Pin lock

Abstract
A fastening mechanism comprising a pin having a shank coupled to the head at a first end of said shank. A metallic pin-lock is provided having a base portion coupled to a resilient pin-engaging portion. The shank has a circumferentially-formed notch at a second end, said notch being adapted to receive the resilient pin-engaging portion. A resilient member is coupled to the base portion of the metallic pin-lock and to a mobile phone housing. A retainer is provided for housing said fastening mechanism inside the mobile phone housing. Upon insertion of the pin into the pin-lock, the pin is adapted to move the resilient pin-engaging portion a predetermined distance until the resilient pin-engaging portion engages the circumferentially-formed notch. The pin-lock is adapted to be removed from the pin via a magnet attracting at least a portion of the pin-lock away from the pin.
Description




TECHNICAL FIELD




The present invention relates in general to a mobile phone interlocking mechanism, and in particular but not by way of limitation, to a pin interlocking mechanism that is adapted to release upon application of a magnet thereon.




BACKGROUND OF THE INVENTION




A mobile phone typically has a housing surrounding electronic components, including a battery and other electronic components therein. In some mobile phone applications, the battery may be externally coupled to the mobile phone housing. The housing, which is typically made of a plastic or thermoplastic material, may consist of multiple components that are typically coupled together using screws, which are threaded, or snaps. In mobile phone applications where the battery is externally located from the mobile phone housing, a battery lock is provided at one end of the battery to couple the battery to the mobile phone housing. To open the mobile phone housing, threaded screws may be removed by a screwdriver and the like.




Because prior art fastening mechanisms, such as those used in the mobile phone industry, are typically small relative to the housing which is being fastened, the fasteners tend to come loose. The threads in the housing are also prone to wear, and typically fail to function after several uses. Those housings which may be snap-fitted together are typically designed for permanent fastening. Accordingly, when these snap-fits are released through the use of specially designed tools, the phone housing will not be in condition for re-assembly. The special tools utilized also are known to damage the housing of the mobile phone, thus making the separation of the housing components costly and undesirable.




SUMMARY OF THE INVENTION




To solve these problems and other problems of the prior art, a fastening mechanism for mobile phones is provided. The fastening mechanism may include a pin having a substantially-cylindrical shaped head. A shank is coupled to the substantially-cylindrical shaped end at a first end of the shank. A locking portion is provided on the shank proximal to a second end of the shank.




A pin-engaging mechanism and a base are provided to engage the locking portion of the shank and secure the fastening mechanism in a fixed relationship. A resilient member, such as a spring, may be provided coupled to the base to allow some flexibility in the interlocking relationship between the pin and the pin-engaging mechanism. The resilient member is preferably constructed of a metallic material adapted to be influenced by a magnet externally applied thereto.




Accordingly, two mobile phone housing components may be coupled together through the use of the pin and the pin-engaging member. The pin may fit through a pre-designed orifice in a first housing component and couple with the pin-engaging mechanism, which is coupled to the second housing component, and fixedly secure the first and second housing components.




To disconnect the housing components, a magnet may be applied to the base to pull the base away from the pin. The force provided by the magnet may tilt the base and the pin-engaging mechanism away from the pin, and thereby disconnect the pin-engaging mechanism from the pin.




The pin may be hidden inside one of the housing components, thereby removing the interconnection components from visibility by a user of the product. However, should aesthetics require visibility of the pin, the pin may be coupled to an external surface of the first housing prior to coupling with the second housing.











BRIEF DESCRIPTION OF THE DRAWINGS




A more complete understanding of the method and apparatus of the present invention may be obtained by reference to the following Detailed Description when taken in conjunction with the accompanying Drawings wherein:





FIG. 1

is an exploded view of one embodiment of the pin lock mechanism according to the principles of the present invention;





FIG. 2

is an exploded view of a second embodiment of the pin lock mechanism according to the principles of the present invention;





FIG. 3

is an isometric view of a pin-engaging mechanism housing according to one embodiment of the present invention;





FIG. 4A

is a top plan view of a pin-engaging mechanism and base according to one embodiment of the present invention;





FIG. 4B

is a side plan view of the pin-engaging mechanism and base of

FIG. 4A

coupled to a resilient member;





