The present invention relates to an electric lock, and more particularly, to an electric lock having an improved clutch mechanism.
Generally, an electric lock can be operated in an electronic control mode or a manual control mode. In the electronic control mode, locking or unlocking operation is performed according to an input instruction of a user. In the manual control mode, the user uses a manual control member of the electric lock to perform locking or unlocking operation. In order to prevent the electric lock from being damaged due to improper operation, the electric lock usually has a clutch mechanism to prevent mutual interference between the electronic control mode and the manual control mode. However, the clutch mechanism of the electric lock of the prior art has a more complex structure and more components, such that the appearance design of the electric lock is limited and the electric lock has poorer reliability.
The present invention relates to an electric lock and a clutch mechanism thereof.
The electric lock of the present invention comprises a housing, a clutch mechanism and a manual control member. The housing is formed with a driving structure and a shaft hole. The driving structure has a first inclined surface, a second inclined surface and a bottom surface located between bottom portions of the first inclined surface and the second inclined surface. The clutch mechanism comprises a driving member having a pushing structure, an elastic member arranged on the driving member for abutting against the driving structure, a rotating member having a pushed structure, and a motor configured to drive the driving member to rotate relative to the driving structure. The manual control member is connected to the rotating member through the shaft hole. When the motor drives the driving member to rotate relative to the driving structure, the elastic member is configured to abut against the first or second inclined surface to push the driving member to move toward the rotating member, so as to allow the pushing structure to abut against the pushed structure, in order to further drive the rotating member to rotate the manual control member.
The clutch mechanism of the electric lock of the present invention comprises a driving member, an elastic member, a rotating member and a motor. The driving member has a pushing structure. The elastic member is arranged on the driving member for abutting against a driving structure on a housing of the electric lock. The driving structure has a first inclined surface, a second inclined surface and a bottom surface located between bottom portions of the first inclined surface and the second inclined surface. The rotating member has a pushed structure. The motor is configured to drive the driving member to rotate relative to the driving structure. When the motor drives the driving member to rotate relative to the driving structure along a first rotating direction, the elastic member is configured to abut against the first inclined surface to push the driving member to move toward the rotating member, so as to allow the pushing structure to abut against the pushed structure, in order to further drive the rotating member to rotate along the first rotating direction. When the motor drives the driving member to rotate relative to the driving structure along a second rotating direction, the elastic member is configured to abut against the second inclined surface to push the driving member to move toward the rotating member, so as to allow the pushing structure to abut against the pushed structure, in order to further drive the rotating member to rotate along the second rotating direction. The second rotating direction is opposite to the first rotating direction.
These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
Please refer to
In the present embodiment, the rotating member 123 is configured to be connected to a latch (not shown in figures) of the electric lock 100 through a transmission rod (not shown in figures). When the rotating member 123 is rotated, the transmission rod is driven by the rotating member 123 to move the latch to an unlocked position or a locked position. In order to perform a manual control mode of the electric lock of the present invention, the manual control member 130 can be used to rotate the rotating member 123. In order to perform an electronic control mode of the electric lock of the present invention, the control circuit 140 can be used to control the motor 124 to rotate to further drive the rotating member 123 to rotate through the driving member 121.
Please refer to
When the electric lock 100 receives a locking command in the standby state, the control circuit 140 controls the motor 124 to drive the driving member 121 to rotate relative to the driving structure 112 along a first rotating direction R1, and the protrusion part 122b of the elastic member 122 is correspondingly moved up along the first inclined surface S1 from the bottom surface S3 of the driving structure 112. The inclined guiding surface F1 of the protrusion part 122b of the elastic member 122 further abuts against the first inclined surface S1 to guide the protrusion part 122b to move relative to the driving structure 112, in order to further push the driving member 121 to move toward the rotating member 123. When the protrusion part 122b of the elastic member 122 is close to the top portion of the first inclined surface S1, the driving member 121 is adjacent to the rotating member 123. As such, when the driving member 121 is further rotated (the guiding plane F3 of the protrusion part 122b of the elastic member 122 correspondingly abuts against the top surface S4 of the driving structure 112), the pushing structure P1 of the driving member 121 is configured to abut against the pushed structure P2 of the rotating member 123 to further drive the rotating member 123 to rotate along the first rotating direction R1. When the rotating member 123 is rotated along the first rotating direction R1, the manual control member 130 is correspondingly moved to a first position, and the latch of the electric lock 100 is correspondingly moved to a locked position.
