Patent Application
20170306653
The present application refers to a cathode lock, specifically refers to a cathode lock capable of the switchover between a normally-opened state and a normally-closed stated.
The requirements on the lock from the people are higher and higher, as the improvement of the living standard.
The existing cathode locks implement the locking process or unlucking process by utilizing the lock tongue to push the lock catch. In many occasions, for example technology department, the doors are required to be in a closed state mostly for keeping the door in a normally-closed state; but during a particular time period, for example the decoration period, the doors are required to be open more oftenly for facilitating the passing of the decorate personnel, further the locks are required to be in the normally-opened state. In the passway of the public space (for example the cinema and so on), the doors are required to be in the normally-closed state during the non-business hours, while the doors are required to be in the normally-opened state during the business hours. However, the door locks are not able to meet the free switch between the normally-opened state and the normally-closed state; thereby there is a need to design different types of locks, which will surely increase the cost of the production.
In order to resolve the forementioned technical problem, the present application provides a cathode lock and a method for switching the cathode lock from normally-opened state to normally-closed state. The said cathode lock is capable to implement the free switch between the normally-opened state and the normally-closed state of the door lock, decrease the cost of the production, and improve the utilization rate.
In order to achieve the forementioned object, the present application provides a cathode lock, which includes: a lock body 1 mounted on a door or on a door frame and a lock tongue capable of locking with the lock body 1. A lock catch 6 capable of locking with the lock tongue is arranged on the lock body 1. A solenoid 9 capable of generating an electromagnetic force when electrified is also mounted on the lock body 1. A breaking apparatus 10 capable of jamming the lock catch is connected to one end of the solenoid 9. The solenoid 9 is electrified to generate the electromagnetic force, and the breaking apparatus 10 is driven into motion under the effect of the electromagnetic force, thus allowing the breaking apparatus 10 to either be abutted against or separated from the lock catch 6.
As a further optimized embodiment of the present application, the breaking apparatus 10 includes the breaking rod 2 installed on the lock body 1 mobilizablily, wherein, the breaking rod 2 is connected to the solenoid 9, a breaking block 4 capable of jamming the lock catch is circularly arranged on the breaking rod 2, and the breaking block 4 is fixed on the breaking rod 2 via fastening screws 5 set on one side of the breaking block 4, wherein, the position of the breaking block 4 on the breaking rod 2 can be regulated/adjusted by loosing the fastening screws 5; the solenoid 9 generates an electromagnetic force by electrifying, and the solenoid 9 drives the breaking rod 2 and the breaking block 4 fixed thereon move for abutting against or separating from each other.
As a further optimized embodiment of the present application, in order to adjust the position that the breaking block is placed on the breaking rod 2, an adjusting spring 7 is provided on the breaking rod 2 between the breaking block 4 and the solenoid 9.
As a further optimized embodiment of the present application, the solenoid 9 includes spindle 91 provided in solenoid 9 and wire enwound around the reel; the solenoid 9 is in electric connection with a circuit board and electrified and diselectrified via the operating the circuit board; the solenoid 9 generates the electromagnetic force by electrifying, then drives the spindle 91 into motion move.
As a further optimized embodiment of the present application, one end of the spindle 91 is connected to the breaking rod 2 for driving the breaking rod 2 into motion.
As a further optimized embodiment of the present application, an end sleeve 8 is installed in between the end of the spindle 91 and the breaking rod 2, wherein the superficial area of the end sleeve 8 is larger than both superficial areas of spindle and the breaking rod, so that the spindle 91 is capable to connect with the breaking rod.
In order to achieve the forementioned object, the present application also provides a method for switching the cathode lock between a normally-opened state and a normally closed state, which includes the following steps: when switching to normally-opened state: loosing the fastening screw and adjusting the position that the breaking block is placed on the breaking rod for separating the breaking block from the lock catch; screwing up the fastening screw for securing the breaking block on the breaking rod, the door is unlocked at this moment; when closing the door, the solenoid 9 is electrified and the spindle 91 of the solenoid 9 drives the breaking rod into motion via the action of the electromagnetic force, the breaking rod drives the breaking block thereon move to the lock catch, the breaking block is abutted against the lock catch, the door is locked at this moment; when switching to normally-closed state: loosing the fastening screw and adjusting the position that the breaking block is placed on the breaking rod for abutting the breaking block against the lock catch; screwing up the fastening screw for securing the breaking block on the breaking rod, the door is locked at this moment; when opening the door, the solenoid 9 is electrified and the spindle 91 of the solenoid 9 drives the breaking rod into motion via the action of the electromagnetic force, the breaking rod drives the breaking block thereon into motion, the breaking block is separated from the lock catch, and the door is unlocked at this moment. As a further optimized embodiment of the present application, when switching to normally-opened state: loosing the fastening screw and adjusting the position that the breaking block is placed on the breaking rod for separating the breaking block from the lock catch; screwing up the fastening screw for securing the breaking block on the breaking rod, the door is unlocked at this moment; when closing the door, the solenoid 9 is electrified and the spindle 91 of the solenoid 9 drives the breaking rod into motion via the action of the electromagnetic force, the breaking rod drives the breaking block thereon move to the lock catch, the breaking block is abutted against the lock catch, the door is locked at this moment.
As a further optimized embodiment of the present application, when switching the cathode lock from the normally-opened state to the normally-closed state, the breaking block is moved forwards to the spindle till it arrives at predetermined position where the lock is in normally-closed state, the breaking block presses the adjusting spring, the fastening screw is screwed up.