FIG. 4C

is a top plan view of a pin-engaging mechanism and base according to an alternate embodiment of the present invention;





FIG. 5

is a side plan view of the pin according to one embodiment of the present invention;





FIG. 6

is an alternate embodiment of the resilient member shown in

FIG. 4A

;





FIG. 7

is a side plan view of the pin-engaging mechanism coupled to a pin and a resilient member as located in an exemplary pin-engaging mechanism housing;





FIG. 8

is a side plan view of the pin-engaging mechanism in a fixed position relative to an external member during decoupling of the pin from the pin-engaging mechanism; and





FIG. 9

is a side plan view of an alternate embodiment of the present invention in a decoupling configuration.











DETAILED DESCRIPTION




The present invention provides an economical, convenient coupling mechanism adapted to secure housing components of mobile phones. Two housing components of a mobile phone may be conveniently coupled through the use of the pin, pin-engaging mechanism and base. Decoupling the housing components may be accomplished through the application of an external magnet in the general vicinity of the base to separate the pin-engaging mechanism from the pin. The coupling and decoupling may occur many times without wear on the components. The coupling mechanism may be internally located to limit visibility thereof




Referring now to the drawings, and more particular to

FIG. 1

, an exploded view of a mobile phone housing assembly


10


is shown. The mobile phone housing assembly


10


includes a first housing portion


20


having an external surface


30


and an internal surface


40


. The first housing portion


20


may be provided with a plurality of orifices


50


for indicia, phone number locations, display locations, and the like. A second housing portion


60


adapted to mate with the first housing portion


20


is also provided. The second housing portion


60


includes an external surface


70


and an internal surface


80


.




A pin


90


couples the first housing portion


20


to the second housing portion


60


. The pin


90


may include a head


100


, which in certain embodiments may be substantially-cylindrical. A shank


110


having a first end


120


and a second end


130


is coupled to the head


100


at the first end


120


. In certain embodiments discussed in more detail below, the second end


130


may be provided with tapers


140


. Proximal to the second end


130


, a locking portion


150


is provided on the shank


110


. In this embodiment, the head


100


is adapted to fixedly secure to the first housing portion


20


and is not visible from the external surface


30


of the first housing portion


20


.




Still referring to

FIG. 1

, a pin-lock housing


160


is provided on the internal surface


80


of the second housing portion


60


. The pin-lock housing


160


includes a top surface


165


having a pin-orifice


170


thereon adapted to receive the pin


90


therethrough. Secured within the pin-lock housing


160


is a pin lock


180


. The pin lock


180


includes a pin-engaging mechanism


190


, which in certain embodiments may be a pair of substantially vertically disposed legs


200


, and a metallic base portion


210


. A resilient member


220


may be provided coupled to the base portion


210


. As shown in

FIG. 1

, the resilient member


220


is an angle


230


having a first end


240


in a first plane and a second end


250


coupled to the second housing portion


60


in a second plane.




Referring now to

FIG. 2

, a mobile phone housing assembly


300


is shown in a second embodiment. The main difference between the mobile phone housing assembly


300


and the mobile phone housing assembly


10


is that the pin


90


is coupled through the first housing portion


20


on the external surface


30


, thus making the pin


90


visible to a user.




Referring now to

FIG. 3

, an isometric view of the pin-lock housing


160


is shown. The pin-lock housing


160


defines a cavity


400


adapted to receive the pin lock


180


(

FIG. 1

) therein. In this embodiment, a first wall


410


of the pin-lock housing


160


is substantially perpendicular to the internal surface


80


(

FIG. 1

) of the second housing portion


60


(FIG.


1


), while a second wall


420


of the pin-lock housing forms an acute angle with respect to the internal surface


80


. It is contemplated that the second wall


420


may be parallel to the first wall


410


, depending on the requirements of the user. A tapered portion


430


may be provided on the pin-lock housing


160


to facilitate engagement with the pin


90


(FIG.


1


).




