This application claims the benefits of Taiwan application Serial No. 110149382, filed Dec. 29, 2021, the disclosures of which are incorporated by references herein in its entirety.
The invention relates to a carrier, and more particularly to a micro DUT (device under test) carrier.
While in manufacturing a micro element such as an edge-emitting laser diode, a testing is usually performed thereupon under different surroundings including, for example, a high-temperature environment and a low-temperature environment. The testing may involve plural micro elements, and may include an electricity test, an energy test, an optical test and so on.
Referring to
Nevertheless, the conventional micro DUT carrier PA1 is provided with a vacuum hole PAH1 for vacuuming thereon the micro DUTs U1, U2. While the probes retrieve from the corresponding micro DUTs U1, U2, the micro DUTs U1, U2 would be lifted and dropped therewith. Possibly, due that the retrieving probes would temporarily drag the micro DUTs U1, U2 therealong, the dragged micro DUTs U1, U2 might be pulled off the micro DUT carrier PAL In addition, since sizes of the micro DUTs U1, U2 are too small to be accurately positioned, thus a need for improving the aforesaid carrier structure is always there.
In view that the retrieving of the probes may dislocate the micro DUTs in the art, and from which various shortcomings such as dropping off and ill positions may be inevitable, accordingly it is an object of the present invention to provide a micro DUT carrier for resolving at least one of those shortcomings in the art.
In this invention, a micro DUT carrier is applied for bearing a plurality of micro DUTs and allowing the plurality of micro DUTs to be energized individually by a plurality of probes so as to generate a plurality of light beams. The micro DUT carrier includes a carrier main body, a pusher and a spring. The carrier main body includes a plurality of bearing stages separated to each other and arranged in an extension direction. Each of the plurality of bearing stages is configured for bearing one of the plurality of micro DUTs. The pusher, disposed at the carrier main body and controlled to move in the extension direction from a locking position to an opening position, includes a pusher main body and a plurality of locking elements. The pusher main body is extended in the extension direction. Each of the plurality of locking elements is extended from the pusher main body in a restraint direction substantially perpendicular to the extension direction, and is disposed in a gap between adjacent two of the plurality of bearing stages. Also, each of the plurality of locking elements has a protrusive portion extending backward with respect to the extension direction. While in the locking position, each of the plurality of micro DUTs is restrained correspondingly at each of the plurality of bearing stages. The spring is disposed between the carrier main body and the pusher. After the pusher is controlled to be pushed to the opening position for disposing the plurality of micro DUTs, the spring provides elastic resilience to send the pusher back to the locking position so as to have the plurality of locking elements to restrain correspondingly the plurality of micro DUTs.
In one embodiment of the present invention, each of the plurality of bearing stages further includes a bearing portion and a restraint portion. The bearing portion has a bearing plane for bearing one of the plurality of micro DUTs. The restraint portion is connected with the bearing portion to form a restraint plane for contacting against each of the plurality of micro DUTs.
In one embodiment of the present invention, each of the plurality of bearing stages further includes a positioning portion disposed on the bearing plane of the bearing portion, separated from the restraint portion, and configured to auxiliarily limit each of the plurality of micro DUTs.
In one embodiment of the present invention, each of the plurality of bearing stages further includes a positioning portion disposed on the bearing plane of the bearing portion, connected with the restraint plane of the restraint portion, and configured to auxiliarily limit each of the plurality of micro DUTs.
In one embodiment of the present invention, each of the plurality of locking elements further includes an extension portion extended in the restraint direction from the pusher main body and connected with the protrusive portion.
In one embodiment of the present invention, the protrusive portion is furnished with a top cutout configured for allowing one of the plurality of probes to enter and then touch electrically corresponding one of the plurality of micro DUTs.
In one embodiment of the present invention, the protrusive portion is furnished with a lateral cutout configured to pass therethrough the plurality of light beams upon when the corresponding one of the plurality of micro DUTs is energized by the one of the plurality of probes.
In one embodiment of the present invention, the extension portion has an extended positioning wall for contacting against the corresponding one of the plurality of micro DUTs upon when the pusher is moved back to the locking position.
In one embodiment of the present invention, the protrusive portion has an overhead restraint protrusion for contacting against the corresponding one of the plurality of micro DUTs upon when the pusher is moved back to the locking position.
In one embodiment of the present invention, each of the plurality of bearing stages is furnished with a vacuum hole for auxiliarily sucking one of the plurality of micro DUTs.
