KR20160035475A - Door lock employing punch card key recognition mechanism, and handle device for the door lock - Google Patents

Abstract

The present invention relates to a door lock employing a punch card key recognition mechanism and a handle device for the same. The handle device for a door lock employing a punch card key recognition mechanism comprises a case, a handle, an elastic member for returning, a drive gear, a one-directional rotation inducing unit, and a motion transfer unit. The case is mounted on an outdoor side of a door. The handle rotates on the outside of the case back and forth between an initial position and an operational position. The elastic member for returning applies an elastic force to the handle in a direction in which the handle is returned to the initial position in the case. The drive gear is arranged coaxially with a rotational center axis of the handle in the case to rotate relative to the handle. The one-directional rotation inducing unit transfers a rotational force of the handle to the drive gear to rotate the drive gear in one direction only while the handle rotates from the initial position to the operational position when the handle rotates and returns once. The motion transfer unit receives a rotational motion of the drive gear to alternately output a forward rotational motion and a reverse rotational motion each time the handle rotates and returns once.

Description

[0001] The present invention relates to a door lock for a cardholder, and a handle device for the door lock,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a door lock in a manner of recognizing and locking or unlocking a through card key.

Generally, a door lock is a device that is mounted on a door, and locks the door in a doorframe or releases it from a locked state according to a user operation. In recent years, digital door locks such as a password input method, a fingerprint recognition method, and an RF method are increasingly used to improve security reliability and ease of use. Such a digital door lock has a disadvantage in that it can not function as a door lock when a circuit breakdown or a power source is discharged.

On the other hand, an example of a card key recognition method is disclosed in Korean Patent No. 0528505. According to this technique, a card in which several punching holes are formed is provided, and when the punching balls and the punches protruding from the movable plate inside the door lock device coincide with each other, they are released from the locked state. However, such a conventional punching ball type card can be easily copied, and a method for supplementing it is needed.

The object of the present invention is to provide a door lock of a perforated card key recognition type which can improve ease of use and improve security, and a handle device for the door lock.

According to another aspect of the present invention, there is provided a door lock handle device for a perforated card key recognition system including a case, a handle, a resilient member for return, a driving gear, a one-direction rotation induction unit, and a motion transmission unit. The case is mounted on the outdoor side of the door. The handle rotates and reciprocates between the initial position and the operating position on the outside of the case. The resilient member for returning applies an elastic force to the handle in a direction to return the handle to the initial position in the case. The drive gear is arranged coaxially with the rotational center axis of the handle in the case and can rotate relative to the handle. The one-direction rotation inducing unit rotates the driving gear in one direction by transmitting the rotational force of the knob to the driving gear only while the knob is rotating from the initial position to the operating position in one rotation of the knob. The motion transfer unit receives the rotational motion of the driving gear every time the knob rotates once, and alternately outputs the rotational motion in the forward direction and the rotational motion in the reverse direction.

The door lock of the perforated card key recognition method according to the present invention includes the above-described handle device, the operation unit, the key insertion unit, and the key recognition unit. The operating stand rotates forward and backward to lock or unlock the lock assembly installed on the inside of the door. The key inserting portion inserts a through hole card key having a through hole pattern and a non-through hole pattern. The key recognizing unit receives the rotational motion from the motion transmitting unit in a state where the card insertion key is inserted into the key inserting unit, performs a recognition operation on the card key, and transmits the rotational motion of the motion transmitting unit when the recognition is successful.

According to the present invention, the forward rotational motion and the reverse rotational motion can be transmitted to the key recognizing device every time the user rotates the knob in one rotation in the same manner, so that the usability can be increased.

According to the present invention, when both the through hole pattern and the non-through hole pattern of the through hole card key are successfully recognized without power supply, it is possible to lock or unseal the through hole card key, thereby improving security. Further, according to the present invention, even if there is a failure of the digital door lock in combination with the digital door lock, it is possible to lock or unlock it, and convenience can be improved.

