The present invention relates to a portable device and a mechanical key.
Nowadays, automobiles use remote control devices such as smart entry devices and smart ignition devices, which employ electronic key systems. More specifically, such a remote control device includes a portable device that communicates with a transceiver, which is installed in an automobile. When a person, or driver, holding the portable device approaches the automobile, the doors of the automobile are automatically unlocked. When the driver leaves the automobile while holding the portable device, the doors automatically lock. When the driver opens the door to enter the automobile while holding the portable device, the steering lock system enters an unlock state. In this state, the starting of the engine is enabled by operating an engine switch. When the driver leaves the automobile while holding the portable device, the steering lock system enters a lock state. Accordingly, the remote control device enables operations from the unlocking of the doors to the starting of the engine without having to insert a key in a key cylinder.
Japanese Laid-Open Patent Publication No. 2000-320202 describes a typical portable device used in such a remote control system. The portable device has a case accommodating a battery, which functions as a power source, a circuit board on which ICs are mounted, and a mechanical key used during emergencies such as when battery drainage occurs. When the mechanical key is not in use, a lock member keeps the mechanical key locked to the case. During an emergency such as when battery drainage occurs, the lock member unlocks the mechanical key so that the mechanical key projects out of the case. The mechanical key is then used to unlock an automobile door or start the engine.
Due to the increasing number of functions in recent electronic key systems, the number of components in a portable device has been increasing. However, the portable device is required to be compact and portable. In the portable device described in Japanese Laid-Open Patent Publication No. 2000-320202, the lock member is necessary for keeping the mechanical key locked in the case and for projecting the lock member out of the case. This increases the number of components and hinders the miniaturization of the portable device.
The present invention provides a compact portable device and mechanical key that improve portability.
One aspect of the present invention is a portable device for communication with a vehicle. The portable device includes a main body. A mechanical key retainer is formed in the main body. A mechanical key is retainable in the mechanical key retainer. The mechanical key is inserted into the mechanical key retainer in a predetermined insertion direction. The mechanical key is removable from the mechanical key retainer when retained in the mechanical key retainer. A first engagement portion engageable with the mechanical key is formed on the mechanical key retainer. A second engagement portion engageable with the first engagement portion of the mechanical key retainer is formed on the mechanical key. The first and second engagement portions are formed to extend in a direction differing from the insertion direction of the mechanical key. One of the first and second engagement portions is a recess and the other one of the first and second engagement portions is a projection.
A further aspect of the present invention is a mechanical key for retention in a portable vehicle communication device by insertion into the portable device in a predetermined insertion direction. The mechanical key is removable when retained in the portable device. The portable device includes a portable device engagement portion. The mechanical key includes a handle. A mechanical key engagement portion is formed on the handle. The mechanical key engagement portion is engageable with the portable device engagement portion. The mechanical key engagement portion is either one of a recess and a projection and is formed to extend in a direction differing from the insertion direction of the mechanical key.
Other aspects and advantages of the present invention will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the invention.
The invention, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
A first embodiment of the present invention will now be described with reference to
The case 16 has a side wall 16a (refer to
In the handle retaining portion 29, an engagement recess 32 is formed in the side wall 29b. The engagement recess 32 extends parallel to the side wall 16a of the case 16, that is, in a direction perpendicular to the longitudinal direction of the mechanical key retainer 27. The engagement recess 32 is generally box-shaped and is located in the substantially middle part of the side wall 29b of the handle retaining portion 29.
As shown in
As shown in
As shown in
The handle base 41 is a generally square plate and formed continuously with the blade 39. Thus, the blade 39 and the handle base 41 are formed from the same plate. The handle base 41 is sized so that it can be accommodated in the handle retaining portion 29 (refer to
The handle base 41 has a thin portion 47, which extends between the second and third cutaway portions 43 and 45. The thin portion 47 is formed so that it occupies a relatively large area of the handle base 41. An elliptic hole 49 extends through the generally middle part of the thin portion 47.
Referring to
An arcuate buffer opening 51 extends through the grip 37 in a manner overlapping the third cutaway portion 45 (refer to
To accommodate the mechanical key 14 in the mechanical key retainer 27 of the case 16, the handle 52 of the mechanical key 14 is first held between fingers. Then, the mechanical key 14 is inserted into the mechanical key retainer 27 from the blade 39 of the key plate 35. The blade 39 and the handle 52 of the mechanical key 14 respectively move into the blade retaining portion 31 and the handle retaining portion 29. While the handle 52 is moving in the handle retaining portion 29, the engagement projection 50 of the handle 52 is forced against the side wall 29b of the handle retaining portion 29 and resiliently flexed. This decreases resistance when the mechanical key 14 is inserted into the mechanical key retainer 27 and enables smooth movement of the mechanical key 14. When the engagement projection 50 is resiliently flexed, the cross-sectional area of the buffer opening 51 formed in the handle 52 is reduced. As a result, the engagement projection 50 is easily resiliently flexed.
