KR101383302B1 - Dead-bolt lock apparatus with tamper-proof structure - Google Patents

Abstract

A locking device realizes a closed state and an open state by using a dead bolt. The dead bolt is in a closed state or an open state when a solenoid shaft moves in a first direction or a second direction according to the currents applied to a solenoid. When the dead bolt is in the closed state or when an unauthorized external force is applied to the dead bolt, the closed state is maintained by generating force applied to the solenoid shaft in the first direction in proportion to the unauthorized external force.

Description

Dead-bolt lock apparatus with tamper-proof structure

TECHNICAL FIELD The present invention relates to a locking device, and more particularly, to a dead bolt locking device having an unauthorized manipulation prevention structure.

In general, the locking device used for the entrance door of the door is a dead-bolt lock type (strike lock type) and a strike lock type (strike lock type). The dead bolt lock method is a method of inserting the dead bolt into the hole, and the strike lock type is installed in the door so that the turner of the lock device holds the latch installed in the door frame.

1 is a view showing the structure of a conventional dead bolt lock locking device.

As shown in FIG. 1, the dead bolt lock type locking device is rotated by a solenoid shaft 3 that moves back and forth according to a current applied to the solenoid 2 located inside the solenoid housing 1. By moving, the dead bolt 9 connected to the crank 5 moves in the up and down direction, thereby becoming a locked state and an unlocked state of the door.

Specifically, as shown in FIG. 1A, when the current is supplied to the locking device, the solenoid shaft 3 moves to the left side by an electromagnetic force generated according to the current applied to the solenoid 2. Is drawn into the solenoid. Accordingly, the crank 5 connected through the solenoid shaft 3 and the connecting pin 6 is rotated in the direction of the arrow a so that the dead bolt 9 protrudes downward from the main body 7 so as to be locked. The device is locked.

In this state, when the current supply to the solenoid 2 is cut off, as shown in FIG. 1B, the electromagnetic force applied to the solenoid is dissipated, and the solenoid shaft 3 moves to the right direction according to the restoring force of the compression spring 4. As the solenoid shaft 3 moves, the crank 5 rotates in the direction of the arrow a, and the force for pressing the dead bolt 9 downward is reduced, so that the dead bolt 9 moves upward. It is drawn into the housing 1. Thus the locking device is unlocked, i.e. opened.

However, in the conventional dead bolt type locking device operating as described above, the lock state is released by an unauthorized operation force applied from the outside. 2 is a view showing that the dead bolt is disabled in the conventional locking device.

In the locked state, as shown in FIG. 2, when an external force (F _Out ) acts to draw the dead bolt 9 into the housing 1, the external force F _Out is applied to the solenoid 2. When the solenoid shaft 3 is larger than the force F _sol for introducing the solenoid shaft 3 into the solenoid according to the electromagnetic force, the dead bolt 9 is introduced into the housing 1 by the elastic force of the spring surrounding the dead bolt 9. Direction force (F _{DB - Spriung} ) and external force (F _Out ) are combined so that the crank (5) is rotated counterclockwise around the connecting pin (8), so that the dead bolt (9) is connected to the housing (1). It is forced into the interior.

Therefore, when the dead bolt is operated by using a tool such as a screwdriver or a saw from the outside of the locked door to the gap between the doors, the dead bolt is disabled and the door can be forcibly opened.

To prevent unauthorized opening of the locking device, it is possible to change the specification of the solenoid so that the force of F _sol applied to the solenoid shaft is greater than the external force (F _Out ), but in this case the solenoid is too large As a result, power consumption increases and product efficiency decreases.

In addition, it is possible to prevent the dead bolt from being neutralized by adding a separate part, but in this case, the number of parts increases and the operation mechanism of the dead bolt becomes complicated.

The problem to be solved by the present invention is to provide a dead bolt locking device that can prevent the lock state is released by unauthorized operation.

Locking device according to a feature of the present invention, through the hole formed in the main body to form an open state by entering the main body or off the main body to form a locked state; Solenoids for generating an electromagnetic force in accordance with the applied current; A solenoid shaft moving in a first direction or a second direction according to the electromagnetic force generated by the solenoid; And a crank that rotates in conjunction with the solenoid shaft to move the dead bolt in a third direction away from the main body or in a fourth direction to introduce the dead bolt into the main body, wherein the crank is connected to the main body. A first connecting pin connected thereto; A guide line including a first end and a second end, wherein the guide end is formed at a position outside the rotation radius, the distance between the first connection pin and the front end; A second connecting pin connected to the solenoid shaft and moving along the guide part; And a tip portion for moving the dead bolt in a third direction or a fourth direction in association with the movement of the second connection pin.