As a further optimized embodiment of the present application, The benefit of the present application lies on: the fastening screw is provided on the cathode lock according to the present application, and the normally state of the cathode lock (normally-opened state and normally-closed state) can be adjusted via adjusting the fastening screw, which achieves the free switch between normally-opened state and the normally-closed state, decrease the cost of the production, and increase the utilization rate of the cathode lock.
The present application will be described in detail by several exemplary embodiments as follow. It should be noted that, without the further description, the elements, structures, and the features in a certain embodiment can also be integrated with other embodiments.
Referring to the
Referring to the
The foresaid solenoid 9 includes spindle 91 provided in solenoid 9 and varnished wire enwound around the reel placing outside of the spindle (unshown in figures); the solenoid 9 is in electric connection with a circuit board and electrified and diselectrified via the operating the circuit board, and the said circuit board can be operated via the existing technology, for example the card swiping, passwords, finger print or the like; the solenoid 9 generates the electromagnetic force by electrifying, then drives the spindle 91 into motion. One end of the spindle 91 is connected to the breaking rod 2 for driving the breaking rod 2 into motion. An end sleeve 8 is installed in between the end of the spindle 91 and the breaking rod 2, wherein the superficial area of the end sleeve 8 is larger than both superficial areas of spindle and the breaking rod, so that the spindle 91 is capable to connect with the breaking rod.
The present application also provides a method for switching the forsaid cathode lock between a normally-opened state and a normally closed state, which includes the following steps: when switching to normally-opened state from the normally-closed state: loosing the fastening screw and adjusting the position that the breaking block placed on the breaking rod for separating the breaking block from the lock catch; screwing up the fastening screw for securing the breaking block on the breaking rod, the door is unlocked at this moment; when closing the door, the solenoid is electrified and the spindle of the solenoid drives the breaking rod into motion via the action of the electromagnetic force, the breaking rod drives the breaking block thereon move to the lock catch, the breaking block is abutted against the lock catch, the door is locked at this moment; when switching to normally-closed state from a normally-opened state: loosing the fastening screw, and the breaking block is pushed to the corresponding position automatically via the tense of the adjusting spring, thereby the breaking block is abutted against the lock catch; screwing up the fastening screw for securing the breaking block on the breaking rod, the door is locked at this moment; when opening the door, the solenoid is electrified and the spindle of the solenoid drives the breaking rod into motion via the action of the electromagnetic force, the breaking rod drives the breaking block thereon into motion, the breaking block is separated from the lock catch, and the door is unlocked at this moment. When regulating the door from a normally-opened state to normally-closed state: normally-closed state, the breaking block is moved forwards to the spindle till it arrives at predetermined position calculated based on the magnetic force and the spring's elasticity; meanwhile, the breaking block presses the adjusting spring, the fastening screw is screwed up; the different solenoid and the different spring will lead to a different positions where the lock is in normally-closed state, the breaking block presses the adjusting spring, the fastening screw is screwed up.
Similarly, when the cathode lock in the normally-closed state is switched to normally-opened state: loosing the fastening screw and adjusting the position that the breaking block placed on the breaking rod for separating the breaking block from the lock catch; screwing up the fastening screw for securing the breaking block on the breaking rod, the lock is in opened state now; when closing the door, the solenoid is electrified and the spindle of the solenoid drives the breaking rod into motion via the action of the electromagnetic force, the breaking rod drives the breaking block thereon move to the lock catch, the breaking block is abutted against the lock catch, the door is locked at this moment. During the time that the cathode lock in the normally-closed state is switched to normally-opened state, the position where the breaking block is placed on the breaking rob is regulated by adjusting the breaking block manually, so that the breaking blocks arrives at the position separated from look catch, then screwing up the fastening screw. Therefore, the magnetic lock in the present application can be in either of the above mentioned two states, when it is in normal work, i.e. the normally-opened state or normally closed states; when the magnetic lock is in normally-opened state, the solenoid 9 is off electrified, and the breaking block is separated from the lock catch, the lock is in unlocked state; when the solenoid 9 is electrified, the spindle of the solenoid hits the end sleeve and drives the breaking block and the breaking rod into motion, further to press the breaking spring, the door is locked when the breaking block is abutted against the lock catch; after diselectrifying, the breaking rod, breaking block and the end sleeve are restored via the resilience from the spring, thereby the lock gets unlocked. When the magnetic lock is in normally-closed state, the solenoid 9 is off electrified, and the breaking block is abutted against the lock catch, the lock is in locked state; when the solenoid is electrified, the spindle of the solenoid hits the end sleeve and drives the breaking block and the breaking rod into motion, further to press the breaking spring, the door is unlocked when the breaking block is separate from the lock catch; after diselectrifying, the breaking rod, breaking block and the end sleeve are restored via the resilience from the spring, thereby the lock gets locked. It should be understood that, the present invention is described in detail by the illustration of the embodiments. Diverse changements and equivalent substitutions can be implemented by the one skilled in the art without departing from such principles. Moreover, under the teach of the present application, the modification can be done to the technical features and the embodiments without departing from such principles for adopting the utilization in practice. Therefore, the present application is not limited by the illustration of the embodiments in the specification, and all the embodiments falling in the scope defined by the claims will belong to the protection of the present application.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201410487082.7 | Sep 2014 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2015/093186 | 10/29/2015 | WO | 00 |