Further insertion of the mechanical key 14 into the mechanical key retainer 27 arranges the blade 39 and the handle 52 in the blade retaining portion 31 and the handle retaining portion 29, respectively. When the engagement projection 50 reaches a position in the mechanical key retainer 27 where it faces toward the engagement recess 32, the engagement projection 50 is resiliently restored to its original position and enters the engagement recess 32. In this state, the engagement projection 50 is engaged with the engagement recess 32. This prevents the mechanical key 14 from falling out of the mechanical key retainer 27. As shown in
To remove the mechanical key 14 from the mechanical key retainer 27, the part of the mechanical key 14 exposed from the first cutaway portion 33 of the case 16 is held between the fingers and force is applied to pull the mechanical key 14 out of the mechanical key retainer 27. As a result, force greater than the engaging force of the engagement projection 50 and engagement recess 32 is applied to the engagement projection 50. This resiliently flexes the engagement projection 50. As a result, the engagement projection 50 is disengaged from the engagement recess 32. Further application of force to the mechanical key 14 moves the mechanical key 14 in the mechanical key retainer 27 in a state in which the engagement projection 50 is resiliently flexed and then removes the mechanical key 14 from the mechanical key retainer 27.
The present embodiment has the advantages described below.
(1) When accommodating the mechanical key 14 in the mechanical key retainer 27 of the main body 12, the engagement projection 50 of the mechanical key 14 is engaged with the engagement recess 32 of the mechanical key retainer 27. Accordingly, the mechanical key 14 and the main body 12 are engaged with each other through a simple structure. Further, there is no need for a lock member. This reduces the number of components in the portable device and enables the portable device 11 to be more compact.
(2) The engagement projection 50 of the mechanical key 14 is formed from a resilient resin material such as an elastomer. Accordingly, when inserting the mechanical key 14 into the mechanical key retainer 27 of the main body 12, the engagement projection 50 is resiliently flexed when necessary to smooth the movement of the mechanical key 14.
(3) The retraction cavity 51a is defined adjacent to the engagement projection 50 in the mechanical key 14. Accordingly, when inserting the mechanical key 14 into the mechanical key retainer 27 of the main body 12, the engagement projection 50 is resiliently flexed so as to be retracted toward the retraction cavity 51a. This ensures the flexing of the engagement projection 50 and enables smooth movement of the mechanical key 14.
(4) The case 16 of the main body 12 includes the first cutaway portion 33. Accordingly, when the mechanical key 14 is accommodated in the mechanical key retainer 27, the mechanical key 14 is partially exposed from the first cutaway portion 33. As a result, the mechanical key 14 may easily be removed from the mechanical key retainer 27 by holding and pulling the exposed part.
(5) The engagement projection 50 of the mechanical key 14 has a relatively high friction coefficient and is formed integrally with the grip 37 so as to improve the grip of the mechanical key 14. Accordingly, the number of components of the mechanical key 14 is decreased, and the portable device 11 may be miniaturized thereby improving the portability of the portable device 11.
(6) The engagement projection 50 of the mechanical key 14 is formed to project in the widthwise direction of the portable device 11. Accordingly, the engagement projection 50 does not increase the thickness of the portable device 11.
A second embodiment of the present invention will now be described with reference to
As shown in
As shown in
As shown in
The handle base 71 does not have the second and third cutaway portions 43 and 45, the thin portion 47, and the elliptic hole 49 of the handle base 41 in the first embodiment. As shown in
As shown in
The handle base 71 includes a thin portion 79, which is thin and extends between the fifth and sixth cutaway portions 75 and 77. Further, the handle base 71 includes a generally box-shaped retraction recess 81, which is located in the middle part of the handle base 71. When the mechanical key 55 is accommodated in the mechanical key retainer 59, the retraction recess 81 faces towards the upper wall 57b of the case 57. As shown in
As shown in
Referring to
The engagement plate 69 is hooked and fastened to the thin portion 79 of the key plate 67 as shown in
To insert the mechanical key 55 into the mechanical key retainer 59 of the case 57, the handle 93 of the mechanical key 55 is first held with the fingers. The mechanical key 55 is then inserted into the mechanical key retainer 59 from the blade 39 of the key plate 67. As the mechanical key 55 moves inside the mechanical key retainer 59, the spherical portion 91 of the handle 93 is forced against the wall surface of the mechanical key retainer 59. This resiliently flexes the spherical portion 91 of the engagement plate 69 and its periphery. Thus, the spherical portion 91 and its periphery move into the retraction recess 81. Accordingly, the engagement plate 69 is resiliently flexed into the retraction recess 81 without any interference. As a result, the resistance produced between the mechanical key 55 and the mechanical key retainer 59 is lowered. Thus, the movement of the mechanical key 55 is smooth.