The second connecting pin moves from the second end to the first end along the guide part according to the movement in the first direction of the solenoid shaft, and the guide part according to the movement in the second direction of the solenoid shaft. Accordingly, the first terminal may move from the first end to the second end.

In addition, the dead bolt is moved in the fourth direction as the second connecting pin is moved from the first end to the second end, so that the open state is formed when the second connecting pin is located at the second end. The dead bolt is moved in the third direction as the second connecting pin moves from the second end to the first end, so that the locked state is formed when the second connecting pin is located at the first end. Can be.

On the other hand, when an endless manipulation force is applied to the dead bolt from the outer wall in the locked state, the force corresponding to the first direction is generated by the counterclockwise rotation force generated by the crank according to the unauthorized manipulation force. Acting as a shaft, the locked state is maintained.

In addition, the locking device surrounds the solenoid shaft, and when the current is applied to the solenoid, the locking device is compressed to move the solenoid shaft in the first direction, and when the current is not applied, the locking device is restored to the original state. A solenoid compression spring for moving the solenoid shaft in the second direction; And a dead bolt compression spring surrounding the dead bolt, wherein the dead bolt is compressed when the dead bolt moves in the third direction and then restored to its original state when the dead bolt moves in the fourth direction. can do.

Locking device according to another aspect of the invention, the solenoid for generating an electromagnetic force in accordance with the applied current; A solenoid shaft moving in a first direction or a second direction opposite to the first direction according to the electromagnetic force generated by the solenoid; When the solenoid shaft moves in the first direction, the lock state is formed out of the main body through a hole formed in the main body, and when the solenoid shaft moves in the second direction, the solenoid shaft enters the main body to form an open state. Dead bolt; And rotate in a clockwise direction in association with a movement in the first direction of the solenoid shaft to move the dead bolt in a third direction away from the main body, and counterclockwise in association with a movement in the second direction of the solenoid shaft. And a crank which rotates in the fourth direction to move the dead bolt into the main body, and the crank is in the first direction to the solenoid shaft according to a force applied in the fourth direction from the outside to the dead bolt. To generate a force to act.

Here, the force generated by the crank may be proportional to the force applied in the fourth direction from the outside to the dead bolt.

According to another aspect of the present invention, there is provided a locking device comprising: a dead bolt that enters a main body through a hole formed in a main body and forms an open state or forms a locked state outside the main body; Solenoid shaft; A solenoid for generating a first force for moving the solenoid shaft in a first direction according to an applied current; A solenoid compression spring that surrounds the solenoid shaft and generates a second force that is compressed when the first force is generated and moves the solenoid shaft in a second direction when the first force is not generated; Rotate clockwise in conjunction with movement in the first direction of the solenoid shaft to move the dead bolt in a third direction away from the main body, and counterclockwise in association with movement in the second direction of the solenoid shaft. A crank which rotates to move the dead bolt in a fourth direction leading to the main body; A third force that surrounds the dead bolt and is compressed when the crank is rotated in a clockwise direction and then moved to the fourth direction while being restored to its original state when the crank is rotated in a counterclockwise direction. And a dead bolt compression spring for generating a fifth force, wherein the crank is a force acting in the first direction on the solenoid shaft in proportion to a fourth force which is a force applied in the fourth direction from the outside to the dead bolt in a locked state. Generates a force, and satisfies the fourth force <first force + fifth force.

Here, the crank is connected to the main body, the first connecting pin to function as a rotating shaft to generate a force acting in the first direction on the solenoid shaft; A guide line including a first end and a second end, wherein the guide end is formed at a position outside the rotation radius, the distance between the first connection pin and the front end; A second connecting pin connected to the solenoid shaft and moving along the guide part; And using the first connecting pin as a rotation axis, and may move in conjunction with the second connecting pin may include a front end for moving the dead bolt in the third direction or the fourth direction.

The guide unit may include a first guide line including the first end; And a direction perpendicular to a direction in which the first guide line is formed while being connected to the first guide line through a connection point. It may include a second guide line including the second end.

In addition, the locking state is formed when the second connecting pin is located at the first end of the guide portion, and the open state is formed while the second connecting pin is located at the second end of the guide portion. Can be.