FIG. 1 is a perspective view of a door lock of a through card key recognition method according to an embodiment of the present invention.
Fig. 2 is a partially exploded perspective view of Fig. 1. Fig.
Fig. 3 is an exploded perspective view of the one-direction rotation induction unit in Fig.
FIGS. 4 to 6 are front views for explaining an example of operation of the unidirectional rotation induction unit shown in FIG. 2. FIG.
Figs. 7 and 8 are front views for explaining an example of the action of the first and second stopper grooves and the stopper block in Fig. 2. Fig.
Figs. 9 to 11 are rear views for explaining an operation example of the resilient member for returning to Fig. 2; Fig.
Fig. 12 is a rear view of the rack gear guide portion in Fig. 2; Fig.
FIG. 13 is an exploded perspective view of the key recognition device in FIG. 3; FIG.
FIG. 14 is a perspective view of a part of the key recognizing part in FIG. 13; FIG.
15 to 17 are side views for explaining the recognition process by the key recognizing unit shown in FIG.
Fig. 18 is an exploded perspective view showing the rotational force intermittent portion shown in Fig. 13; Fig.
19 to 21 are perspective views for explaining an operation example of the rotational force intermittent portion in FIG.
Fig. 22 is a perspective view for explaining an example of the action of the key return operation portion in Fig. 13;
23 is a configuration diagram showing an example in which a position sensor and a power control unit are further provided in the door lock.

The present invention will now be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and a detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

FIG. 1 is a perspective view of a door lock of a through card key recognition method according to an embodiment of the present invention. Fig. 2 is a partially exploded perspective view of Fig. 1. Fig.

1 and 2, the door lock 100 of the through card key recognition system includes a handle device 110 and a key recognition device 120.

The handle device 110 includes a case 111, a handle 112, a resilient member 113, a driving gear 114, a one-way rotation induction part 115, and a motion transmission part 116 Respectively. The case 111 is mounted on the outdoor side of the door. The case 111 is formed with a key insertion hole 111a into which the through hole card key 10 is inserted. The case 111 may be provided with a pull holding member 1111 that rotatably supports the pull 112.

The knob 112 rotates and reciprocates between the initial position and the operating position on the outside of the case 111. [ For example, the handle 112 is composed of a bar-shaped handle and can be rotated around one end. The knob 112 can rotate from the initial position on the left side to the operating position in the counterclockwise direction. Here, the maximum rotation angle of the knob 112 may be set to 30 degrees as an angle between the initial position and the operating position.

The elastic member 113 for returning applies an elastic force to the handle 112 in the direction of returning the handle 112 to the initial position within the case 111. [ Therefore, when the user holds the handle 112 and rotates the handle 112 from the initial position to the operating position, the handle 112 can return to the initial position by the resilient member 113 for return.

Although not shown, the handle 112 may be connected to a latch bolt actuation mechanism. When the knob 112 is rotated from the initial position to the operating position by the user, the latch bolt is pulled into the latch of the door frame to fix the door. When the knob 112 is returned from the operating position to the initial position by the returning elastic member 113, The door can be released by pulling it out of the latch of the door frame.

The driving gear 114 is disposed coaxially with the rotational center axis of the knob 112 in the case 111 and is relatively rotatable with respect to the knob 112. [ The driving gear 114 may be in the form of a ring gear or the like.

The unidirectional rotation induction unit 115 transmits the rotational force of the handle 112 to the driving gear 114 only while the knob 112 rotates from the initial position to the operating position in one- Thereby rotating the gear 114 in one direction. The unidirectional rotation induction portion 115 does not transmit the rotational force of the handle 112 to the driving gear 114 while the knob 112 returns from the operating position to the initial position. The motion transfer unit 116 receives the rotational motion of the driving gear 114 every time the knob 112 reciprocates once, and alternately outputs the rotational motion in the forward direction and the rotational motion in the reverse direction. The unidirectional rotation induction unit 114 and the motion transmission unit 115 can be received in the case 111. [

The above-described handle device 110 can operate as follows.

When the user rotates the handle 112 from the initial position to the operating position and then releases the handle 112, the handle 112 is returned by the returning elastic member 113 from the operating position to the initial position. In this process, the driving gear 114 receives the rotational force of the knob 112 by the one-direction rotation inducing portion 115 and rotates in one direction only while the knob 112 is rotated from the initial position to the operating position.

The rotational motion of the driving gear 114 is output through the motion transmitting portion 116 in the forward or reverse rotational motion. If the rotational motion of the driving gear 114 is output through the motion transmitting portion 116 in the forward rotational direction during the forward rotation operation of the knob 112, 114 is outputted as a rotational motion in the reverse direction through the motion transmission portion 116. [ Accordingly, each time the user rotates the knob 112 by one rotation in the same manner, the user alternately outputs the rotational motion in the forward direction and the rotational motion in the opposite direction from the motion transfer unit 116 and transfers the same to the key recognition apparatus 120 .

