The present invention relates to hinge assemblies and, more particularly, to a hinge assembly for foldable devices such as mobile telephones, portable computers, and so on.
With the development of wireless communication and information processing technologies, portable electronic devices such as mobile phones and personal digital assistants (PDA) are appearing in abundance, and consumers can now enjoy the full convenience of high technology anytime and anywhere.
Portable electronic devices includes several types such as bar type, flip type and folder type so as to satisfy different tastes of different people. A bar type mobile phone, since its keypad is exposed, can easily be damaged or the keypad can be pressed by mistake. A flip type mobile phone, although it was introduced to solve this problem and equipped with a flip to protect the keypad by covering it, shares another problem with the bar type mobile phone that its main body is still too long for convenient transport. Furthermore, the flip type mobile phone fails to satisfy the demand for a larger display screen required for internet access, etc. Thus, a folder type mobile phone has been introduced to shorten the length of the main body of a bar type phone or a flip type phone. However, the hinges that connect the cover and the housing can only open 150 degrees. The folder type mobile phone cannot be opened 180 degrees like a bar type mobile.
Therefore, a new hinge assembly and a portable electronic device therewith are desired in order to overcome the above-described problems.
One embodiment of the present hinge assembly includes a connecting member, two cams, two shafts and two elastic elements. The connecting member includes a first sleeve, a second sleeve and a connecting sleeve connected between the first sleeve and the second sleeve. The first sleeve and the second sleeve each have a partition board formed therein. Each partition board includes a plurality of protrusions extending therefrom with a plurality of latching grooves formed between the protrusions. Each cam has at least one latching block and defines an axial hole. Each shaft has a shaft portion. The shaft portion is structured and arranged for passing through the axial hole of each cam and rotating together with each cam. Each elastic element provides an elastic force for each cam so as to hold the cam against a corresponding partition board.
Other advantages and novel features of the present hinge assembly will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
Many aspects of the hinge assembly can be better understood with reference to the following drawings. The components in the drawings are not necessarily drawn to scale, the emphasis instead being placed upon clearly illustrating the principles of the present hinge assembly. Moreover, in the drawings, like reference numerals designate corresponding parts throughout the several views.
Referring now to the drawings in detail,
The cover 110 includes an upper cover 112 and a lower cover 114. The upper cover 112 and the lower cover 114 are each substantially a rectangular cavity with an open side, and may be clasped together so as to form the cover 110.
The upper cover 112 defines an arcuate cutout 1122 at one end thereof, which communicates the end of the upper cover 112. The upper cover 112 has a display 16 for showing information on an upper surface thereof. Adjacent to the arcuate cutout 1122, the upper cover 112 defines a receiving groove 1124 opposite to the display 116. The receiving groove 1124 is substantially semi-circular.
The lower cover 114 forms two symmetrically fixed cylinders 1142 at one end thereof. Each fixed cylinder 1142 is substantially cylindrical, and the two fixed cylinders 1142 are positioned opposite to each other. One of the fixed cylinders 1142 defines a reverse rotating groove 1144 with non-circular shape. The other of the fixed cylinders 1142 defines a rotating groove 1146 with a circular shape. A rectangular cavity 1140 is defined between the two fixed cylinders 1142. An arcuate groove 1148 is defined at one end of the lower cover 114, and communicates the cavity 1140.
The housing 120 includes an upper housing 122 and a lower housing 124. The upper housing 122 and the lower housing 124 are respectively substantially a rectangular cavity with an open side, and may be clasped each other so as to form the housing 120. The upper housing 122 has a keypad 126 for inputting information.
The upper housing 122 defines an arcuate cutout 1222 at one end thereof, which communicates with the end of the upper housing 122. Adjacent to the arcuate cutout 1222, the upper housing 122 defines a receiving groove 1224 opposite to the keypad 126. The receiving groove 1224 is substantially semi-circular.
The lower housing 124 defines two symmetrically fixed cylinders 1242 at one end thereof. The cylinders 1242 are substantially cylindrical, and are positioned opposite to each other for engaging in the receiving groove 1224. One of the fixed cylinders 1242 defines a reverse rotating groove 1244 with non-circular shape. The other of the fixed cylinders 1242 defines a rotating groove 1246 with a circular shape. A rectangular cavity 1240 is defined between the two fixed cylinders 1242. An arcuate groove 1248 is defined at one end of the lower housing 124, and communicates with the cavity 1240.
Referring to
Referring also to
The first sleeve 12 is substantially a hollow cylinder. A partition board 104 is positioned in a middle of the first sleeve 12, thereby dividing the first sleeve 12 into two parts. The first sleeve 12 has a circular end for rotatably engaging in the rotating groove 1146. A limiting block 102 is formed in an inner peripheral wall of the first sleeve 12, and extends from an opposite end to the partition board 104 along an axis of the first sleeve 12. The partition board 104 forms two symmetrically opposite first protrusions 1020 and two symmetrically opposite second protrusions 1022. The first protrusions 1020 and the second protrusions 1022 are located around a periphery of the partition board 104, and intersect with the peripheral wall of the first sleeve 12. Each first protrusion 1020 and each second protrusion 1022 is substantially trapeziform in shape. A latching groove 1024 is defined between each first protrusion 1020 and each second protrusion 1022. An axial hole 108 is defined in a middle of the partition board 104.