Further insertion of the mechanical key 55 into the mechanical key retainer 59 accommodates the blade 39 and the handle 93 respectively in the blade retaining portion 60 and the handle retaining portion 61. Further, the spherical portion 91 of the engagement plate 69 is moved until reaching a position where it faces toward the engagement window 65. At this position, the spherical portion 91 enters the engagement window 65 and resiliently restores the engagement plate 69 to its original shape. In this state, the spherical portion 91 is engaged with the engagement window 65 so as to prevent the mechanical key 55 from falling out of the mechanical key retainer 59. Further, as shown in
To remove the mechanical key 55 from the mechanical key retainer 59, force for pulling out the mechanical key 55 from the mechanical key retainer 59 is applied with the user's fingers to the bent portion 73 exposed from the fourth cutaway portion 62. When the applied force becomes greater than the engaging force between the spherical portion 91 and the engagement window 65, the spherical portion 91 and its periphery are resiliently flexed. This disengages the spherical portion 91 from the engagement window 65. Further application of force to the mechanical key 55 moves the mechanical key 55 in the mechanical key retainer 59 with the spherical portion 91 and its periphery in a resiliently flexed state until the mechanical key 55 is removed from the mechanical key retainer 59.
The present embodiment has the advantages described below.
(7) When the mechanical key 55 is accommodated in the main body 54 of the mechanical key 55, the spherical portion 91 arranged on the engagement plate 69 of the mechanical key 55 is engaged with the engagement window 65 of the mechanical key retainer 59. Accordingly, the engagement of the mechanical key 55 and the main body 54 is enabled with a simple structure, and the need for a locking means is eliminated. This reduces the number of components in the portable device 53, enables miniaturization, and improves portability.
(8) The engagement plate 69, which includes the spherical portion 91, is formed from a resilient metal. Accordingly, when accommodating the mechanical key 55 in the mechanical key retainer 59 of the main body 54, the spherical portion 91 and its periphery are resiliently flexed when necessary so that the mechanical key 55 moves smoothly. Further, since the engagement plate 69 is made of metal, the engagement plate 69 has higher durability compared to when the engagement plate 69 is made of a resin. This further ensures the engagement between the mechanical key 55 and the main body 54.
(9) The mechanical key 55 includes the retraction cavity 82. Accordingly, when inserting the mechanical key 55 into the mechanical key retainer 59 of the main body 54, the spherical portion 91 and its periphery, which are resiliently flexed, enter the retraction cavity 82. This ensures resilient flexing of the spherical portion 91 and its periphery and enables the mechanical key 55 to move further smoothly.
(10) The case 57 of the main body 54 includes the fourth cutaway portion 62. Accordingly, when the mechanical key 55 is accommodated in the mechanical key retainer 59, the mechanical key 55 is partially exposed from the fourth cutaway portion 62. By pulling this exposed part, the mechanical key 55 is easily removed from the mechanical key retainer 59.
(11) The engagement window 65, which communicates the mechanical key retainer 59 with the exterior of the main body 54, is formed for engagement with the mechanical key 55. The engagement window 65, which is a hole extending through the main body 54, is easy to form and has a simple shape. This contributes to the miniaturization of the portable device 53.
(12) When the mechanical key 55 is accommodated in the mechanical key retainer 59, the spherical portion 91 is exposed to the exterior through the engagement window 65. Accordingly, the accommodation of the mechanical key 55 in the mechanical key retainer 59 may easily be confirmed by checking whether or not the spherical portion 91 is exposed through the engagement window 65.
A third embodiment of the present invention will now be described with reference to
As shown in
Further, as shown in
As shown in
The handle base 115 does not have the third cutaway portion 45, the thin portion 47, and the elliptic hole 49 of the handle base 41 in the first embodiment. However, the handle base 115 includes the second cutaway portion 43 of the first embodiment. The handle base 115 has a bell-shaped thin portion 117, which extends from the second cutaway portion 43 in the insertion direction of the mechanical key 99.
As viewed in
The lower grip member 107 is a bell-shaped plate made of resin and formed to fit into the lower fitting pit 121 of the key plate 105. When the lower grip member 107 is fitted in the lower fitting pit 121, the lower grip member 107 fills the lower fitting pit 121 and is flush with the lower surface 99a of the mechanical key 99. Further, a support projection 124 projects from the lower grip member 107. The support projection 124 includes a cylindrical lower portion and a conical higher portion. The support projection 124 is much smaller than the fitting hole 123 of the key plate 105. When the lower grip member 107 is fitted into the lower fitting pit 121 of the key plate 105, the support projection 124 is in concentric alignment with the fitting hole 123 of the key plate 105.
In the present embodiment, the spring 109 is a compression spring and has a constant diameter. The spring 109 is sized so that it may be fitted to the support projection 124 of the lower grip member 107. Accordingly, the spring 109 is located inside the fitting hole 123 of the key plate 105 in the mechanical key 99.
The hook 111, which functions as an engagement projection, is made of extremely thin metal and has a flat and circular top surface 111a. The top surface 111a has a diameter than is smaller than that of the engagement window 65 of the case 101 (refer to
The upper grip member 113 is a bell-shaped plate made of a resin and formed to fit into the upper fitting pit 119 of the key plate 105. When the upper grip member 113 is fitted in the upper fitting pit 119, the upper grip member 113 fills the upper fitting pit 119. A gripping projection 125, which has a generally trapezoidal cross-section when viewing the mechanical key 99 from above, projects from the upper grip member 113 away from the key plate 105. As shown in
As shown in
The upper grip member 113 further includes fused projections 129 and 131 projecting toward the key plate 105. The first fused projection 129 is formed to have an arcuate cross-section when viewing the mechanical key 99 from above. When the upper grip member 113 is fitted into the upper fitting pit 119, the first fused projection 129 is shaped and positioned to be engaged with the second cutaway portion 43. Further, the first fused projection 129 has a lower surface 129a, which is sized to abut against the lower grip member 107. In the present embodiment, the lower surface 129a of the first fused projection 129 is fused to the lower grip member 107.