3, the unidirectional rotation induction unit 115 includes a rotation block 1151, a rotation interrupting plate 1152, an engagement pin 1153, an elastic member 1154 for a first engagement pin, And an elastic member 1155 for the second latching pin.

The rotation block 1151 is fixed on the same axis as the rotation center axis of the knob 112. The rotation block 1151 is rotatably supported by the case 111. [ The rotating coupling plate 1152 is fixed to the inside of the driving gear 114 and rotates together with the driving gear 114. The rotation interrupting plate 1152 is formed by arranging the latching grooves 1152a along the circumference at an angle equal to the maximum rotation angle of the knob 112. [

The engaging pin 1153 is installed on the rotating block 1151 so as to be slidable in the radial direction of the rotating block 1151 so as to be inserted into or separated from any one of the engaging grooves 1152a of the engaging grooves 1152a. For example, the rotation block 1151 is formed with a hole 1151a for a locking pin extending in the radial direction on one side and a stepped hole in the thickness direction. The engaging pin 1153 has a engaging pin body 1153a at the center of its periphery. The engaging pin body 1153a is seated in the engaging pin hole 1151a and slides in the radial direction of the rotating block 1151. [ The cover 1153b is mounted on the rotation block 1151 so as not to separate from the state where the engagement pin 1153 is inserted into the engagement pin hole 1151a. The cover 1153b has a hole corresponding to the movement locus of the engaging pin 1153.

4 and 5, the elastic member 1154 for the first latching pin is configured such that the latching pin 1153 is inserted into any one of the latching grooves 1152a while the knob 112 is rotated from the initial position to the operating position An elastic force is applied to the engagement pin 1153 so as to be separated from the engagement state. The elastic member 1154 for the first latching pin may have a plate spring shape and may be supported by the case 111. The elastic members 1154 for the first latching pin may be formed in a symmetrically connected structure in a pair. The reason for this is as follows. As described below, the latch pin 1153 can be positioned on the opposite side with respect to the center of the rotation block 1151 as the handle 112 is changed in position. In this case, an additional elastic member 1154 for the first latching pin is required, which makes it convenient to use the elastic member 1154 for the first latching pin of the same type.

6, the elastic member 1155 for the second latching pin is inserted into the latching groove 1152a of the latching groove 1152a while the latching pin 1153 is rotated in the following one of the latching grooves 1152a during the rotation of the knob 112 from the operating position to the initial position Elastic force is applied to the engaging pin 1153 so as to fit into the engaging pins 1152a and 1152a. The elastic member 1155 for the second latching pin may be in the form of a leaf spring and may be supported by the case 111. The elastic members 1155 for the second latching pins may also be symmetrically connected in pairs in the same manner as the elastic members 1154 for the first latching pins.

The first and second stopper grooves 1151b and 1151c may be formed around the rotation block 1151. [ The stopper block 1156 is selectively fitted in the first and second stopper grooves 1151b and 1151c. The stopper block 1156 is rotated in the first stopper groove 1151b or the second stopper groove 1151c when the rotation block 1151 is rotated to correspond to the first stopper groove 1151b or the second stopper groove 1151c And is installed in the case 111 so as to be accessible. The stopper block 1156 may be disposed at the 6 o'clock side of the lower center of the rotation block 1151. [

7, the first stopper groove 1151b restricts the handle 112 to rotate from the initial position on the left side to the operating position in the counterclockwise direction from the outdoor side of the door with the stopper block 1156 interposed therebetween . The knob 112 is positioned horizontally at the initial position on the left side. In this state, if the user rotates the knob 112 by 180 degrees and places the stopper block 1156 on the opposite side, the stopper block 1156 is separated from the first stopper groove 1151b.

8, the user rotates the handle 112 by 180 degrees to rotate the rotation block 1151 together so that the stopper block 1156 can be inserted into the second stopper groove 1151c . The second stopper groove 1151c restricts the handle 112 to rotate clockwise from the initial position on the right side on the outdoor side of the door to the operating position with the stopper block 1156 sandwiched therebetween. Accordingly, the user can conveniently change the handle 112 to a desired position of the left and right through the above-described process.

