The present invention relates to a module card ejecting mechanism for a module card (e.g. express card) slot.
A typical module card ejecting mechanism disclosed in U.S. Pat. No. 5,871,365 employs a push-push mechanism with a heart-shaped cam structure. Although this structure can achieve the intended effectiveness, it is somewhat complicated, relatively high in manufacturing cost and takes up a larger space.
Thus, it is necessary to provide a module card ejecting mechanism which is simplified and easy to be manufactured.
According to a preferred embodiment of the present invention, a module card ejecting mechanism comprises an ejecting plate and a push-push ejecting mechanism. The push-push ejecting mechanism comprises:
(1) a housing including a channel having a guiding section, said guiding section having a push-out engagement part and a push-in engagement part which are cross-configured along an annular direction;
(2) a pushing rod including a pilot flange and adaptable for allowing the pushing rod to slidably but non-rotatably engage with the guiding section;
(3) a rotator configured in a way that it is cyclically, alternatively engaged with the cross-configured push-out engagement part and push-in engagement part; and
(4) a spring for elastically urging against the rotator.
This module card ejecting mechanism makes use of the interactions between the rotator configuration, the pilot flange and the guiding section, thereby causing the rotator to alternatively rotate to and engage with the first rotating position or the second rotating position, so as to drive said pushing rod to move to the card-withdrawing position or the card-inserting position.
The further characteristics of the present invention can be further appreciated by the following detailed description and the description of the drawings.
a is a schematic view of the module card ejecting mechanism 1 used with a module card connector assembly C;
b illustrates an assembled state of
a is an exploded view of the module card ejecting mechanism 1;
b is a partially sectional view of the push-push ejecting mechanism 20;
a is a partially sectional view of the pushing rod 40 located at the “card-withdrawing position”;
b is a partially sectional view of the pushing rod 40 located at the “card-inserting position”; and
a and 5b are the schematic views of the module card ejecting mechanism 1 used with a dual-width module card connector assembly and a mono-width module card connector assembly.
As shown in the drawings, the module card ejecting mechanism 1 of the present invention can be used in a module card connector assembly C.
After a module card P is positioned into the card slot S of the module card connector assembly C, the module card P can be coupled to the head end H of the module card connector assembly C or can be took out therefrom by repeatedly applying a pushing force thereon.
As shown in
The ejecting plate 10 is mounted onto the head end H of the module card connector assembly C, and it can slide along the card-moving direction of the module card connector assembly C. The ejecting plate 10 includes a card contact part 12 for operational interactions with the inserting and withdrawing operations of an inserted card (e.g. a module card), and a card coupling part 14 mechanically coupled to the push-push ejecting mechanism. The card contact part 12 is associated with the coupling part 14.
The push-push ejecting mechanism 20 comprises a housing 30, a pushing rod 40, a rotator 50, and a spring 60. The end of the push-push ejecting mechanism 20 can be sealed by a separated end cap 70.
The housing 30 has an inner wall 32, which defines a channel 34 with a guiding section 36 surrounding the inner wall 32. The guiding section 36 includes a push-out engagement part and a push-in engagement part which are cross-configured along an annular direction and coupling to the rotator 50. The guiding section 36 preferably includes an annularly-configured guiding means between the push-out engagement part and a push-in engagement part, which is capable of rotating the rotator 50 and driving the same to engage with the push-out engagement part or the push-in engagement part. According to the preferred embodiments of the present invention, said push-out engagement parts are preferably in the form of a plurality of annularly-disposed elongated slots 362, wherein each elongated slot 362 is preferably formed with a stopping wall 363. The push-in engagement parts are preferably in the form of a plurality of annularly-disposed short slots 364, wherein each short slot 364 is preferably formed with a stopping wall 365. The guiding means is preferably in the form of a plurality of guiding vanes 366 configured along an annular direction, wherein each guiding vane 366 preferably comprises an inclined guiding surface 367. Each guiding vane 366 intervenes between an elongated slot 362 and an a short slot 364.
