1. Field of the Invention
The present invention generally relates to a lock having a simplified structure. Particularly, the present invention relates to a lock having a simplified lock core structure.
2. Description of the Prior Art
Consumer electronics play a very important role in the modern life. Fast lifestyle and eagerness for instant information make portable electronic devices become a necessity to most people. However, since these portable devices are in high demand, wide spread, high unit price, small volume, and high portability and become more and more popular, the possibility of being stolen or lost accordingly increases.
One type of locks is developed to against thieves. For example, laptop computer locks can connect the lock hole of electronic devices by a latch unit. In particular, when the lock is in the unlocked state, the latch unit can be controlled to change its status. Under different statuses, the latch unit can be inserted into or retreated from the lock hole or can be engaged with the lock hole. When the lock is in the locked state, the latch unit is not controllable, being locked to a certain status. Under such a status, the electronic device is secured by the lock due to the engagement of the latch unit with the lock hole.
As shown in
However, in the lock core structure of the conventional lock 1, to complete the arrangement of pin 8, lock core 5, and seat unit 2a must require appropriate mechanical techniques and proper manufacture steps. Considering the complexity of techniques and procedures, simplifying the lock core structure is desired.
It is an object of the present invention to provide a lock having a simplified structure to simplify the production process and reduce the production cost.
In one aspect, the present invention provides a lock including a lock core structure and a movable unit, wherein the lock core structure controls rotation of the movable unit. The lock core structure includes a restriction unit and a lock core. The restriction unit has a passage penetrating therethrough to form a first opening and a second opening on two opposite sides of the restriction unit. In addition, an extension wall is formed in the passage to face the second opening. The lock core is disposed in the passage to couple with the restriction unit and is movable relative to the restriction unit in an axial direction. The lock core further includes an end face and an extension portion, wherein the end face and the extension wall are disposed in the passage in a manner that the end face faces the extension wall. The extension portion of the lock core is disposed on one side of the lock core that is close to the first opening and selectively protrudes outside the first opening. In addition, the movable unit is disposed on one side of the restriction unit that has the first opening and selectively couples with the lock core. The movable unit can perform a reciprocal rotation within a given angle.
The lock core structure further includes an elastic unit disposed between the end face and the extension wall, wherein deformation of the elastic unit is linked to axial movement of the lock core. The axial movement of lock core can drive the end face to move toward the extension wall and also compress the elastic unit. Similarly, the elastic unit can release an elastic force to push the end face so as to drive the lock core to axially move in a reverse direction. The movable unit selectively couples with the lock core in the axial direction and has a rotation axis perpendicular to the axial direction, wherein the axial movement of the lock core toward the movable unit can drive the movable unit to rotate.
The restriction unit of the lock core structure further has a notch formed under the extension wall to communicate with the first opening and the second opening, wherein the extension portion of the lock core passes through the notch and reciprocally moves in the notch. In addition, the restriction unit further has a stop zone formed in the passage and on one side of the notch that is away from the first opening. The extension portion stops at the stop zone so as to restrict movement of the lock core away from the movable unit. Moreover, the extension portion of the lock core further includes a driving part and the movable unit includes a driven part adjacent to the driving part. As the lock core moves toward the movable unit, the driving part pushes the driven part away from the notch so as to drive the movable part to rotate. Similarly, movement of the lock core away from the movable unit indirectly or directly drives the driven part to move toward the notch so as to drive the movable unit to rotate in a reverse direction.
The restriction unit mainly consists of a first seat unit and a second seat unit connected in series, wherein the notch is formed in the first seat unit; the stop zone is a surface of the second seat unit connected to the first seat unit. In addition, the restriction unit further has a through hole substantially crossing the axial direction and communicating with the passage. The lock core further has a groove on its surface to selectively correspond to the through hole. Moreover, the lock core structure further includes a movable pin movably disposed in the through hole. A portion of the movable pin moves into the groove corresponding to the through hole to limit movement of the lock core toward the movable unit.
The lock of the present invention further includes a shell part fitted on the lock core structure and a portion of the movable unit. The shell part has a fixing unit disposed on one side of the lock core structure that is connected to the movable unit. The moveable part can rotate with respect to the fixing unit. Moreover, the fixing unit has an indentation. The movable unit has a latch end. The movable unit reciprocally rotates to drive the latch end to move relative to the indentation, wherein the latch end moves toward the indentation and is received in the indentation.