An example of the action of the returning elastic member 113 will be described with reference to FIG. 9 to FIG. 11 together with FIG. 2 as follows. The returning elastic member 113 may be composed of a torsion spring that generates an elastic force in a winding direction when an external force is applied in a pulling direction. The torsion spring is disposed so as to surround the periphery of the pull holding member 1111. The torsion springs may include a pair of latching rods 113a and 113b extending at both ends in a direction parallel to the rotation axis of the handle 112. [ The latching rods 113a and 113b can be arranged side by side on the side of 6 o'clock with respect to the pull holding member 1111. [ The case 111 may have a support tab 1112 inserted between the engagement rods 113a and 113b. The rotation block 1151 may include a pushing rod 1151d which is disposed outside the support step 1112 and inserted between the engagement rods 113a and 113b.

9, in a state where the stopper block 1156 is positioned so as to deviate from the rotation block 1151, the handle 112 is rotated in the clockwise direction from the 12 o'clock direction to the 3 o'clock direction . The left hook 113b is pushed by the pushing rod 1151d of the rotating block 1151 and moves in the direction of 9 o'clock with the right hook 113a being hooked on the hook 1112. [ As a result, the torsion spring elastically deforms and applies an elastic force to rotate the rotation block 1151 counterclockwise to the pushing rod 1151d. In this state, when the stopper block 1156 is inserted into the first stopper groove 1151b of the rotating block 1151, the rotating block 1151 is stopped in the stopper block 1156 In the counterclockwise direction.

As a result, the handle 112 is subjected to an elastic force to rotate counterclockwise in a state in which it is no longer rotated counterclockwise at a position of 3 o'clock. In this state, when the user grasps the handle 112 and rotates from the 3 o'clock direction to the 6 o'clock direction and then releases the knob 112, the handle 112 can return to the 3 o'clock position.

9, in a state in which the stopper block 1156 is positioned to deviate from the rotation block 1151, the handle 112 is rotated counterclockwise from the 12 o'clock direction to the 9 o'clock position as shown in Fig. Direction. Then the right hooking rod 113a is pushed by the pushing rod 1151d of the rotating block 1151 and moves in the 3 o'clock direction in a state where the left hooking rod 113b is hooked on the supporting step 1112. [ As a result, the torsion spring elastically deforms and applies an elastic force to the pushing rod 1151d to rotate the rotating block 1151 clockwise. In this state, when the stopper block 1156 is inserted into the second stopper groove 1151c of the rotating block 1151, the rotating block 1151 is stopped in the stopper block 1156 And receives an elastic force to rotate clockwise.

As a result, the handle 112 is subjected to elastic force to rotate clockwise in the clockwise direction at a position of 9 o'clock in a state where it is no longer rotated. In this state, when the user grasps the handle 112 and rotates it from the 9 o'clock direction to the 6 o'clock position, the handle 112 can return to the 9 o'clock position.

Referring to Fig. 12 together with Fig. 2, the motion transmission portion 116 includes a driven gear 1161, a cam member 1162, a rack gear 1163, a rack gear guide portion 1164, and a pinion gear 1165). The driven gear 1161 is engaged with the drive gear 114. The cam member 1162 is fixed to the rotation shaft of the driven gear 1161. [ The cam member 1162 may be a plate cam. The cam member 1162 has a short axis portion and a long axis portion on both sides with respect to the center of rotation. The rack gear 1163 is brought into close contact with the cam member 1162 and reciprocally moved in accordance with the rotation of the cam member 1162 in one direction. The rack gear 1163 can be reciprocated in a sliding manner as the short axis portion and the long axis portion of the cam member 1162 closely contact each other when the cam member 1162 rotates by 180 degrees.

The rack gear guide portion 1164 guides the movement of the rack gear 1163 in a state in which the rack gear 1163 is in close contact with the cam member 1162. [ For example, the rack gear guide portion 1164 may include a movable pin 1164a and a guide block 1164b. The movable pin 1164a is protruded at a position deviated from the center of rotation of the cam member 1162. [

The guide block 1164b is slidably supported by the case 111 in a direction parallel to the moving direction of the rack gear 1163 while the rack gear 1163 is mounted. The case 111 may have support pins and the guide block 1164b may have support holes. The support holes can respectively support the support pins and can extend in the direction parallel to the moving direction of the rack gear 1163 to support the slide movement of the guide block 1164b. The guide block 1164b has a movable hole 1164c for guiding the movement of the movable pin 1164a and keeping the rack gear 1163 in contact with the cam member 1162. [