As stated above, the present invention utilizes the carrier main body, the pusher and the spring to bear a plurality of micro DUTs, and allows the micro DUTs to be individually energized by a plurality of probes so as to generate a plurality of laser or light beams. In comparison to the prior art, the present invention utilizes the pusher to be controllably moved between the locking position and the opening position. While in the opening position, the carrier main body can be ready to bear the micro DUTs. The elastic resilience of the spring is utilized to send the pusher back to the locking position. Upon such an arrangement, the locking elements can be applied to restrain the micro DUTs on the corresponding bearing stages, and thus the conventional shortcomings in dropping the micro DUTs while the probes are retrieved can be resolved. In addition, in the present invention, the restraint plane of the restraint portion provides a further moving limitation to the micro DUTs in another direction. Further, the present invention further provides the positioning portion to contribute one more moving limitation to the micro DUTs in a further direction. Thus, beside the aforesaid directional moving limitations provided by the present invention, the positioning accuracy of the micro DUTs can be substantially enhanced. Furthermore, the conventional vacuum holes are also provided in the present invention for vacuuming the corresponding micro DUTs auxiliarily in both positioning and moving limitations.
All these objects are achieved by the micro DUT carrier described below.
The present invention will now be specified with reference to its preferred embodiment illustrated in the drawings, in which:
The invention disclosed herein is directed to a micro DUT carrier. In the following description, numerous details are set forth in order to provide a thorough understanding of the present invention. It will be appreciated by one skilled in the art that variations of these specific details are possible while still achieving the results of the present invention. In other instance, well-known components are not described in detail in order not to unnecessarily obscure the present invention.
Refer to
As shown in
As shown in
The pusher main body 121, extending in the extension direction D1, can undergo relative displacements with respect to the carrier main body 11. Each of the locking elements 122 is protruded from the pusher main body 121 in a restraint direction D2. Preferably, the restraint direction D2 is substantially perpendicular to the extension direction D1. As shown in
After the micro DUT U1 is rested on the corresponding bearing stage 111, the positioning portion 1113 would limit the micro DUT U1 at one direction. As shown in the figure, the positioning portion 1113 would limit the movement of the micro DUT U1 at a first direction D4. Substantially, the first direction D4 is perpendicular to both the extension direction D1 and the restraint direction D2.
The spring 13, disposed between the carrier main body 11 and the pusher 12, provides elastic resilience to push the pusher 12. Practically, while the pusher 12 is pushed to move in the extension direction D1, the spring 13 would be depressed in the extension direction D1 by the pusher 12.
The carrier main body 11 can be a unique part or a multi-piece part. In this embodiment, the carrier main body 11 is shown to be a multi-piece (two-piece) part to mount the pusher 12 and the spring 13 individually.
Then, refer to
At this time, each of the locking elements 122, disposed by closing to the corresponding bearing stage 111, is configured for locating the micro DUT U1 onto the corresponding bearing stage 111.
As shown in
As shown in
Practically, the probes P1, P2 are to contact a pad on the micro DUT U1, and thus any of the two probes P1, P2 shall be harder than the pad. As long as the testing is over, the two probes P1, P2 would be retrieved upward in the restraint direction D2 to leave the micro DUT U1. At this time, temporary adherence between the probes P1, P2 and the micro DUT U1 would lift the micro DUT U1 upward in the restraint direction D2 to leave the bearing plane A1. Then, the protrusive portion 1221 would be there to limit the upward movement of the micro DUT U1, and send the micro DUT U1 back to the bearing plane A1. Upon such an arrangement, aforesaid shortcomings in device dropping can be resolved.
In addition, as shown in
Finally, refer to
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Compared to the locking element 122 of this embodiment, the locking element 122a of this embodiment is much regularly shaped. As shown in
In addition, referring to
In summary, the present invention utilizes the carrier main body, the pusher and the spring to bear a plurality of micro DUTs, and allows the micro DUTs to be individually energized by a plurality of probes so as to generate a plurality of laser or light beams. In comparison to the prior art, the present invention utilizes the pusher to be controllably moved between the locking position and the opening position. While in the opening position, the carrier main body can be ready to bear the micro DUTs. The elastic resilience of the spring is utilized to send the pusher back to the locking position. Upon such an arrangement, the locking elements can be applied to restrain the micro DUTs on the corresponding bearing stages, and thus the conventional shortcomings in dropping the micro DUTs while the probes are retrieved can be resolved. In addition, in the present invention, the restraint plane of the restraint portion provides a further moving limitation to the micro DUTs in another direction. Further, the present invention further provides the positioning portion to contribute one more moving limitation to the micro DUTs in a further direction. Thus, beside the aforesaid directional moving limitations provided by the present invention, the positioning accuracy of the micro DUTs can be substantially enhanced. Furthermore, the conventional vacuum holes are also provided in the present invention for vacuuming the corresponding micro DUTs auxiliarily in both positioning and moving limitations.
While the present invention has been particularly shown and described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and detail may be without departing from the spirit and scope of the present invention.
Number | Date | Country | Kind |
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110149382 | Dec 2021 | TW | national |