
the positioning member 110 can be operated in an automatic fashion, 
without an expensive additional drive unit for accurate positioning. Thus, 
the present substrate positioning system is accurate and efficient in 
operation, simple in construction, and available at a reduced cost. 
Furthermore, the movable guide 18 and the secondary positioning member 110, 
which are movable relative to the support plate 10, can be clamped by the 
clamp levers 52 and the clamp lever 134, respectively, such that they are 
normally fixed in psotion in the Y-axis and X-axis directions, 
respectively. Therefore, the positions of the movable guide 18 and the 
secondary positioning member 110 relative to the support plate 10 will not 
be changed during movements of the NC table 72 for positioning the 
substrate in drilling holes therein or placing chips thereon. This means 
improved accuracy of positioning of the substrate. Since the clamp levers 
52, 134 are automatically operated by the extensions 68, 68 and the 
unclamping member 146 into their unclamp position prior to changing the 
positions of the movable guide 18 and the secondary positioning member 
110, it is not necessary to manually unclamp the movable brackets 16, 16 
and the secondary positioning member 110. Namely, there is no possibility 
that these members 16, 16, 110 are left in their clamp position when they 
are moved relative to the support plate 10. Further, the unclamping 
members 68, 68 and 146 also serve as engagement members for holding the 
movable guide 18 (brackets 16, 16) and the secondary positioning member 
110 at the predetermined Y-axis and X-axis positions, respectively, as 
previously described. Hence, the construction of the apparatus is further 
simplified. 
In connection with the constructional simplicity of the instant substrate 
positioning apparatus, it is further noted that the driving device 
comprising the cylinder 96 and the spring 92 for operating the support 
plate 10 between its upper and lower positions is not provided exclusively 
for engagement of the engagement grooves 64, 64 with the extensions 68, 
68. In other words, this driving device is absolutely necessary for 
elevating and lowering the support plate 10 for engagement and 
disengagement of the positioning pins 114, 128 with repsect to the 
positioning holes in the substrate, when the substrate is supplied to or 
discharged from the support plate 10 by means of the feed-in and feed-out 
devices 34, 36. In this sense, the engagement and disengagement of the 
engagement grooves 64 with respect to the extensions 68, 68 do not require 
an exclusive driving device, which would complicate the positioning 
apparatus. 
While the present invention has been described in detail in its preferred 
embodiment referring to the drawings, it is to be understood that the 
invention may be otherwise embodied. 
For example, while the illustrated embodiment is adapted to accurately 
position the substrate by both of the primary and second positioning 
members 106, 110 and to change the X-axis position of the secondary 
positioning member 110 to suit the size of the substrate, it is possible 
that the secondary positioning member is disposed near and in fixed 
relation with the right-hand side movable bracket 16 (in FIG. 2) so that 
the secondary positioning member may be moved in the Y-axis direction 
together with the movable brackets 16, that is, the Y-axis position of the 
secondary positioning member may be changed simultaneously when the 
position of the movable guide 18 is changed. Further, in the case where 
the Y-axis positioning of the substrate by the stationary and movable 
guides 14, 18 is sufficiently high, it is possible that the X-axis 
position of the substrate is established by using only one of the primary 
and secondary positioning members (X-axis positioning member). 
Although the primary and second positioning members 106, 110 of the 
illustrated embodiment are disposed on the Y-axis slide 82 and their 
positioning pins 114, 128 are inserted into the positioning holes in the 
substrate to position the substrate in the X-axis direction as well as in 
the Y-axis direction, it is possible that the X-axis positioning of the 
substrate is effected by other suitable arrangements such as an X-axis 
positioning member which is adapted to abut on the side of the substrate 
parallel to the Y-axis. Further, the positioning members 106, 110 may be 
disposed on the support plate 10 or on the movable and stationary guides 
14, 18, if the positioning pins 114, 128 are operated between their upper 
and lower positions by suitable cylinders, or if the substrate is placed 
on the support plate 10 after the substrate is once positioned above the 
support plate 10. 
In the illustrated embodiment, the extensions 68, 68 of the engagement 
member 66 serves not only as the second engagement member engageable with 
the first engagement member 16, 16 for holding the movable guide 18 at a 
fixed Y-axis position, but also as the unclamping member for bringing the 
clamp levers 52 into their unclamp position. However, it is possible that 
the second engagement member and the unclamping member are provided as 
separate members. Similarly, the unclamping member 146 may be replaced by 
two separate members which serve, respectively, as the fourth engagement 
member for holding the secondary positioning member 110 at a fixed X-axis 
position, and as the unclamping member for bringing the clamp lever 134 to 
its unclamp position. 
Although the illustrated embodiment uses the clamp levers 52, 134 for 
clamping the movable brackets 16, 16 and the secondary positioning member 
110, it is possible to use other clamping means such as air cylinders. 
Further, such clamping means may be eliminated, if the frictio force 
between the movable brackets 16, 16 and the support plate 10, or between 
the secondary positioning member 110 and the guide rail 108, is so large 
that the brackets 16, 16 or the secondary positioning member are (is) not 
slidably movable relative to the support plate 10 or the guide rail 108. 
Further, the engagement member 66 may be adapted to be movable in the 
vertical direction for effecting engagement of its extensions 68, 68 with 
the grooves 64, 64 in the movable brackets, rather than the support plate 
10 is moved from its lower position to its upper position for the same 
purpose. Further, the unclamping member 146 as the fourth engagement 
member engageable with the groove 132 of the secondary positioning member, 
may be fixed in the Y-axis as well as in the X-axis direction. In this 
case, the engagement of the engagement member 146 with the groove 132 may 
be attained by moving the Y-axis slide 82 in the Y-axis direction. 
Although the illustrated positioning apparatus is loaded and unloaded by 
means of the feed-in and feed-out devices 34, 36 of belt-conveyer type, in 
combination with loading and unload devices for transferring the substrate 
to and from the positioning apparatus, this conveyor and loading/unloading 
system may be replaced by other suitable systems. Furthermore, the 
automatic loading and unloading operations of the substrates by the loader 
and unloader arrangement may be replaced by manual loading and unloading 
operations by the operator who changes the substrate on the support plate 
10, from one to another. In this instance, it is not necessary that the 
substrate holder for supporting the substrate on the support plate 10 be 
capable of guiding the substrate in the X-axis direction, like the 
substrate holder provided in the illustrated embodiment in the form of the 
stationary and movable guides 14, 18. Instead, the substrate holder is 
required merely to position the substrate in the Y axis direction by 
engagement thereof with the two sides of the substrate parallel to the X 
axis, before the substrate is held by the substrate holder. 
It will be obvious that the present invention may be embodied with various 
other changes, modifications and improvements which may occur to those 
skilled in the art, without departing from the spirit of the invention.