The pinion gear 1165 meshes with the rack gear 1163. The pinion gear 1165 converts the slide reciprocating motion of the rack gear 1163 into forward and reverse rotation motions. The forward and reverse motions output from the pinion gear 1165 are transmitted to the recognition drive cam 1462a via the second intermediate gear 1166b of the key recognition device 120 to be described later. An intermediate gear unit 1166 may be provided between the pinion gear 1165 and the recognition drive cam 1462a. The intermediate gear unit 1166 includes a first intermediate gear 1166a which is coaxially connected to the pinion gear 1165 by a connecting shaft 1166c and a second intermediate gear 1166b which is engaged with the first intermediate gear 1166a, And a second intermediate gear 1166b that is fixed to the second gear member 1166b. The number of teeth of each of the first and second intermediate gears 1166a and 1166b is set such that the recognition drive cam 1462a rotates 360 degrees when the pinion gear 1165 rotates by one rotation of the handle 112. [

The key recognition apparatus 120 includes an operation unit 121, a key insertion unit 130, and a key recognition unit 140. This will be described with reference to FIGS. 13 to 22. FIG. 13 to 22 illustrate the key recognition device 120 in the up-and-down direction on the basis that the through-hole pattern 12 and the non-through hole pattern 13 of the through-hole card key 10 are positioned upward Respectively. Therefore, what is referred to as 'up' or 'down' in the description of the components of the key recognizing apparatus 120 refers to the position of the through card key 10 as a reference, and is not limited to that term.

Referring to FIG. 13, the operation unit 121 is configured to switch the lock state of the lock assembly (not shown) installed on the door side of the door to the unlock state, or to change the unlock state of the lock assembly to the lock state, Reverse. The lock assembly is configured to lock or unlock the door by pulling or pulling a deadbolt into or from the latch of the door frame according to the lock or unlock operation of the operation console 121. [

The key insertion unit 130 is configured to insert the through card key 10. For example, the key inserting unit 130 is coupled to the lower frame 1431 of the key recognizing unit 140 so as to be spaced apart from the lower frame 1431 and inserts the through hole card key 10 into the slot 132 formed on the key cover 131. The slot 132 corresponds to the insertion hole 111a of the case shown in Fig.

The through card key 10 includes a card body 11, a through hole pattern 12, and a non-through hole pattern 13. The through-hole pattern 12 is formed through the card main body 11. The through-hole pattern 12 includes at least one passage 11a. The passage portion 11a may be a circular hole.

The non-penetrating pattern 13 may include first and second non-penetrating patterns 14 and 15. The first non-through hole pattern (14) is formed on one side of the card body (11). The first non-penetrating pattern 14 includes at least one first non-passage 14a. The first non-cylindrical portion 14a has a closed structure without a groove.

The second non-through hole pattern (15) is formed on one side of the card body (11) so as to have a thickness thinner than the first non-through hole pattern (14). That is, the second non-through hole pattern 15 includes at least one second non-through hole 15a having a groove structure, and the thickness of the second non-through hole 15a is greater than the thickness of the first non- Is set to be thinner. The second non-passage 15a may be a circular groove. The depth of the second non-passage 15a may be set to about half of the thickness of the card body 11, but is not limited thereto.

The through card key 10 includes at least one or more than one of the through-holes 12a, the first non-through hole 14a, and the second non-through hole 15a so as to allow unique identification, The security can be improved. In the case where a digital door lock for locking or unlocking the lock assembly by digital authentication includes an RFID (Radio Frequency Identifier) authenticator, the card main body 11 may include an RFID tag incorporating identification information for access. The RFID authenticator can read the access identification information embedded in the RFID tag and act to unlock the lock state of the lock tag when authentication is successful. The digital door lock can be housed in the case 111. Fig.

The key recognition unit 140 determines that the through hole pattern 12 of the through hole card key 10 and the first through hole 12 of the through hole card key 10 are in contact with each other in accordance with the rotation operation of the handle 112, , And the non-penetrating pattern (14) (15). The key recognition unit 140 transmits the rotational force of the handle device 110 to the operating base 121 when the recognition of the cardholder key 10 is successful. The operation unit 121 can be rotated to the locked position or the unlocked position in accordance with the direction of the rotational force transmitted from the handle device 110. [ The key recognition unit 140 does not transmit the rotational force of the handle device 110 to the operating member 121 when the recognition of the cardholder key 10 fails.