The pushing rod 40 has a free end 42 and a pilot flange 44. The pilot flange 44 may couple to the guiding section 36 in a slidable but non-rotatable way, such that the pushing rod 40 can axially, non-rotatably move in the channel 34. According to the preferred embodiments of the present invention, the pilot flange 44 is preferably formed with a plurality of annylarly-arranged convex guiding blocks 442 which can slide along the corresponding guide slots (not shown) formed on the guiding section 36, so as to allow the pushing rod 40 to axially move in the channel 34. To provide a simplified guiding section 36 structure, guide slots in the form of elongated slots 362 and short slots 364 are recommended. The pilot flange 44 is formed with a plurality of generally V-shaped, annularly-disposed guiding grooves 46, and a plurality of annularly-disposed groove tops 48, wherein the guiding grooves 46 and the groove tops 48 are cross-arranged such that each groove top 48 intervenes between two adjacent guiding grooves 46. The guiding grooves 46 and the groove tops 48 can guide the rotator 50 to rotate, as described below in details.
The rotator 50 preferably comprises a plurality of annularly-disposed ribs 52, and a plurality of annularly-arranged oblique surfaces 54. The number of ribs 52 is the same as the number of the elongated slots 362 (push-out engagement part) or the short slots 364 (push-in engagement part) of the guiding section 36, and the ribs 52 allow the rotator 50 to couple with the elongated slots 362 or short slots 364. The oblique surface 54 can slide on the guiding surface 367 of the guiding vane 366 to guide the rotator 50 to slide and rotate at the same time. The oblique surface 54 is preferably formed at the end of the rib 52.
As shown in the preferred embodiment of
Prior to use, the ribs 52 of the rotator 50 are coupled to the elongated slots 362 (push-out engagement part) and located at the first rotating position. During use, a pushing force applied to the card contact part 12 of the ejecting plate 10 can be delivered to the pushing rod 40, and therefore push the rotator 50. With the elastically biasing of the spring 60, the rotator 50 departs from the elongated slot 362 under the guidance of the pilot flange 44 of the pushing rod 40 and of the ribs 52. Once the ribs 52 depart from the elongated slots 362, the oblique surfaces 54, which originally docks to the groove top 48 on the rotator 50, correspondingly slide into the generally V-shaped guiding groove 46, so that the rotator 50 slightly rotates forward with the oblique surfaces 54 facing the guiding vanes 366 of the guiding section 36. If the pushing force is released at this time, and then the oblique surfaces 54 are pushed backward by the elastic force of the spring 60 and thus slide on the guiding surfaces 367 of the guiding vanes 366, finally engage with short slots 364 (push-in engagement part) and secured at a second rotating position. The pushing rod 40 therefore correspondingly moves into a card-inserting position (as shown in
When the rotator 50 is fixed at the second rotating position, another pushing force applied to the ejecting plate 10 (intended to push the module card P out of the head end H of the card slot S) can be delivered into the pushing rod 40 and thus push the rotator 50. The oblique surfaces 54 of the rotator 50 are pushed and ejected by the groove tops 48. Once the oblique surfaces 54 depart from the short slots 364, they slide into the generally V-shaped guiding grooves 46 on the pushing rod 40, slightly rotate the rotator 50 forward, with the oblique surfaces 54 facing another guiding vanes 366. At this time, if the pushing force is released, the oblique surfaces 54 would be pushed backward by the elastic force of the spring 60, and slide on another guiding surfaces 367 on another guiding vanes 366, and finally slide into the elongated slots 362 to go to the first rotating position again. Thus the pushing rod 40 is correspondingly pushed backward to the card-withdrawing position (as shown in
By this way, the rotator 50 makes use of the interactions between its configuration, the pilot flange and the guiding section, thereby alternatively rotating to and engage with the first rotating position or the second rotating position, so as to drive said pushing rod to move to the card-withdrawing position or the card-inserting position.
The present invention also employs a pair of module card ejecting mechanism 1 assembled on the module card connector assembly C to achieve better effects. Additionally, as shown in
Number | Date | Country | Kind |
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092137486 | Dec 2003 | TW | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SG04/00428 | 12/29/2004 | WO | 5/7/2007 |