The second fused projection 131 has an annular cross-section when viewing the mechanical key 99 from above. The second fused projection 131 has an outer diameter, which is substantially equal to the inner diameter of the fitting hole 123 in the key plate 105, and an inner diameter, which is greater than that of the spring hole 127 and smaller than that of the fitting hole 123. When the upper grip member 113 is fitted to the upper fitting pit 119 of the key plate 105, the second fused projection 131 is fitted into the fitting hole 123 of the key plate. Further, the second fused projection 131 has a lower surface 131a that abuts against the lower grip member 107. In the present embodiment, the lower surface 131a of the second fused projection 131 is fused to the lower grip member 107.
Accordingly, as shown in
To insert the mechanical key 99 into the mechanical key retainer 59 of the case 101, the handle 137 of the mechanical key 99 is first held with the fingers, and the mechanical key 99 is inserted into the mechanical key retainer 59 from the blade 39 of the key plate 105. As the mechanical key 99 moves in the mechanical key retainer 59, the hook 111, which is urged to project outwards, is forced against the wall surface of the mechanical key retainer 59. As a result, the hook 111 is moved toward the retraction cavity 135 of the mechanical key 55 against the urging force of the spring 109. This lowers resistance when the mechanical key 99 is inserted into the mechanical key retainer 59 and enables smooth movement of the mechanical key 99. In this state, the hook 111 is resiliently flexed and displaced from its original position.
Further insertion of the mechanical key 99 into the mechanical key retainer 59 arranges the blade 39 and the handle 137 respectively in the blade retaining portion 60 and the handle retaining portion 61. Then, the hook 111 of the mechanical key 99 reaches a position where the hook 111 faces toward the engagement window 65 of the case 101. The urging force of the spring 109 engages the hook 111 with the engagement window 65 and resiliently restores the hook 111 at its original position. This prevents the mechanical key 99 from falling out of the mechanical key retainer 59. In this state, as shown in
To remove the mechanical key 99 from the mechanical key retainer 59, the gripping projection 125 exposed from the seventh cutaway portion 103 is held with the fingers to apply force to the mechanical key 99 for removing the mechanical key 99 from the mechanical key retainer 59. As a result, force greater than the engaging force of the hook 111 and the engagement window 65 is applied to the hook 111. This resiliently flexes the hook 111 into the retraction cavity 135 against the urging force of the spring 109 and disengages the hook 111 from the engagement window 65. Further application of force to the mechanical key 99 moves the mechanical key 99 in the mechanical key retainer 59 with the hook 111 located in the retraction cavity 135 until the mechanical key 99 is removed from the mechanical key retainer 59.
The present embodiment has the advantages described below.
(13) When the main body 97 of the mechanical key 99 is accommodated in the mechanical key retainer 59, the hook 111 arranged in the mechanical key 99 is engaged with the spring hole 127. Accordingly, the engagement of the mechanical key 99 and the main body 97 is enabled with a simple structure, and the need for a locking means is eliminated. This reduces the number of components in the portable device 95, enables miniaturization, and improves portability.
(14) The hook 111 and the spring 109, which function as an engagement projection, are arranged on the mechanical key 99. The engagement window 65, which functions as an engagement recess, is arranged on the main body 97. Accordingly, although the engagement projection, which has a rather complicated structure, is arranged on the mechanical key 99, the engagement recess is formed by merely forming a hole that extends through the main body 97. This simplifies the structure of the main body 97, enables miniaturization of the portable device 95, and improves portability.
(15) The engagement projection of the mechanical key 99 is formed by the hook 111 and the spring 109, which are resilient. Accordingly, in comparison to when forming the projection from only a resilient resin, such as an elastomer, the resilient force of the spring 109, which has high durability, further ensures movement of the engagement projection. As a result, the engagement force between the mechanical key 99 and the main body 97 is further ensured.
(16) The engagement projection of the mechanical key 99 is formed by arranging the spring 109 in the hook 111. When the spring 109 is resiliently flexed and compressed, the hook 111 is moved inward. Accordingly, the space required for the hook 111 and the spring 109 in the mechanical key 99 is reduced. This further ensures miniaturization of the portable device 95.
(17) The retraction cavity 135 is adjacent to the hook 111 in the mechanical key 99. Accordingly, when the mechanical key 99 is accommodated in the mechanical key retainer 59, the hook 111 is resiliently flexed and moved into the retraction cavity 135. The movement of the hook 111 ensures smooth movement of the mechanical key 99.