Thus, the key recognizing unit 140 recognizes only the through hole pattern 12 of the through hole card key 10 as well as the first and second non-through hole patterns 14 and 15, It is possible to make it more difficult for an unauthorized user to predict or reproduce, compared with the conventional method of recognizing only the through-hole pattern of the perforated card key, and thus the security can be further improved.

Referring to FIG. 14 together with FIG. 13, the key recognizer 140 may include a plurality of recognition bars 1410, at least one pattern plate 1470, and a torque interrupter 1480.

The recognition bars 1410 are arranged such that the lower ends of the recognition bars 1410 correspond to the through-hole pattern 12 of the through hole card key 10 and the first and second non-through holes 14 and 15, respectively. For example, when the through hole pattern 12 and the first and second non-through holes 14 and 15 are combined and arranged in two rows in the longitudinal direction of the through hole card key 10, the recognition bars 1410 are also arranged in two rows And the lower end portions thereof are arranged corresponding to the through-hole pattern 12 and the first and second non-through-hole patterns 14 and 15.

Each lower end of the recognition bars 1410 is sized to be inserted into the passage 12a of the through-hole pattern 12 and the second non-passage 15a of the second non-communicating pattern 15. The recognition bars 1410 are formed with projecting pins 1411 on each side. The projecting pins 1411 of the recognition bars 1410 are projected to be inserted into the first, second and third pattern holes 1471, 1472 and 1473 of the pattern plate 1470, respectively.

The recognition bar movement unit is for moving the recognition bars 1410 independently. The recognition bar moving section may include a recognition bar guide section, elastic members 1440 for the recognition bar, a movable frame 1450, and a movable frame moving section.

The recognition bar guide unit guides the elevation of the recognition bars 1410. The recognition bar guide portion may include a lower frame 1431, a vertical frame 1432, and an upper frame 1434. [ The lower frame 1431 passes through the lower ends of the recognition bars 1410 to guide the upper and lower sides thereof. The vertical frame 1432 is vertically protruded from the lower frame 1431 between the pattern plate 1470 and the recognition bars 1410. The vertical frame 1432 is formed with guide holes 1433 for supporting the projecting pins 1411 of the recognition bars 1410 in a vertically movable manner. The upper frame 1434 is engaged with the vertical frame 1432 at the upper side of the lower frame 1431 and guides the upper end of the recognition bars 1410 through the upper ends thereof.

The elastic members 1440 for the recognition bar are installed on the upper sides of the projecting pins 1411 to apply an elastic force in the direction of lowering the recognition bars 1410. For example, the elastic members 1440 for the recognition bar may be respectively made of compression coil springs. Each of the elastic members 1440 for the recognition bar is supported by the lower surface of the upper frame 1434 with the upper end thereof fitted in the upper end of the recognition bar 1410 and the lower end of the elastic member 1440 by the engagement protrusions formed on the upper side of the projecting pin 1411 It is possible to apply an elastic force in the direction of lowering the recognition bar 1410. [

The movable frame 1450 is disposed so as to correspond to the lower side of each of the projecting pins 1411 so as to move the recognition bars 1410 up and down. That is, in the process of the movable frame 1450 being lifted up to the maximum, the projecting pins 1411 are supported by the movable frame 1450 so that the recognition bars 1410 rise. At this time, compression forces are applied to the elastic members 1440 for the recognition bar, respectively, so that the recognition bars 1410 are in a state of receiving the elastic force in the downward direction.

In this state, when the movable frame 1450 is moved down to the maximum, the recognition bars 1410 are lowered by the restoring forces of the elastic members 1440 for the recognition bar. At this time, the recognition bars corresponding to the through-hole patterns 12 among the recognition bars 1410 are lowered until they are inserted into the passages 12a. The recognition bars corresponding to the first non-penetrating pattern 14 among the recognition bars 1410 are lowered until they are contacted with the first non-conductors 14a. The recognition bars corresponding to the second non-through hole pattern 15 among the recognition bars 1410 are inserted into the second non-through holes 15a and descend until they are contacted.