As shown in
Moreover, in the embodiment of the present invention, as shown in
As shown in
As shown in
The through hole 330 is preferably formed in the second seat unit 300, i.e. the movable seat unit, and the inner space of the through hole 330 is preferably in a size capable of restricting the movement of the movable pin 530 in the hole with respect to the wall of the through hole 330. Moreover, as shown in
In an embodiment of the present invention, an extension wall 220 is formed in the passage 230 of the restriction unit 250, preferably in the passage 230 and within the stationary seat unit 200, and faces the second opening 232, wherein the extension wall 220 can be located at the distal end of the passage 230 to reduce the first opening 231. Alternatively, as shown in FIGS. 3B and 4A-4B, the extension wall 220 extends from the inner wall of the passage 230 with two sides respectively face the first opening 231 and the second opening 232 and is positioned a distance away from the first opening 231. In addition, the stationary seat unit 200 further has a notch 210, wherein the notch 210 is formed from the surface of the seat unit 200 toward the inner side to communicate with the passage 230 as well as the first opening 231 and the second opening 232. The notch 210 preferably further extends along the axial direction I. That is, one side of the stationary seat unit 200 is formed with a long-narrowed notch 210 communicating with the passage 230. The width of the notch 210 along the radial direction is preferably larger than the length of the extension portion 570 of the lock core 500 in the same direction. The extension portion 570 passes through the notch 210 and can reciprocally move within the notch 210. The driving part 5700 is preferably able to protrude outside the first opening 231 and acts together with the movable unit 600. Furthermore, the end face 505 of the lock core 500 is disposed in the passage 230 in a manner that the end face 505 faces the extension wall 220 and the elastic element 72 is disposed between the end face 505 and the extension wall 220. The deformation of the elastic element 72 is linked to the axial movement of the lock core 500. In particular, when the lock core 500 moves toward the movable unit 600, the lock core 500 also moves relative to the restriction unit 250, so that the end face 505 moves toward the extension wall 220 to compress the elastic element 72. When the key acts on the lock core structure 850 to release the lock core 500 from the engagement state, the compressed elastic element 72 can be released to provide elastic force to push the lock core 500 to move away from the movable unit 600. The movement of the lock core 500 toward the movable unit 600 preferably occurs upon a user pressing the lock core 500.
In addition to the movement of the lock core 500 toward the movable unit 600 stopping at the engagement of the movable pin 530 and the groove 510, the distance that the lock core 500 moves away from the movable unit 600 can also be controlled. As described above, the lock core 500 includes the stopping portion 590; the restriction unit 250 is formed with the stop zone 240. As shown in FIGS. 3B and 4A-4B, the stopping portion 590 of the lock core 500 is preferably disposed on one side of the extension wall 570 opposite to the driving part 5700, such as a stepped protrusion on the surface of the body 520. The stop zone 240 can be formed within the notch 210, preferably on one end of the notch 210 away from the first opening 231. That is, one side surface of the second seat unit 300 adjacent to the first seat unit 200 can serve as the stop zone 240. The lock core 500 moves in the passage 230 away from the movable unit 600 and stops as the stopping portion 590 touches against the stop zone 240. Meanwhile, the lock core 500 also moves away from the movable unit 600. The position that the lock core 500 stops at the stop zone 240 preferably allows the driving part 5700 to move completely outside the contactable range of the driven part 610. It depends upon the location of the stop zone, the length of the notch, or the design of stopping portion.
Furthermore, since the elastic element 73 disposed at the corresponding location of the lock core 500 can move toward the movable unit 600 and is compressed as the driving part 5700 pushes the driven part 610 by the inclined face, when the driving part 5700 moves outside the contactable range of the driven part 610, the elastic element 73 can push one side of the movable unit 600 having the driven part 610 by touching against the side of the movable unit 600 having the driven part 610, allowing the latch end 630 to ascend. Moreover, since the extension portion 570 of the lock core 500 passes through the notch 210, when the driving part 5700 moves toward the first opening 231 and acts together with the movable unit 600, the movement of the lock core 500 away from the movable unit 600 will cause the driving part 5700 to move into the notch 210 through the first opening 231, allowing the driven part 610 to move toward the communicating direction of the first opening 231 and the notch 210. When the movement of the lock core 500 toward the movable unit 600 causes the driving part 5700 to protrude outside the first opening 231 and push the driven part 610, the driven part 610 is driven to move away from the notch 210.
In general, the lock core 500 including the body 520, the extension portion 570, the end face 505, and the groove 510 preferably has a closed outer surface, wherein the groove 510 is a shallow trench formed in the surface of the body 520 and considered as a portion of the outer surface. In particular, the lock core 500 of the present invention is preferably a solid structure, instead of a hollow tube having a receiving inner space enclosed by an inner surface. That is, the lock core 500 of the present invention is disposed with no restriction hole, simplifying the manufacture process and the lock core structure. Moreover, the restriction unit 250 of the present invention, such as the first seat unit 200, has no through hole to allow the restriction pin to pass therethrough for controlling the axial displacement of lock core. That is, the restriction unit 250 of the present invention has a simplified structure and a highly workable manufacture process. In addition, the simplified structure of the lock core 500 and the restriction unit 250 of the present invention also simplifies the assembly of the lock and reduces the assembly time of the lock.
Although the preferred embodiments of present invention have been described herein, the above description is merely illustrative. The preferred embodiments disclosed will not limit the scope of the present invention. Further modification of the invention herein disclosed will occur to those skilled in the respective arts and all such modifications are deemed to be within the scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
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101212069 | Jun 2012 | TW | national |