BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is an isometric view of the entire high speed tray transfer system.
FIG. 2 is an isometric view of the tray loader.
FIG. 3
a is an isometric view showing the vertical tray mover.
FIG. 3
b is a different angle isometric view of FIG. 3.
FIG. 4 is an isometric view of the two vertical tray movers attached to their respective horizontal tray movers.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 illustrates the invention. It comprises a tray loader 1, two independent horizontal mover assemblies 2, two independent vertical tray mover assemblies 3 with platens 31, a tray unloader (not shown), and an electronic controller for controlling the operation of each assembly (not shown).
The tray loader 1 can hold a stack of trays, and lower the bottom tray onto a platen one at a time. The stack of trays are placed within four vertical bars 10 that are positioned to capture the corners of the trays. The stack of trays are supported on the bottom by four tray holder fingers 11.
FIG. 2 shows elevator assembly 12 which can lift the stack of trays by raising or lowering the elevator plates 13 that are connected on the bottom via a horizontal plate 17. These elevator plates straddle other components (see FIG. 1). These plates can move up or down via an electric motor 14 connected to a screw drive 15. The elevator plates are each attached to linear bearings 16. In operation, the elevator plates 13 are moved upward until they contact the bottom of the stack of trays. From this position the elevator plates move slightly higher and thus slightly raise the entire stack of trays. The tray holder fingers 11 are now retracted. Next the elevator plates 13 are moved downward by a distance approximately equal to the thickness of a tray. The tray holder fingers 11 are then extended between the lowest and second lowest tray. As the elevator plates move further down, the tray that was second from the bottom of the stack comes to rest on the tray holder fingers. In this way a single tray is removed from the bottom of the stack of trays. Then the elevator plates 11 continue to lower the tray until it rests on a platen 31 (a flat plate that a tray can rest on).
Each platen 31 is connected to a vertical tray mover assembly 3 as seen in FIGS. 3a and 3b. Once a tray is resting on the platen it is clamped in place. The tray clamps are mechanisms on the platens that hold a tray in place on the platen. In a preferred embodiment they consist of two stationary pins 32 on one end of the platen and a movable pin 33 on the other end. This movable pin is activated on demand by a solenoid 34 (FIG. 3b) or other actuator and can move toward and away from the stationary pins. The vertical tray mover is a mechanism that can move the platen, and thus the tray, vertically. It employs an electric motor 35, connected to a screw drive 36 via a pair of bevel gears to achieve the up and down motion. Linear bearings 37 guide the vertical movement.
The horizontal tray mover 2 is a mechanism that horizontally moves a vertical tray mover 3 as seen in FIG. 4. In a preferred embodiment this consists of a high-speed electric motor 31 driven screw drive 32 and linear bearing 33 with structural members that support the vertical tray mover. Activating the motor and thus turning the screw causes the horizontal tray mover to move horizontally. Bearing 33 guides the horizontal motion and bears the weight of the attached assemblies. Various alternate actuators could be used for the horizontal tray mover. The horizontal tray mover is attached to the housing of the high-speed transfer system. There are two of these assemblies in the housing; a left hand version and a right hand version. They are oriented 180 degrees rotated from each other so that the platens of each unit can pass above or below each other as they cycle through the same path in a clockwise or counter-clockwise fashion.
Precise positional information about of each horizontal tray mover is provided by encoder 34. Likewise, feedback regarding the location of each vertical tray mover is provided by encoder 38 (FIG. 3b). The elevator positional information is provided by encoder 17 (FIG. 2). These encoders allow the electronic controller to precisely position these movers. These are optical rotary encoders connected to the motor shafts. Alternatively, linear encoders could be used. Non-optical encoders could be used also.
During operation, once a tray has been placed on a platen, the horizontal mover moves the tray away from the tray loader. The tray is thus feed between horizontal rails 42 and 43 (see FIG. 1). Rail 43 is spring loaded so as to apply pressure to push the tray against rail 42. In this way the tray is laterally justified against rail 42. When the tray has moved far enough to be clear of the loader mechanisms, the vertical tray mover moves the tray upward until the top surface of the tray contacts the vertical tray limit rails 41. The servomotor on the vertical tray mover can change from position mode to torque mode. Thus the motor moves the platen vertically until it experiences a specific force against it. In this way the force exerted upon the tray can be used to flatten warped trays. Additionally, the tray location is thus justified from the top of the tray for greatest vertical positional accuracy of devices. Now the tray can be horizontally indexed underneath the pick and place by means of the horizontal tray mover. The method of tray clamping does not require any additional clamping or unclamping while this platen is providing devices to the pick and place. Therefore the index time is minimized. Meanwhile, the other platen delivers its tray to the end of the tray transfer system where a tray unloader can process it. One embodiment utilizes another instance of the tray delivery system operated in reverse and thus stacks up used trays. This now empty platen can move downward via the vertical tray mover, until it is lower than the platen that is currently servicing the pick and place. Then the platen moves back to the tray delivery system by passing underneath the other platen. The platen obtains a new tray of devices and is queued behind the platen servicing the pick and place, so that as soon as the pick and place is finished with the current tray, a tray full of new devices can be immediately delivered.
By having these mechanisms cycle around in a somewhat circular fashion, this high-speed tray transfer system is able to continuously feed trays to the pick and place without any interruption. It should be obvious that various actuators could be used and still remain within the scope of this invention. Various alternative structures could produce the same effect of having two or more platens that can pass each other. For example, if the platens tilted or pivoted they could pass each other also.