The movable frame moving part moves the movable frame 1450 in accordance with the rotation of the handle 112. The movable frame moving unit may include a rotating shaft 1461, a recognizing driving cam 1462a, and a recognizing driven cam 1462b. The rotation shaft 1461 is coupled to the rotation center of the second intermediate gear 1166b and rotates in accordance with the rotation of the knob 112. [ The rotating shaft 1461 is extended toward the operation table 121 side. The recognition drive cam 1462a and the recognition follower cam 1462b are formed in the same shape. The recognition drive cam 1462a and the recognition follower cam 1462b are provided on the rotary shaft 1461 so as to move the movable frame 1450 up and down together with the rotary shaft 1461. [

For example, the recognition drive cam 1462a and the recognition follower cam 1462b are disposed adjacent to both ends of the rotation shaft 1461. [ The movable frame 1450 includes a first movable portion 1451 disposed so as to correspond to each lower side of the projecting pins 1411 and a second movable portion 1451 that contacts the upper surfaces of the recognition drive cam 1462a and the recognition follower cam 1462b And a pair of second movable parts 1452 connected to each other. The second movable parts 1452 are kept in contact with the recognition drive cam 1462a and the recognition driven cam 1462b by the elastic members 1440 for the recognition bar so that the recognition drive cam 1462a, And can be moved up and down according to the rotating operation of the follower cam 1462b.

The recognition drive cam 1462a and the recognition follower cam 1462b are rotated 360 degrees in the forward or reverse direction according to the one rotation operation of the knob 112. [ Each of the recognition drive cam 1462a and the recognition follower cam 1462b moves to the top dead center so that the movable frame 1450 is lifted to the maximum, The movable frame 1450 is lowered to the maximum.

First, second, and third pattern holes 1471, 1472, and 1473 are formed in the pattern plate 1470. When the through hole pattern 12 and the first and second non-through holes 14 and 15 are combined and arranged in two rows in the longitudinal direction of the through hole card key 10, the pattern plates 1470 are provided in two, Respectively. The pattern plates 1470 are provided with an elastic force toward the recognition drive cam 1462a by the elastic member 1476 for the pattern plate.

The first, second and third pattern holes 1471, 1472 and 1473 are formed in such a manner that the height of the projecting pins 1411 when the recognition bars 1410 are lowered is smaller than the height of the hole pattern 12 and the first and second non- The protruding pins 1411 are guided by the elastic members 1476 for the pattern plates so that the pattern plates 1470 can be slidably moved toward the recognition driving cam 1462a respectively . When the pattern plates 1470 slide toward the recognition drive cam 1462a, the drive block 1483 is connected to the driven block 1481 in the rotational force interrupting portion 1480 as described later. In this state, when the driving block 1483 rotates, the operating block 121 can be rotated by the rotation of the driven block 1481. [

16 to 18, the first pattern hole 1471 is connected to the lower ends of the first vertical long hole 1471a and the first vertical long hole 1471a, and extends from the recognition driving cam 1462a And a first horizontal long hole 1471b formed in a direction perpendicular to the first direction. The first horizontal long hole 1471b is positioned so as to receive the projecting pin 1411 in a state where the recognition bar corresponding to the through hole pattern 12 of the recognition bars 1410 is inserted into the passage 12a, ) Can be slid toward the recognition drive cam 1462a.

The second pattern hole 1472 is composed of a second horizontal long hole 1472b connected to the upper ends of the second vertical long hole 1472a and the second vertical long hole 1472a and formed in a direction away from the recognition drive cam 1462a . The second horizontal long hole 1472b is positioned so as to receive the projecting pin 1411 in a state where the recognition bar corresponding to the first non-communicating pattern 14 among the recognition bars 1410 is in contact with the first non-passage 14a , So that the pattern plate 1470 can slide toward the recognition drive cam 1462a.

The third pattern hole 1473 is connected to the upper ends of the third vertical long hole 1473a and the third vertical long hole 1473a to form a third horizontal long hole 1473b formed in a direction away from the recognition drive cam 1462a Lt; / RTI > The third horizontal long hole 1473b is formed so that the recognition bar corresponding to the second non-communicating pattern 15 among the recognition bars 1410 is inserted into the second non-passage 15a to receive the projecting pin 1411 Thereby allowing the pattern plate 1470 to slide toward the second recognition drive cam 1462a.