In addition, after the latch of the electric lock 100 is located at the locked position, the control circuit 140 further controls the motor 124 to drive the driving member 121 to rotate relative to the driving structure 112 along a second rotating direction R2 (opposite to the first rotating direction R1), such that the protrusion part 122b of the elastic member 122 is moved down along the first inclined surface 31 from the top surface S4 of the driving structure 112, in order to move the driving member 121 gradually away from the rotating member 123 (the spring 126 also pushes the driving member 121 to move away from the rotating member 123) until the guiding plane F3 of the protrusion part 122b of the elastic member 122 abuts against the bottom surface S3 of the driving structure 112. In the meantime, the electric lock 100 returns to the standby state.
When the electric lock 100 receives an unlocking command in the standby state, the control circuit 140 controls the motor 124 to drive the driving member 121 to rotate relative to the driving structure 112 along the second rotating direction R2, and the protrusion part 122b of the elastic member 122 is correspondingly moved up along the second inclined surface S2 from the bottom surface S3 of the driving structure 112. The inclined guiding surface F2 of the protrusion part 122b of the elastic member 122 further abuts against the second inclined surface S2 to guide the protrusion part 122b to move relative to the driving structure 112, so as to further push the driving member 121 to move toward the rotating member 123. When the protrusion part 122b of the elastic member 122 is close to the top portion of the second inclined surface S2, the driving member 121 is adjacent to the rotating member 123. As such, when the driving member 121 is further rotated (the guiding plane F3 of the protrusion part 122b of the elastic member 122 correspondingly abuts against the top surface S4 of the driving structure 112), the pushing structure P1 of the driving member 121 is configured to abut against the pushed structure P2 of the rotating member 123, so as to further drive the rotating member 123 to rotate along the second rotating direction R2. When the rotating member 123 is rotated along the second rotating direction R2, the manual control member 130 is correspondingly moved to a second position, and the latch of the electric lock 100 is correspondingly moved to an unlocked position.
In addition, after the latch of the electric lock 100 is located at the unlocked position, the control circuit 140 further controls the motor 124 to drive the driving member 121 to rotate relative to the driving structure 112 along the first rotating direction R1, such that the protrusion part 122b of the elastic member 122 is moved down along the second inclined surface S2 from the top surface S4 of the driving structure 112, in order to move the driving member 121 gradually away from the rotating member 123 (the spring 126 also pushes the driving member 121 to move away from the rotating member 123) until the guiding plane F3 of the protrusion part 122b of the elastic member 122 abuts against the bottom surface S3 of the driving structure 112. In the meantime, the electric lock 100 returns to the standby state.
On the other hand, the user can also directly rotate the manual control member 130 when the electric lock 100 is in the standby state, so as to move the latch through the rotating member 123. For example, when the electric lock 100 is in the standby state and the user rotates the manual control member 130 along the first rotating direction R1 to the first position, the rotating member 123 is synchronously rotated along the first rotating direction R1 to move the latch to the locked position; when the electric lock 100 is in the standby state and the user rotates the manual control member 130 along the second rotating direction R2 to the second position, the rotating member 123 is synchronously rotated along the second rotating direction R2 to move the latch to the unlocked position. The driving member 121 is away from the rotating member 123 when the electric lock 100 is in the standby state. Therefore, when the user rotates the manual control member 130, the rotating member 123 does not interact with the driving member 121.
On the other hand, when the electronic control mode and the manual control mode interfere with each other, the clutch mechanism 120 of the present invention can prevent the electric lock 100 from being damaged due to improper operation. For example, when the motor 124 drives the driving member 121 to rotate relative to the driving structure 112 along the first rotating direction R1 and the user rotates the manual control member 130 along the second rotating direction R2, the rotating direction of the driving member 121 is opposite to the rotating direction of the rotating member 123, and the protrusion part 122b of the elastic member 122 can be further deformed to allow the driving member 121 to move backward, so as to avoid conflict between the pushing structure P1 of the driving member 121 and the pushed structure P2 of the rotating member 123, which may cause component damage.
According to the aforementioned arrangement, the clutch mechanism 120 of the electric lock of the present invention can smoothly perform the manual control mode and the electronic control mode. When the electronic control mode and the manual control mode interfere with each other, the clutch mechanism 120 of the present invention can also prevent the electric lock 100 from being damaged due to improper operation.
In contrast to the prior art, the clutch mechanism of the electric lock has fewer components to reduce space occupied by the clutch mechanism. Therefore, the electric lock of the present invention can become thinner and have greater appearance design flexibility. Moreover, the clutch mechanism of the electric lock of the present invention has a simpler structure to prevent the electric lock from being damaged due to improper operation, thereby further improving reliability of the electric lock.
Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
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109125321 | Jul 2020 | TW | national |
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Number | Date | Country | |
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20220025675 A1 | Jan 2022 | US |