(18) The case 101 of the main body 97 includes the seventh cutaway portion 103. Accordingly, when the mechanical key 99 is accommodated in the mechanical key retainer 59, part of the mechanical key 99 is exposed from the seventh cutaway portion 103. As a result, by holding and applying force to the exposed part, the mechanical key 99 may easily be removed from the mechanical key retainer 59.
(19) The engagement window 65, which communicates the mechanical key retainer 59 with the exterior of the main body 97, is used as an engagement recess for engagement with the mechanical key 99. Accordingly, the engagement recess is easily formed by the engagement window 65 extending through the main body 97, and the shape of the engagement recess is simplified. This ensures miniaturization of the portable device 95.
(20) When the mechanical key 99 is accommodated in the mechanical key retainer 59, the hook 111 is exposed from the mechanical key 99 through the spring hole 127 and the engagement window 65. Accordingly, the accommodation of the mechanical key 99 in the mechanical key retainer 59 may easily be confirmed by checking whether or not the hook 111 is exposed through the engagement window 65.
A fourth embodiment of the present invention will now be described with reference to
As shown in
Further, as shown in
As shown in
The handle base 157 is formed by eliminating the second cutaway portion 43 from the handle base 158 of the third embodiment. An eighth cutaway portion 159, which is wider than the second cutaway portion 43, is formed at the same position as the second cutaway portion 43 in the handle base 115 of the third embodiment. In the same manner as the handle base 115 of the third embodiment, a thin portion 161 extends from the eighth cutaway portion 159 in the insertion direction of the mechanical key 143. In the present embodiment, the thin portion 161 is generally rectangular. The two corners at the front side of the thin portion 161 with respect to the insertion direction of the mechanical key 143 are rounded.
Referring to
In the same manner as the handle base 115 of the third embodiment, a fitting hole 167 extends through the thin portion 161 of the handle base 157. In the present embodiment, the fitting hole 167 has a bell-shaped cross-section. The front end of the fitting hole 167, with respect to the insertion direction of the mechanical key 143, is straight. When the mechanical key 143 is accommodated in the mechanical key retainer 59 (refer to
Referring to
A rectangular spring hole 169 extends through the upper grip member 151. The size of the rectangular spring hole 169 is substantially the same as the size of the engagement window 147 of the case 145 (refer to
A fulcrum projection 173 also projects from the upper grip member 151 toward the key plate 149. The fulcrum projection 173 is cylindrical and formed between the rectangular spring hole 169 and third fused projection 171. The projecting length of the fulcrum projection 173 is substantially the same as that of the third fused projection 171.
As shown in
As shown in
Referring to
The lower grip member 155 is fitted into the lower fitting pit 165 of the key plate 149. In this state, the leaf spring support 183 of the lower grip member 155 is fitted between the fourth and fifth fused projections 175 and 177 of the upper grip member 151. Further, the fulcrum projection 173 of the upper grip member 151 is fitted in the fulcrum projection receptacle 185 of the lower grip member 155. In this state, the third to fifth fused projections 171, 175, and 177 of the upper grip member 151 are fused to the lower grip member 155. As shown in
The leaf spring 153 is located between the upper grip member 151 and the lower grip member 155. More specifically, in a state in which the fulcrum projection 173 of the upper grip member 151 is inserted through the fulcrum projection hole 179, by fitting the fulcrum projection 173 into the fulcrum projection receptacle 185 of the lower grip member 155, the leaf spring 153 is fixed in a cantilevered state between the upper grip member 151 and the lower grip member 155. The leaf spring 153 is arranged between the fourth and fifth fused projections 175 and 177. The arch 181 of the leaf spring 153 projects toward the upper grip member 151. Further, the leaf spring 153 is positioned and sized to enable insertion through the rectangular spring hole 169 of the upper grip member 151. Accordingly, as shown in
The application of force to the leaf spring 153 toward the lower grip member 155 resiliently flexes the leaf spring 153 toward the retraction cavity 189 about the fulcrum projection hole 179. In the mechanical key 143, the upper grip member 151, the leaf spring 153, and the lower grip member 155 form a handle 191.
To insert the mechanical key 143 into the mechanical key retainer 59 of the case 145, the handle 191 of the mechanical key 143 is first held with the fingers, and the mechanical key 143 is inserted into the mechanical key retainer 59 from the blade 39 of the key plate 149. As the mechanical key 143 moves in the mechanical key retainer 59, the arch 181 of the leaf spring 153, which projects outward from the handle 191, is forced against the wall surface of the mechanical key retainer 59. As a result, the leaf spring 153 is resiliently flexed, and the arch 181 is moved toward the retraction cavity 189 of the mechanical key 143. This lowers resistance when the mechanical key 143 is inserted into the mechanical key retainer 59 and enables smooth movement of the mechanical key 143.