In addition, when the force applied in the fourth direction with the dead bolt from the outside in the state that the second connecting pin is located at the first end, according to the movement in the fourth direction of the dead bolt While the tip portion rotates, the rotational force generated by the first connection pin acts as a force applied to the second connection pin, and the force applied to the second connection pin acts on the solenoid shaft in the first direction. May include power.

According to an embodiment of the present disclosure, the lock state of the dead bolt type device may be prevented from being released by an unauthorized operation. In particular, instead of increasing the solenoid magnetic force or adding a separate component, it is possible to effectively prevent the dead bolt from being disabled by changing a part of the structure of the locking device.

1 is a view showing the structure of a conventional dead bolt lock locking device.
2 is a view showing that the conventional dead bolt lock locking device is disabled.
3 is a cross-sectional view showing the structure of a locking device according to an embodiment of the present invention.
4 is an external perspective view of a locking device according to an embodiment of the present invention.
5 is a view showing the structure of a crank according to an embodiment of the present invention.
6 and 7 are views showing an operating state of the dead bolt locking device according to an embodiment of the present invention.
8 is a view showing a process in which the locked state of the dead bolt locking device according to an embodiment of the present invention.
9 is a view showing a force generated according to the rotational force of the crank in the locking device according to an embodiment of the present invention.
10 is an exemplary view showing a force generated according to another structure of the crank, Figure 11 is a view showing an operating state according to the structure of FIG.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Hereinafter, with reference to the drawings will be described a dead bolt locking device having a tamper resistant structure according to an embodiment of the present invention.

3 is a cross-sectional view of a dead bolt locking device having an unauthorized manipulation prevention structure according to an embodiment of the present invention, Figure 4 is an external perspective view of the locking device shown in FIG.

As shown in Figure 3, the locking device 10 according to an embodiment of the present invention is a solenoid 11, a solenoid shaft 12, a solenoid moving in the first or second direction according to the current applied to the solenoid A solenoid compression spring 13 surrounding the shaft, a crank 14 rotating in conjunction with the solenoid shaft, and a dead bolt 15 moving in the third or fourth direction connected to the crank.

The solenoid 11 has a coil wound therein and is provided inside the solenoid housing 16. The solenoid shaft 12 moves in the first direction or the second direction according to the electromagnetic force applied to the solenoid 11. When the current is supplied to the solenoid 11, a force that pulls the solenoid shaft 12 into the solenoid housing 16, that is, a first force F _sol , acts according to the electromagnetic force.

The solenoid compression spring 13 surrounds the solenoid shaft 12. When the first force F _sol is applied, the solenoid compression spring 13 is compressed, but when the first force F _sol is extinguished, that is, the second force. It is restored by (F _{sol - spring} ). Accordingly, when the solenoid shaft 12 has a first force (F _sol) is that when the action is moves in the first direction in which the inlet to the solenoid housing 16, a first force (F _sol) is not functional, the first It moves in a second direction opposite to the first direction by two forces (F _sol-spring ).

The crank 14 is connected to the solenoid shaft 12 and interlocks with the solenoid shaft.

5 is a view showing the structure of a crank according to an embodiment of the present invention.

Crank 14 according to an embodiment of the present invention, as shown in Figure 5 (A), the first connecting pin 141 for connecting the crank 14 to the main body 17, the crank to the solenoid shaft 12 The second connecting pin 142 for connecting, the guide portion 143 for guiding the second connecting pin, and the dead bolt 5 is connected to the force to move the dead bolt 5 in the third or fourth direction The tip includes a tip 144.

The first connecting pin 141 fixes the crank 14 to the main body 17 and functions as a rotation axis of the crank 14. The crank 14 rotates a predetermined angle counterclockwise or clockwise by using the first connecting pin 141 as the rotation axis.

The guide part 143 guides the second connecting pin to position the second connecting pin at the first point and the second point. To this end, as shown in FIG. 5B, the guide part 143 includes a first guide groove 1431 including a first end P1 corresponding to the first point and a second corresponding to the second point. And a second guide groove 1432 including an end P2, and the first guide groove 1431 and the second guide groove 1432 are connected through the connection point P3. The second connecting pin 142 moves along the first guide line 1431 from the first end P1, and then moves along the second guide groove 1432 at the connection point P3 and finally, the second end P2. The movement is terminated and positioned by). In addition, the second connecting pin 142 moves along the second guide line 1432 from the second end P2, and then moves along the first guide groove 1431 at the connection point P3, and finally the first end ( Located in P1).

