The present invention generally relates to hinge mechanisms, and more particularly to a hinge mechanism for hinging together housings of a foldable, portable electronic device such as a mobile phone or a PDA (Personal Digital Assistant).
Portable mobile phones typically have two housings rotatably joined by a type of hinge that allows the housings to fold upon one another. Many such foldable mobile phones have most of the electronics in one housing, called the main housing, and fewer electronics in the other housing, called the cover. Other such foldable mobile phones have all the electronics in the main housing, with the cover serving only to cover a keypad and a display of the main housing. The main housing and the cover are connected together by a hinge mechanism. Generally, the opening or closing of most covers is achieved by means of cams and a spring of the hinge mechanism.
However, the hinge assembly includes a variety of individual pieces that must be installed within the foldable mobile phone 100 when the foldable mobile phone 100 is assembled. This does not meet the growing trend for foldable mobile phone manufacturers to use integrated one-piece hinge assemblies that can be quickly and easily press-fitted into foldable mobile phone sub-assemblies during manufacturing. Manufacturing costs associated with non-integrated hinge assemblies are higher than those associated with one-piece hinge assemblies.
What is needed, therefore, is a hinge mechanism which is modularized, easy to install into a foldable electronic device, and low in cost.
A hinge mechanism for a foldable, portable electronic device includes a shaft, a cam, a housing, an arresting member, a cam follower, and an elastic member. The shaft has a pair of shaft ends. The cam has a cam tip. The housing has opposite housing ends. One housing end is an open housing end, and the opposite housing end is a partially open housing end. The partially open housing end includes a transverse wall and a keyed hole defined in the transverse wall. The cam follower has a cam surface arranged to movably contact the cam tip. The elastic member is provided for providing an elastic force. The cam, the cam follower, the elastic member and the arresting member surround the shaft in turn. The cam follower and the elastic member are received in the housing. The cam is disposed at the partially open housing end with the tip of the cam being received in the housing. The transverse wall of the partially open housing end prevents the cam from sliding further into the housing. The arresting member is disposed adjacent to the open housing end, whereby the arresting member can slide into the housing. The cam is rotatable relative to the shaft and non-rotatable relative to the housing, and the cam follower is slidable and non-rotatable relative to both the shaft and the arresting member and rotatable relative to the housing and rotatable relative to the housing.
The hinge mechanism is simple, easily manufactured, and relatively inexpensive. In addition, the hinge mechanism is modularized, so it is easily installed into the main housing and cover of a foldable mobile phone or other electronic device.
Other advantages and novel features will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings, in which:
Referring to
Referring also to
Referring also to
The cam 2 is column-shaped, and a cam hole 20 runs through the cam 2 along an axis thereof. A diameter of the cam hole 20 is smaller than that of the flange 12 of the shaft 1. The cam 2 includes a cylinder-shaped base 21, a pair of tips 22 symmetrically formed, and a keyed portion 23 disposed between the base 21 and the tips 22. The keyed portion 23 includes two connecting portions 28, each having a cross-section of part of a ring and each operatively linking the base 21 and one respective tip 22. Thus, the two connecting portions 28 form the keyed portion 23 having a cross-section with a contour of a symmetrically truncated circle. A fixing hole 24, coaxial with the cam hole 20, is defined in an end of the base 21. The fixing hole 24 is for receiving the flange 12 of the shaft 1. A diameter of the fixing hole 24 is larger than that of the cam hole 20.