Further insertion of the mechanical key 143 into the mechanical key retainer 59 arranges the blade 39 and the handle 191 respectively in the blade retaining portion 60 and the handle retaining portion 61. Then, the arch 181 of the leaf spring 153 in the mechanical key 143 reaches a position where the arch 181 faces toward the engagement window 147 of the case 145. The resilient force of the leaf spring 153 causes engagement with the engagement window 147 and resiliently restores the leaf spring 153 to its original shape. This prevents the mechanical key 143 from falling out of the mechanical key retainer 59. In this state, as shown in
To remove the mechanical key 143 from the mechanical key retainer 59, the gripping projection 125 exposed from the seventh cutaway portion 103 is held with the fingers to apply force to the mechanical key 143 for removing the mechanical key 143 from the mechanical key retainer 59. As a result, force greater than the engaging force of the arch 181 of the leaf spring 153 with the engagement window 147 is applied to the arch 181. This resiliently flexes the arch 181 of the leaf spring 153 into the retraction cavity 189 and disengages the arch 181 from the engagement window 147. Further application of force to the mechanical key 143 moves the mechanical key 143 in the mechanical key retainer 59 with the arch 181 located in the retraction cavity 189 until the mechanical key 143 is removed from the mechanical key retainer 59.
The present embodiment has the advantages described below.
(21) When the main body 141 of the mechanical key 143 is accommodated in the mechanical key retainer 59, the arch 181 arranged on the leaf spring 153 in the mechanical key 143 is engaged with the engagement window 147 of the mechanical key retainer 59. Accordingly, the engagement of the mechanical key 143 and the main body 141 is enabled with a simple structure, and the need for a locking means is eliminated. This reduces the number of components in the portable device 139, enables miniaturization, and improves portability.
(22) The leaf spring 153 having the arch 181 is formed from a resilient metal. Accordingly, when the mechanical key 143 is accommodated in mechanical key retainer 59 of the main body 141, the leaf spring 153 is resiliently flexed to enable smooth movement of the mechanical key 143. The arch 181, which functions as an engagement projection that engages the engagement window 147, is formed integrally with the leaf spring 153. This reduces the number of components in the portable device 139. Further, since the leaf spring 153 is made of metal, the leaf spring 153 has higher durability compared to when the leaf spring 153 is made of a resin. This further ensures the engagement between the mechanical key 143 and the main body 141.
(23) The mechanical key 143 includes the retraction cavity 189. Accordingly, when inserting the mechanical key 143 into the mechanical key retainer 59 of the main body 141, the leaf spring 153 enters the retraction cavity 189. This ensures resilient flexing of the leaf spring 153 and enables the mechanical key 143 to move further smoothly.
(24) The case 145 of the main body 141 includes the seventh cutaway portion 103. Accordingly, when the mechanical key 143 is accommodated in the mechanical key retainer 59, part of the mechanical key 143 is exposed from the seventh cutaway portion 103. As a result, by holding and applying force to the exposed part, the mechanical key 143 may easily be removed from the mechanical key retainer 59.
(25) The engagement window 147, which communicates the mechanical key retainer 59 with the exterior of the main body 141, is used as an engagement recess for engagement with the mechanical key 143. Accordingly, the engagement recess is easily formed by the engagement window 147 extending through the main body 141, and the shape of the recess is simplified. This ensures miniaturization of the portable device 139.
(26) The fulcrum projection hole 179, which functions as the fulcrum of the leaf spring 153, is located rearward from the arch 181 with respect to the insertion direction of the mechanical key 143. Accordingly, the distance from the fulcrum projection hole 179 to the location in which the mechanical key 143 receives external force is longer during insertion of the mechanical key 143 than during removal of the mechanical key 143. As a result, the arch 181 is resiliently flexed with a smaller force during insertion of the mechanical key 143 than during removal of the mechanical key 143. This prevents the mechanical key 143 from falling out of the mechanical key retainer 59 and facilitates insertion of the mechanical key 143 into the mechanical key retainer 59.
(27) When the mechanical key 143 is accommodated in the mechanical key retainer 59, the arch 181 is exposed from the mechanical key 143 through the engagement window 147. Accordingly, the accommodation of the mechanical key 143 in the mechanical key retainer 59 may easily be confirmed by checking whether or not the arch 181 is exposed from the engagement window 147.
A fifth embodiment of the present invention will now be described with reference to
As shown in
Further, as shown in
The handle base 205 is formed by eliminating the eighth cutaway portion 159, the thin portion 161, and the fitting hole 167 from the handle base 157 of the fourth embodiment. A flexible member receptacle 207 extends through the middle part of the handle base 205. The flexible member receptacle 207 has a substantially square cross-section. The handle base 205 further includes a frame-like lip 209, which extends along the walls of the flexible member receptacle 207. As shown in
As shown in
An engagement projection 213 projects from the flexible member 203. The engagement projection 213 is shaped and positioned in a manner enabling insertion into the engagement window 65 of the case 199 (refer to
The flexible member 203 has a thin portion 215, which extends outward from the engagement projection 213. The thin portion 215 has a generally square cross-section when viewing the mechanical key 197 from above. A box-shaped recess 217 is formed in the flexible member 203 on the opposite side of the engagement projection 213 and thin portion 215. A retraction cavity 219 is defined in the recess 217. The flexible member 203 also has a support projection 221 projecting downward into the retraction cavity 219 from the surface of the recess 217 that is opposite to the engagement projection 213. The support projection 221 has a circular cross-section. The handle base 205 and the flexible member 203 form a handle 223 of the mechanical key 197.