In particular, in the embodiment of the present invention, in order to prevent the dead bolt from being disabled, the first end P1 of the guide part 143 is located outside the center of the first connecting pin 141. Specifically, when the distance between the first connecting pin 141 of the crank 14 and the front end portion 144 is a rotation radius r, the first end P1 is formed at a position outside the rotation radius. Through the guide portion 14, the dead bolt is prevented from being released, that is, unlocked by an unauthorized operation. This will be described later in more detail.

On the other hand, the dead bolt 15 is moved in the third direction (downward direction) or the fourth direction (upward direction) through a hole formed in the panel 19, which is formed in the lower portion of the main body 17, the panel 19 is connected to the main body The dead bolt compression spring 18 surrounds the dead bolt 15. According to the force exerted by the tip 144 of the crank 14, the dead bolt 15 moves in a third direction away from the main body 17, and the dead bolt compression spring 18 is applied to the dead bolt 15. When it is compressed by the losing force and the force is extinguished, it is restored by the elastic force, that is, the third force (F _DB-spring ). Accordingly, the dead bolt 15 is moved into the main body 17 by moving in the fourth direction opposite to the third direction by the third force F _DB-spring .

The dead bolt locking device 10 having such a structure may be connected to the door to perform a locking function. That is, the body 17 is coupled to the door frame and the panel 19 is made of a form that is coupled to the door, the body 17 is coupled to the door and the panel 19 can be made of a form coupled to the door frame, The main body 17 and the panel 19 are preferably arranged at positions corresponding to each other. The main body 17 and the panel 19 may be coupled to the door frame and the door by fastening members such as screws.

Next will be described the operation of the dead bolt locking device according to an embodiment of the present invention having such a structure.

6 is a view showing an operating state of the dead bolt locking device according to an embodiment of the present invention. In particular, it is a diagram illustrating a process of operating in the locked state in the open state.

When no power is applied to the dead bolt locking device 10, the dead bolt 15 is drawn into the main body 17 as shown in FIG. 6A, and the locking device is opened. At this time, the second connecting pin 142 of the crank 14 is located at the second end P2 of the guide portion 143. When power is applied in this state, the current is supplied to the solenoid 11 and a first force F _sol is generated.

Since the first force F _sol is greater than the second force F _sol-spring by the solenoid compression spring 13 and the third force F _{DB - spring} by the dead bolt compression spring 18, The solenoid shaft 12 is moved in the first direction by the force F _sol . As a result, the crank 14 connected by the solenoid shaft 12 and the first connecting pin 141 rotates. Specifically, the second connecting pin 142 is the guide portion 143 as shown in FIG. By moving along the second guide groove 1432, the crank 14 generates a rotational force b in a clockwise direction about the first connecting pin 141. Therefore, the front end portion 144 of the crank 14 is lowered and the dead bolt 15 is moved downward to push the dead bolt 15 out of the main body 17.

The second connecting pin 142 moves along the second guide groove 1432 and moves along the first guide groove 1431 through the connection point P2 as shown in FIG. When it stops at P1, the movement to the downward direction of the dead bolt 15 also ends. Therefore, the locked state is implemented and maintained by the dead bolt 15.

7 is a view showing an operating state of the dead bolt locking device according to an embodiment of the present invention. In particular, it is a diagram illustrating a process in which the locking device operates in the open state from the locked state.

As shown in FIG. 7A, when the power supply applied to the solenoid 11 is interrupted while the lock state is maintained by the dead bolt 15, the first force F caused by the electromagnetic force of the solenoid 11 is blocked. _sol ) is destroyed. Is _{- (spring} F _sol) to the solenoid shaft 12 by the movement in the second direction Accordingly, the solenoid compression spring 13 and a second output as restored. As the solenoid shaft 12 moves in the second direction, as shown in FIG. 7B, the second connecting pin 142 of the crank 14 is moved from the first end P1 to the first guide groove 1431. Start to move along.