Referring now to

FIGS. 4A and 4B

, the pin lock


180


is shown in a top plan view and a side view, respectively. The pin lock


180


includes the pin-engaging mechanism


190


and the metallic base portion


210


. A resilient member


220


, in this case a spring, is shown coupled to the metallic base portion


210


. While any number of materials may be used for the base portion


210


, the materials must be capable of being acted upon by a magnet. Best seen in

FIG. 4B

, substantially vertically disposed legs


200


may be provided as the pin-engaging mechanism


190


. The legs


200


may terminate in a coupling portion


500


adapted to mate with the locking portion


150


of the pin


90


(FIG.


1


). The legs


200


thereby couple the pin


90


thereto upon engagement with the locking portion


150


. It can be appreciated that although the pin-engaging mechanism


190


may comprise multiple flanges


195


and is shown as two components, a single component


197


as shown in

FIG. 4C

may be used with at least equal efficiency.




Referring now to

FIG. 5

, an enlarged side plan view of the pin


90


according to one embodiment of the present invention is shown. The locking portion


150


is seen as a reduction in diameter of the shank


110


, and is proximally located near the second end


130


of the pin


90


. Tapers


140


are provided at about the second end


130


to facilitate engagement with the pin-engaging mechanism


190


(FIGS.


4


A and


4


B). The tapers


140


help bias the pin-engaging mechanism


190


away from the shank


110


until the pin-engaging mechanism


190


meets the locking portion


150


, wherein the pin


90


becomes locked or coupled to the pin-engaging mechanism


190


. The pin head


100


may be cylindrical, substantially cylindrical, rectangular or any other shape, depending on the requirements of the user.




Referring now to

FIG. 6

, an enlarged side view of the resilient member


220


is shown as an angle having first end


240


in a first plane and second end


250


, which is preferably coupled to the second housing portion


60


(

FIG. 1

) in a second plane. The angle of the first end


240


with respect to the second end


250


is preferably acute. The resilient member may also be metallic, such that application of a magnet on the second end


250


will move the first end


240


towards the second end


250


. The resilient member


220


may be a spring, a spring-damper combination, or any other resilient structure capable of deformation to interlock with the pin


90


, yet capable of releasing the pin


90


after application of a magnet thereto.




Referring now to

FIG. 7

, a side plan view of the pin-engaging mechanism


190


coupled to a pin


90


and one embodiment of a resilient member


700


as located in an exemplary pin-engaging mechanism housing


710


is shown. As seen in this embodiment, coupling portion


500


of pin-engaging mechanism


190


mates with locking portion


150


of pin


90


to couple the pin thereto. Resilient member


700


is seen in an extended position, but may contract as well, thus providing flexibility in the connection between the pin


90


and pin-engaging mechanism


190


.




Referring now to

FIG. 8

, there is shown a side plan view of the pin-engaging mechanism


190


in a separation configuration relative to the pin


90


during decoupling of the pin


90


from the pin-engaging mechanism


190


. As can be seen, a magnet


800


is applied to the pin-engaging mechanism housing


710


and attracts the pin-engaging mechanism


190


in the direction of the magnetic force. The force is strong enough to separate the pin


90


from the pin-engaging mechanism


190


, which allows the pin


90


to separate from the pin-engaging mechanism


190


. Because the resilient member


700


may be metallic, the resilient member


700


may also be attracted by the magentic force of the magnet


800


. This feature thus allows quick coupling and decoupling of external components described above.




Referring now to

FIG. 9

, there is shown a side plan view of a pin lock


900


in an alternate separation configuration embodiment. In this embodiment, different non-metallic materials, such as thermoplastics and the like, may be used to construct a pin lock


910


or a pin engaging mechanism


930


, thereby eliminating the dependency of the decoupling of the pin


920


and the pin lock


910


on a magnet (not shown). The pin lock


910


is shown in a similar configuration as pin lock


180


, and one or more pin-engaging mechanisms


930


may be included. As in prior embodiments, a pin lock housing


940


is adapted to receive the pin lock


910


and pin


950


. The pin


950


may be adapted to mate with the pin-engaging mechanism


930


in manner similar to that described above. Optionally, a resilient member


960


is shown coupled to the pin lock


910


and the pin lock housing


940


.