To insert the mechanical key 197 into the mechanical key retainer 59 of the case 199, the handle 223 of the mechanical key 197 is first held with the fingers, and the mechanical key 197 is inserted into the mechanical key retainer 59 from the blade 39 of the key plate 201. As the mechanical key 197 moves in the mechanical key retainer 59, the engagement projection 213, which projects outward from the handle 223, is forced against the wall surface of the mechanical key retainer 59. As a result, the engagement projection 213 and thin portion 215 are resiliently flexed, and the engagement projection 213 is moved toward the retraction cavity 219 of the mechanical key 197. This lowers resistance when the mechanical key 197 is inserted into the mechanical key retainer 59 and enables smooth movement of the mechanical key 197.
Further insertion of the mechanical key 197 into the mechanical key retainer 59 arranges the blade 39 and the handle 223 respectively in the blade retaining portion 60 and the handle retaining portion 61. Then, the engagement projection 213 of the mechanical key 197 reaches a position where the engagement projection 213 faces toward the engagement window 65 of the case 199. Then, the flexed engagement projection 213 and thin portion 215 are resiliently restored to their original positions and the engagement projection 213 engages with the engagement window 65. This prevents the mechanical key 197 from falling out of the mechanical key retainer 59. In this state, as shown in
To remove the mechanical key 197 from the mechanical key retainer 59, the part of the handle base 205 exposed from the first cutaway portion 33 is held with the fingers to apply force to the mechanical key 197 for removing the mechanical key 197 from the mechanical key retainer 59. As a result, force greater than the engaging force of the engagement projection 213 and the engagement window 65 is applied to the engagement projection 213. This resiliently flexes the engagement projection 213 into the retraction cavity 219 and disengages the engagement projection 213 from the engagement window 65. Further application of force to the mechanical key 197 moves the mechanical key 197 in the mechanical key retainer 59 with the engagement projection 213 located in the retraction cavity 219 until the mechanical key 197 is removed from the mechanical key retainer 59.
The present embodiment has the advantages described below.
(28) When the mechanical key 197 is accommodated in the mechanical key retainer 59 of the main body 195, the engagement projection 213 arranged on the mechanical key 197 is engaged with the engagement window 65 of the mechanical key retainer 59. Accordingly, the engagement of the mechanical key 197 and the main body 195 is enabled with a simple structure, and the need for an engaging means such as a locking means is eliminated. This reduces the number of components in the portable device 193, enables miniaturization, and improves portability.
(29) The engagement projection 213 of the mechanical key 197 is formed from a resilient resin material such as an elastomer. Accordingly, when the mechanical key 197 is accommodated in the mechanical key retainer 59 of the main body 195, the engagement projection 213 and its periphery are resiliently flexed to enable smooth movement of the mechanical key 197.
(30) The retraction cavity 219 is formed next to the engagement projection 213 in the mechanical key 197. Accordingly, when inserting the mechanical key 197 into the mechanical key retainer 59 of the main body 195, the engagement projection 213 is resiliently flexed into the retraction cavity 219. The movement of the engagement projection 213 enables smooth movement of the mechanical key 197.
(31) The case 199 of the main body 195 includes the first cutaway portion 33. Accordingly, when the mechanical key 197 is accommodated in the mechanical key retainer 59, part of the mechanical key 197 is exposed through the first cutaway portion 33. Thus, by holding and applying force to the exposed part, the mechanical key 197 is easily removed from the mechanical key retainer 59.
(32) The engagement projection 213 of the mechanical key 197 is formed integrally with the flexible member 203, which has a relatively high friction coefficient thereby increasing the gripping force when using the mechanical key 197. This reduces the number of components in the mechanical key 197, enables miniaturization of the portable device 193, and improves portability.
(33) The engagement window 65, which communicates the mechanical key retainer 59 with the exterior of the main body 195, is used as an engagement recess engaged with the mechanical key 197. Accordingly, the engagement recess is easily formed by the engagement window 65 extending through the main body 195, and the shape of the recess is simplified. This ensures miniaturization of the portable device 193.
(34) When the mechanical key 197 is accommodated in the mechanical key retainer 59, the engagement projection 213 is exposed from the case 199 through the engagement window 65. Accordingly, the accommodation of the mechanical key 197 in the mechanical key retainer 59 may easily be confirmed by checking whether or not the engagement projection 213 is exposed through the engagement window 65.
It should be apparent to those skilled in the art that the present invention may be embodied in many other specific forms without departing from the spirit or scope of the invention. Particularly, it should be understood that the present invention may be embodied in the following forms.
In the first, second, fourth, and fifth embodiments, the engagement projections (i.e., the engagement projections 50 and 213, the spherical portion 91, and the arch 181) are arranged on the mechanical keys 14, 55, 143, and 197. However, the engagement projections may be arranged on the main bodies 12, 54, 141, and 195 instead. In such cases, engagement recesses, which receive the engagement projections, are arranged on the mechanical keys 14, 55, 143, and 197.