The second connecting pin 142 of the solenoid shaft 12 and the crank 14 is continuously moved by the second force F _sol-spring , and the second connecting pin 142 is moved through the connecting point P3. When moved along the second guide groove 1432, a counterclockwise rotation force is generated using the first connecting pin 141 as the rotation axis. Accordingly, as the front end 144 of the crank 14 moves upward, the force that the front end 144 presses the dead bolt 15 is removed. As a result, the dead bolt 15 is moved in the third direction by the third force (F _DB-spring ) by the dead bolt compression spring 18 is drawn into the main body 17.

As the dead bolt 15 enters the main body 17, the locked state starts to be released, and the second connecting pin 142 moves along the second guide groove 1432 in FIG. When stopped at the end P2, the movement of the dead bolt 15 also ends. Therefore, the dead bolt 15 is completely drawn into the main body 17 to implement and maintain the open state.

On the other hand, as described above, when the power supply to the solenoid 11 is cut off so that the locking device 10 is in the open state, when the external force is applied to the locking device 10 in the locked state May occur. For example, a third bolt may be applied to the dead bolt 15 of the locking device 10 in a locked state by using a tool such as a screwdriver to perform unauthorized manipulation of the dead bolt.

The force exerted by the dead bolt to control the dead bolt from outside is called the fourth force (F _out ). In the embodiment of the present invention, the locked state is maintained even when an unauthorized operation force, that is, a fourth force F _out is applied in the locked state.

8 is a view showing a process in which the locked state of the dead bolt locking device according to an embodiment of the present invention.

In the locked state, the end bolt 144 of the crank 14 is applied to the dead bolt 15 when the fourth force F _out , which is an unauthorized operation force, is applied and the fourth force F _out is sufficiently larger than the first force F _sol . ) Is moved upwards to cause the crank 14 to rotate counterclockwise about the first connecting pin 141, that is, the rotation force a.

This rotational force a causes a force applied to the second connecting pin 142 connecting the solenoid shaft 12 and the crank 14. The force applied to the second connection pin 142 is called a fifth force (F _pin ). As shown in FIG. 9, the fifth force F _pin acts in the lower left direction by the rotation force a. 9 is a view showing a force generated according to the rotational force of the crank in the locking device according to an embodiment of the present invention. The force applied to the second connection pin 142 according to the rotational force (a) generated in the crank 14 is the fifth force (F _pin ) is the first connection pin 141, as shown in Figure 9 (A) It is applied in the lower left direction on the basis of. This is because the second connecting pin 142 is located at a position outside the rotation radius, which is the distance between the first connecting pin 141 and the tip portion 144. As shown in FIG. 9B, the fifth force F _pin acts in the vertical direction at the horizontal force F _H and the first connection pin 141, which is a force acting in the horizontal direction at the first connection pin 141. It can be expressed as the force of the vertical force (F _V ) that is the force. The horizontal force F _H acts in the horizontal direction on the left side with respect to the first connection pin 141.

In order for the dead bolt 15 to be drawn into the main body 17 according to the fourth force F _out , which is an endless manipulation force applied to the dead bolt 15, the second connecting pin 142 is formed along the guide part 143. 1 Move to the right from the end (P1). However, as shown in FIG. 8, even when the fourth force F _out is applied to the dead bolt 15 due to the stepless operation, the fourth force F _sol is acted on by the solenoid 11. The horizontal force F _H constituting the fifth force F _pin according to the rotation force generated by the force F _out additionally acts, so that the dead bolt 15 no longer enters the main body 17. And mechanically locked. That is, as the fourth force F _{out as} the stepless manipulation force increases, the horizontal force F _H of the fifth force F _pin generated accordingly increases, so that the force to maintain the solenoid shaft 12 in the first direction is increased. Is increased. As a result, as the stepless operation force increases, the force that the solenoid shaft 12 is held in the first direction, that is, the force that tries to maintain the lock state, also increases, so that the dead bolt 15 is not drawn into the main body 17 and is locked. Is maintained.

On the other hand, when the second connecting pin 142 of the crank 14 is located within the rotation radius which is the distance between the first connecting pin 141 and the tip 144, as shown in FIG. The fifth force F _pin generated according to the rotation force a is applied in the lower right direction with respect to the first connection pin 141. 10 is an exemplary view showing a force generated according to another structure of the crank, Figure 11 is a view showing an operating state according to the structure of FIG.

When the second connection pin 142 is located within the rotation radius, as shown in FIG. 10A, the fifth force F _pin according to the rotation force a is right based on the first connection pin 141. It is applied to the second connecting pin 142 in the lower direction. Accordingly, as shown in FIG. 10B, the fifth force F _pin may be represented as the sum of the horizontal force F _H acting in the right direction and the vertical force F _V acting in the vertical direction.