In this embodiment, the pin lock housing


940


is designed to resist sufficient force, such that in order to decouple pin


950


from the pin lock


910


, a first force F


1


is applied in the direction indicated in

FIG. 9. A

resistive force in the direction indicated by F


2


naturally occurs between the-pin lock


910


and the pin


950


. Supplementing this resistive force F


2


, the pin lock housing wall


950


will contact the pin lock


910


, which will create force F


3


, and resist force F


1


in the same direction as F


2


. Finally and optionally, the resilient member


960


will provide force F


4


to resist F


1


and aid in the decoupling of the pin lock


910


from the pin


950


. It can be appreciated that instead of the resilient member


960


, an alternate coupling means may be provided to couple the pin lock


910


to the pin lock housing


940


. Accordingly, the interaction between the pin lock housing wall


950


, the pin lock


910


, the optional resilient member


960


and the pin


950


will provide sufficient decoupling force to remove the pin


950


from the pin lock


910


.




The previous description is of a preferred embodiment for implementing the invention, and the scope of the invention should not necessarily be limited by this description. The scope of the present invention is instead defined by the following claims.



Claims
  • 1. A fastening mechanism, comprising:a pin having a head; a shank coupled to said head at a first end of said shank; a metallic pin-lock having a base portion coupled to a resilient pin-engaging portion; said shank having a circumferentially-formed notch at a second end, said notch being adapted to receive said resilient pin-engaging portion; a spring coupled to said base portion of said metallic pin-lock and to a mobile phone housing; a retainer housing said fastening mechanism; wherein, upon insertion of said pin into said pin-lock, said pin is adapted to move said resilient pin-engaging portion a predetermined distance until said resilient pin-engaging portion engages said circumferentially-formed notch; and wherein said pin-lock is adapted to be removed from said pin via a magnet attracting at least a portion of said pin-lock away from said pin.
  • 2. The fastening mechanism of claim 1, wherein said pin-engaging portion comprises a plurality of legs, each leg terminating at a pin interlocking portion.
  • 3. The fastening mechanism of claim 1, wherein said retainer housing is a mobile phone housing.
  • 4. The fastening mechanism of claim 1, wherein said resilient pin-engaging portion is a spring.
  • 5. The fastening mechanism of claim 1, wherein said resilient pin-engaging portion is comprised of an angle, said base being coupled to said angle disposing said base at an acute angle relative to a mobile phone housing.
  • 6. A fastening mechainsm, comprising:a pin having a head; a shank coupled to said head at a first end of said shank; a non-metallic pin-lock having a base portion coupled to a resilient pin-engaging portion; said shank having a circumferentially-formed notch at a second end, said notch being adapted to receive said resilient pin-engaging portion; a coupling member coupled to said base portion of said non-metallic pin-lock and to a mobile phone housing; a retainer housing said fastening mechanism; wherein, upon insertion of said pin into said pin-lock, said pin is adapted to move said resilient pin-engaging portion a predetermined distance until said resilient pin-engaging portion engages said circumferentially-formed notch; and wherein said pin-lock is adapted to be removed from said pin via interaction between a first pre-determined force between said pin and said pin lock, a second predetermined force between said pin lock and said retainer, said retainer being adapted to resist said first predetermined force, a third predetermined force between said retainer and said pin lock, and a fourth predetermined force between said coupling member and said retainer.
  • 7. The fastening mechanism of claim 6, wherein said resilient pin-engaging portion is metallic.
  • 8. The fastening mechanism of claim 6, wherein said pin-engaging portion is comprised of a plurality of legs are disposed at an acute angle relative to said base.
RELATED APPLICATION(S)

This patent application claims the benefit of priority from, and incorporates by reference the entire disclosure of, U.S. Provisional Patent Application Serial No. 60/355,308, which was filed on Feb. 7, 2002.

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Number Name Date Kind
444019 Damvig Jan 1891 A
863543 Lomax Aug 1907 A
1964847 Engler et al. Jul 1934 A
3210820 Humiston Oct 1965 A
3449802 Mackey Jun 1969 A
4040148 Fukumoto Aug 1977 A
4745664 Damvig May 1988 A
5061112 Monford, Jr. Oct 1991 A
5600977 Piron Feb 1997 A
5704100 Swan Jan 1998 A
5917907 Kela Jun 1999 A
6059156 Lehtinen May 2000 A
Provisional Applications (1)
Number Date Country
60/355308 Feb 2002 US