The second sleeve 14 is substantially a hollow cylinder. The structure of the second sleeve 14 is similar to that of the first sleeve 12. A partition board 144 is positioned in a middle of the second sleeve 14, thereby dividing the second sleeve 14 into two parts. The second sleeve 14 has a circular end for rotatably engaging in the rotating groove 1246. A limiting block 142 is formed in an inner peripheral wall of the second sleeve 14, and extends from an opposite end to the partition board 144 along an axis of the second sleeve 14. The partition board 144 forms two symmetrically opposite third protrusions 1040 and two symmetrically opposite fourth protrusions 1042. The third protrusions 1040 and the fourth protrusions 1042 are located around a periphery of the partition board 144, and intersect with the peripheral wall of the second sleeve 14. Each third protrusion 1040 and each fourth protrusion 1042 is substantially trapeziform in shape. A latching groove 1044 is defined between each third protrusion 1040 and each fourth protrusion 1042. An axial hole 148 is defined in a middle of the partition board 144.
The height of the first protrusions 1020, the second protrusions 1022, the third protrusions 1040 and the fourth protrusions 1044 are respectively defined as “H1”, “H2”, “H3”, “H4”. “H1”, “H2”, “H3” and “H4” are related by the equation:
H4=H1>H2>H3.
The connecting sleeve 16 is substantially hollow cylinder, and perpendicularly communicates the first sleeve 12 and the second sleeve 14 and vice-versa. The first sleeve 12 and the second sleeve 14 respectively define a wire groove 17, 18 adjacent to a corresponding partition board 104, 144. The wire grooves 17 and 18 are used as a passage allowing wires to connect the cover 110 and the housing 120.
Each shaft 20 includes a flange portion 22 and a shaft portion 24. The flange portion 22 is substantially disk-like in shape, and is positioned at one end of the shaft portion 24. The shaft portion 24 is a deformable shaft structure, and is formed by cutting two flat surfaces. One end of the shaft portion 24 opposite to the flange portion 22 defines a fixed hole 26.
Referring also to
Each spring 40 is a cylindrical spring. An inner diameter of each spring 40 is larger than an outer diameter of each shaft portion 24, thereby allowing each spring 40 to be placed around a corresponding shaft portion 24 of each shaft 20.
Referring also to
In assembly, referring to
The assembled hinge assembly 200 is assembled into the foldable electronic device 100. Firstly, the lower cover 114 is positioned opposite to the lower housing 124, with the fixed cylinder 1142 opposite to the fixed cylinder 1242. Next, the first sleeve 12 of the hinge assembly 200 is received in the cavity 1140 of the lower cover 114, and the second sleeve 14 is received in the cavity 1240 of the lower housing 124. The two ends of the connecting sleeve 16 respectively engage in corresponding arcuate grooves 1148, 1248 so as to connect the lower cover 114 and the lower housing 124. At the same time, the fixed portion 54 of each barrels 50 engages in a given reverse rotating groove 1144 or 1244, and the circular ends of the first sleeve 12 and the second sleeve 14 are respectively received in their corresponding rotating grooves 1146, 1246. After that, printed circuit boards are received in the foldable electronic device 100. Wires pass through the wire groove 17, 18 of the connecting member 10 so as to electronically connect the cover 110 and the housing 120. Finally, the receiving groove 1124 of the upper cover 112 receives the fixed cylinders 1142, and one end of the connecting sleeve 16 engages in the cutout 1122. Thus, the upper cover 112 covers the lower cover 114. The receiving groove 1224 of the upper housing 122 receives the fixed cylinders 1242, and the other end of the connecting sleeve 16 engages in the cutout 1222. Thus, the upper housing 122 covers the lower housing 124. Accordingly, the assembled process of the foldable electronic device 100 is finished.
Referring to
If the cover 180 is opened to 180 degrees, referring to
The principles of the closing process are basically the same as the cover 110 of the foldable electronic device 100 is opened. Thus, the closing process is not detailed.
In an alternative embodiment, the receiving hole 522 of the barrel 50 may be omitted. Accordingly, the spring 40 directly resists an end wall of the barrel 50.
In an alternative embodiment, the first protrusion 1020, the second protrusion 1022, the third protrusion 120 and the fourth protrusion 122 are not limited to being trapeziform in shape. Alternatively, the configuration may be replaced by concave and convex surfaces. The latching blocks 32 may also be replaced by other structures.
In an alternative embodiment, the height of the first protrusion 1020, the second protrusion 1022, the third protrusion 1040 and the fourth protrusion 1042 are not limited to the above relationship. Alternatively, the height of the first protrusion 1020 can be reversed to the second protrusion 1022. Then, the housing 120 is firstly opened to an angle of 90 degrees relative to the cover 110, and the cover 110 is further opened to an angle of 90 degrees relative to the housing 120.
Understandably, the connecting member may includes a first connecting portion configured so as to be rotatably received in the housing, a second connecting portion configured so as to be rotatably received in the cover, and a third connecting portion connecting the first connecting portion with the second connecting portion in a manner such that the first connecting portion and the second connecting portion are non-removable relative to each other. The first connecting portion and the second connecting portion respectively define a first rotation axis and a second rotation axis that are parallel to each other. A first rotation limiting unit is configured so as to be engaged between the first connecting portion and the housing in a manner so as to limit the housing to rotate within a first predetermined angle relative to the first rotating axis. A second rotation limiting unit is configured so as to be engaged between the second connecting portion and the cover in a manner so as to limit the cover to rotate within a second predetermined angle relative to the second rotating axis.
As described above, the hinge assembly 200 may be opened to an angle of 90 degrees so as to view the information on the display 116. Moreover, the foldable electronic device 100 may be also opened to an angle of 180 degrees. Accordingly, the foldable electronic device 100 is like a bar type mobile phone when opened. Therefore, the foldable electronic device combines the advantages of the bar type mobile phone and the foldable type mobile phone. Understandably, the angle of 90 degrees may be variable, and be replaced by other angles.
It is believed that the present 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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200510101035.5 | Nov 2005 | CN | national |