While the fourth force F _out is applied to the dead bolt 15 due to the unauthorized operation, as shown in FIG. 11, in the state in which the first force F _sol by the solenoid 11 is acting in the first direction. The horizontal connecting force F _H constituting the fifth force F _pin according to the rotational force acts in the second direction opposite to the first force F _sol , so that the second connecting pin 142 is guided. It moves to the right direction from the first terminal P1 along the unit 143. That is, the horizontal force F _H of the fifth force F _pin for moving the solenoid shaft 12 in the second direction also increases as the fourth force F _out due to the unauthorized operation by the dead bolt 15 increases. As a result, the second connecting pin 142 of the crank 14 moves along the guide portion 143 to the second end P2, whereby the leading end portion 144 of the crank 14 moves upward. 15) the downward pressure is removed. As a result, the dead bolt 15 is drawn into the main body 17 by an endless operation force, and the locked state is released.

Therefore, this embodiment of the present invention illustrates the structure of the crank 14 to generate a force for moving the dead bolt 15 in the third or fourth direction, that is, the lower or upper direction in conjunction with the solenoid shaft 12. Optimally configured as in 5, to prevent deadbolt deactivation by unauthorized operation. That is, even without increasing the size of a separate part or solenoid, in a position outside the rotation radius, which is the distance between the first connecting pin 141 which becomes the rotation axis in the crank 14 and the tip portion 144 moving according to the rotation, Through the structure in which the second connecting pin 142 moving in accordance with the rotational force is located, it is possible to effectively prevent the locking state of the locking device 10 is released by force.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (12)

delete delete delete delete delete delete delete A dead bolt which enters into the main body through a hole formed in the main body and forms an open state or forms a locked state outside the main body;
Solenoid shaft;
A solenoid for generating a first force for moving the solenoid shaft in a first direction according to an applied current;
A solenoid compression spring that surrounds the solenoid shaft and generates a second force that is compressed when the first force is generated and moves the solenoid shaft in a second direction when the first force is not generated;
Rotate clockwise in conjunction with movement in the first direction of the solenoid shaft to move the dead bolt in a third direction away from the main body, and counterclockwise in association with movement in the second direction of the solenoid shaft. A crank which rotates to move the dead bolt in a fourth direction leading to the main body;
A third force that surrounds the dead bolt and is compressed when the crank is rotated in a clockwise direction and then moved to the fourth direction while being restored to its original state when the crank is rotated in a counterclockwise direction. Dead bolt compression spring
Including;
The crank generates a fifth force, which is a force acting in the first direction on the solenoid shaft in proportion to a fourth force, which is a force applied in the fourth direction from the outside to the dead bolt in the locked state, and the fourth force <fourth 1 force + 5 force lock. The method of claim 8, wherein
The crank is
A tip portion for moving the dead bolt in the third direction or the fourth direction;
A first connecting pin connected to the main body and functioning as a rotating shaft of the crank to generate a force acting in the first direction on the solenoid shaft;
A guide line including a first end and a second end, wherein the guide end is formed at a position outside the rotation radius, the distance between the first connection pin and the tip end; And
It is connected to the solenoid shaft, in accordance with the guide line of the guide portion in conjunction with the movement of the solenoid shaft in the first direction or the second direction to move along the guide portion located at the first end or the second end. Second connecting pin
/ RTI &gt;
The front end portion is a locking device to rotate the dead bolt in the third direction or the fourth direction by rotating in conjunction with the second connection pin, the first connecting pin as the rotation axis. The method of claim 9, wherein
The guide portion
A first guide line including the first end; And
It is formed in a direction perpendicular to the direction in which the first guide line is formed while being connected through the first guide line and the connection point. A second guide line including the second end
Locking device comprising a. The method of claim 9, wherein
The locked state is formed in a state in which the second connection pin is located at the first end of the guide part, and the open state is formed in a state in which the second connection pin is located at the second end of the guide part. lock The method of claim 9, wherein
In the state where the second connecting pin is located at the first end, when a force applied in the fourth direction from the outside to the dead bolt,
As the front end portion rotates as the dead bolt moves in the fourth direction, a rotational force generated by the first connection pin acts as a force applied to the second connection pin, and a force applied to the second connection pin. Is a force acting on the solenoid shaft in the first direction.

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