In the first to fifth embodiments, the engagement projections 50 and 213, the spherical portion 91, the hook 111, and the arch 181 are formed from resilient materials. However, the engagement projections 50 and 213, the spherical portion 91, the hook 111, and the arch 181 may be formed from materials that are not resilient.
In the first to fifth embodiments, the mechanical keys 14, 55, 99, 143, and 197 respectively include the retraction cavities 51a, 82, 135, 189, and 219. However, the mechanical keys 14, 55, 99, 143, and 197 do not have to include the retraction cavities 51a, 82, 135, 189, and 219.
In the first to fifth embodiments, the main bodies 12, 54, 97, 141, and 195 include the cutaway portions 33, 62, and 103. However, the main bodies 12, 54, 97, 141, and 195 do not have to include the cutaway portions 33, 62, and 103. Further, in the first to fifth embodiments, the cutaway portions 33, 62, and 103 may have any shape as long as the mechanical keys 14, 55, 99, 143, and 197 can easily be removed from the mechanical key retainers 27 and 59. For example, the cutaway portion 103 may be shaped to have a rectangular cross-section. When changing the shapes of the cutaway portions 33, 62, and 103, the shapes of the bent portion 73 and the gripping projection 125 may be changed accordingly. For example, the gripping projection 125 may have a rectangular cross-section.
In the second to fifth embodiments, the engagement windows 65 and 147 function as engagement recesses for receiving the engagement projections of the mechanical keys 55, 99, 143, and 197. However, engagement recesses having other shapes may be employed. For example, engagement recesses that do not extend through the cases 57, 101, 145, and 199 may be employed.
In the first and fifth embodiments, the engagement projections 50 and 213 are respectively formed integrally with the grip 37 and the flexible member 203, which have a relatively high friction coefficient. However, the engagement projections 50 and 213 may respectively be formed separately from the grip 37 and the flexible member 203
In the second and fourth embodiments, the spherical portion 91 and the arch 181 are respectively formed by pressing the engagement plate 69 and the leaf spring 153. However, the spherical portion 91 and the arch 181 may be formed through other processes. Further, the spherical portion 91 and the arch 181 may respectively be formed separately from the engagement plate 69 and the leaf spring 153.
In the second embodiment, the spherical portion 91 has a spherical surface. However, the spherical portion 91 may have other shapes. For example, the spherical portion 91 may have the shape of a truncated cone.
In the third embodiment, the spring 109 has a constant diameter. However, as shown in
In the third embodiment, the lower grip member 107 and the upper grip-member 113 are thermally fused and fixed to each other. Instead, the lower grip member 107 and the upper grip member 113 may be formed integrally with each other from the beginning.
In the fourth embodiment, the arch 181 is formed on the leaf spring 153. However, the arch 181 may be formed on a metal plate, which is separate from the leaf spring 153. In such a case, as shown in
In the fourth embodiment, the fulcrum projection hole 179, which functions as the fulcrum of the leaf spring 153, is located towards the rear of the mechanical key 143 with respect to the mechanical key insertion direction. However, the leaf spring 153 may be arranged in the mechanical key 143 so that the fulcrum projection hole 179 is located toward the front of the mechanical key 143.
In the second to fifth embodiments, the spherical portion 91, the hook 111, the arch 181, and the engagement projection 213 are exposed through the engagement windows 65 and 147 and the spring hole 127. However, the spherical portion 91, the hook 111, the arch 181, and the engagement projection 213 may be unexposed. In such a case, the engagement windows 65 and 147 and the spring hole 127 may be covered with a transparent material. This enables visual confirmation of the spherical portion 91, the hook 111, the arch 181, and the engagement projection 213. Thus, the accommodation of the mechanical keys 55, 99, 143, and 197 in the mechanical key retainer 59 may easily be checked.
In the first to fifth embodiments, the portable devices 11, 53, 95, 139, and 193 are card-shaped. However, the portable devices 11, 53, 95, 139, and 193 may have other shapes.
The present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein, but may be modified within the scope and equivalence of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2005-253970 | Sep 2005 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
2316655 | Voos | Apr 1943 | A |
4888970 | Kinzler | Dec 1989 | A |
5051724 | Morrow et al. | Sep 1991 | A |
5561331 | Suyama et al. | Oct 1996 | A |
6386007 | Johnson et al. | May 2002 | B1 |
6460386 | Watanuki et al. | Oct 2002 | B1 |
6553802 | Jacob | Apr 2003 | B1 |
6672118 | Wright | Jan 2004 | B1 |
7098791 | Okada | Aug 2006 | B2 |
7227446 | Kumazaki et al. | Jun 2007 | B2 |
7290419 | Balko et al. | Nov 2007 | B2 |
20050166650 | Shimura et al. | Aug 2005 | A1 |
Number | Date | Country |
---|---|---|
2000-320202 | Nov 2000 | JP |
2003-307054 | Oct 2003 | JP |
2004-068417 | Mar 2004 | JP |
Number | Date | Country | |
---|---|---|---|
20070044525 A1 | Mar 2007 | US |