The housing 3 is substantially a flattened cylinder, and has a first housing end 30 and an opposite second housing end 31. The housing 3 is open at the first housing end 30, and is partially open at the second housing end 31. The second housing end 31 includes a transverse wall 35 and a keyed hole 32 defined in the housing 3 and extending through in the transverse wall 35. The keyed hole 32 takes a shape of a symmetrically truncated circle, so as to matingly fit with the keyed portion 23. (It is to be understood that the mating shape of keyed portion 23 and keyed hole 32 could be any shape that would essentially eliminate any rotation therebetween.) The transverse wall 35 has a transverse inner end face 36 (shown in
The cam follower 4, received in the housing 3, is generally column-shaped. The cam follower 4 has a first follower end 40 and a counteractive portion 46 adjoining the first follower end 40. A diameter of the first follower end 40 is greater than that of the counteractive portion 46. An extremity of the counteractive portion 46 distal from the first follower end 40 is defined as a second follower end 41 of the cam follower 4. A through hole 42 is defined in the cam follower 4 along an axis thereof. A shape of the through hole 42 is the same as a cross-section of the flattened shaft portion 14 of the shaft 1. The through hole 42 has a diameter small enough to stop the cam follower 4 rotating relative to the flattened shaft portion 14, but large enough to allow the cam follower 4 to slide along the flattened shaft portion 14. A pair of opposite valleys 44 are defined on the first follower end 40. A pair of opposite peaks 45 are formed on the first follower end 40, the peaks 45 separating the valleys 44 from each other. Thus, the valleys 44 and the peaks 45 cooperatively form a cam surface 48. In the illustrated embodiment, the valleys 44 are symmetrically opposite each other, and the peaks 45 are symmetrically opposite each other.
The spring 5, which is received in the housing 3 and surrounds the shaft 1, is helical and column-shaped. One end of the spring 5 is coiled around the counteractive portion 46 of the cam follower 4, and the opposite end of the spring 5 abuts the arresting member 6.
The arresting member 6, which is engaged in the main housing 300 of the foldable mobile phone, is a polygonal prism. A through hole 62 is defined in the arresting member 6 along an axis thereof. A shape of the through hole 62 is the same as the cross-section of the flattened shaft portion 14 of the shaft 1. The through hole 62 has a diameter small enough to stop the flattened shaft portion 14 rotating relative to the arresting member 6. A pair of aligned pinholes 64 is defined in the arresting member 6. The pinholes 64 are aligned perpendicular to the through hole 62, and are for receiving the pin 7.
In assembly of the hinge mechanism 500, firstly, the flattened shaft portion 14 of the shaft 1 is passed through the cam 2, the housing 3, the cam follower 4, the spring 5, and the arresting member 6. The flange 12 of the shaft 1 is contained in the fixing hole 24. The tips 22 of the cam 2 are received in the central hole of the housing 3 at the second housing end 31, so as to form a cam surface together with the transverse inner end face 36 of the transverse wall 35 of the second housing end 31 of the housing 3. The cam follower 4 and the spring 5 are received in the central hole of the housing 3. The flattened shaft portion 14 non-rotatably engages in the through hole 42 of the cam follower 4 and the through hole 62 of the arresting member 6. The spring 5 biases the cam follower 4 and the cam 2 into engagement. The valleys 44 of the cam follower 4 receive the tips 22 of the cam 2. The pin 7 is fixed into the pinholes 64 of the arresting member 6 and the transverse hole 16 of the shaft 1, so that the hinge mechanism is assembled into a unified whole, as shown in
Referring to
In use, when the cover 400 is manually rotated up toward an open position, the housing 3 and the cam 2 rotate together with the cover 400. Because the shaft 1 and the arresting member 6 are fixed to the main housing 300, and because the cam follower 4 is non-rotatable and slidable relative to the shaft 1, the cam 2 drives the cam follower 4 to slide along the flattened shaft portion 14 of the shaft 1. In particular, the tips 22 of the cam 2 slide out of the valleys 44 of the cam follower 4, and drive the cam follower 4 to move toward the arresting member 6, simultaneously compressing the spring 5. When the tips 22 of the cam 2 reach the peaks 45 of the cam follower 4, the spring 5 is compressed to its shortest length, as shown in
In an alternative embodiment, the spring 5 can instead be another elastic member, such as a rubber element.
It is believed that the embodiments and their advantages will be understood from the foregoing description, and it will be apparent that various changes may be made thereto without departing from the spirit and scope of the invention or sacrificing all of its material advantages, the examples hereinbefore described merely being preferred or exemplary embodiments of the invention.
Number | Date | Country | Kind |
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200420093827.3 | Oct 2004 | CN | national |
This application is a Continuation-in-Part of U.S. application Ser. No. 11/227,716, filed on Sep. 15, 2005, the contents of which are hereby incorporated by reference thereto.
Number | Date | Country | |
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Parent | 11227716 | Sep 2005 | US |
Child | 11525463 | Sep 2006 | US |