Therefore, as shown in FIG. 16, when the recognition bars 1410 are raised and then lowered as shown in FIG. 17, the passage 12a and the second non-passage 15a Are positioned so as to be received in the first and third horizontal elongated holes 1471b and 1473b while descending along the first and third vertical elongated holes 1471a and 1473a, The protruding pin 1411 corresponding to the second horizontal elongated hole 15a is positioned to be received in the second horizontal elongated hole 1472b without descending along the second vertical elongated hole 1472a. Then, as shown in Fig. 18, the pattern plate 1470 is slid toward the recognition drive cam 1462a by the elastic member 1476 for the pattern plate. The drive block 1483 is connected to the driven block 1481 in the rotational force intermittent portion 1480 and the drive block 1483 is connected to the drive block 1483 in this state, The operating rod 121 can be rotated by the rotation of the driven block 1481. [

The rotational force intermittent portion 1480 transmits the rotational force of the handle device 110 to the operating rod 121 in a state in which the pattern plates 1470 slide toward the recognition driving cam 1462a. The rotational force intermittent portion 1480 may include a driven block 1481, a supporting block 1482, and a driving block 1483. In the driven block 1481, a pair of latching protrusions 1481a are formed at regular intervals on the surface facing the recognition drive cam 1462a, and the operation pad 121 is coupled to the opposite surface. When the driven block 1481 rotates, the operating rod 121 rotates together.

The support block 1482 is coupled to the pattern plates 1470 and slides together, and rotatably supports the driven block 1481. The driving block 1483 is provided at the end of the rotating shaft 1461 and rotates together with the rotating shaft 1461. The driving block 1483 has a pair of latching grooves 1483a for engaging with the latching protrusions 1481a while the pattern plates 1470 slide toward the recognition driving cam 1462a.

The operation of the above-described rotational force interrupter 1480 will be described with reference to FIGS. 19 to 21. FIG. 19, even if the handle 112 is rotated before the hole card key 10 is inserted into the key insertion portion 130 or when the hole card key 10 fails to be recognized, 1483 and the driven block 1481 are spaced apart from each other, the rotational force of the driving block 1483 is not transmitted to the driven block 1481.

20, when the recognizing drive cam 1462a and the recognition follower cam 1462b are rotated 180 degrees in either direction, when the recognition of the through hole card key 10 is successful, the pattern plate 1470 Are moved toward the recognition drive cam 1462a so that the retaining block 1482 moves along with the pattern plates 1470 so that the retaining protrusions 1481a of the follower block 1481 move to the side of the drive block 1483 Respectively, into the engaging grooves 1483a. In this state, when the recognition drive cam 1462a and the recognition follower cam 1462b continue to rotate in the same direction, the follower block 1481 rotates to rotate the operation table 121 . The operation unit 121 can switch the lock assembly into the locked state or the unlocked state in accordance with the direction of the rotational force transmitted from the handle device 110. [

The key return operation part 150 may be configured such that when the recognition drive cam 1462a and the recognition follower cam 1462b rotate to 360 degrees after the lock assembly is unlocked or locked, (130). Therefore, after the door is unlocked or locked, the user can retrieve the card pocket key 10.

The key return operation part 150 may include a pushing pin 151 and a pushing projection 152. [ The pushing pin 151 protrudes from the drive block 1483 toward the support block 1481. [ The pushing protrusion 152 is pressed against the pushing pin 151 in a process in which the recognition drive cam 1462a and the recognition follower cam 1462b continue to rotate in the same direction up to 360 degrees after the lock assembly is unlocked or locked So that the pattern plates 1470 can be returned to their original positions.

The operation of the key return operation unit 150 will now be described. When the recognition drive cam 1462a and the recognition follower cam 1462b further rotate in the same direction in the state where the lock assembly is unlocked or locked, the pushing pin 151, as shown in Fig. 22, And pushes the support block 1482 together with the pushing projection 152 in the direction away from the recognition drive cam 1462a. As a result, the pattern plates 1470 are returned to their original positions, and the driving block 1483 and the driven block 1481 are separated from each other.

In this state, the pushing pin 151 moves along the projecting surface of the pushing projection 152 while the recognition drive cam 1462a and the recognition follower cam 1462b further rotate to 360 degrees in the same direction The movable frame 1450 keeps the distance between the driving block 1483 and the driven block 1481 apart and the movable frame 1450 ascends to the maximum by the recognition driving cam 1462a and the recognition driven cam 1462b. Thereby, the recognition bars 1410 are raised such that they are all separated from the cavity card key 10 by the movable frame 1450. Accordingly, the user can retrieve the through card key 10 from the key inserting portion 130.

23, the door lock 100 may further include a position sensor 160 and a power control unit 170. [ The position sensor 160 detects whether the operation pedestal 121 is in the lock position for locking the lock assembly. A sensor dog 161 may be provided on the operation table 121. The sensor dog 161 is fixed to the operation table 121 and rotates together with the operation table 121. The sensor dog 161 may be configured as shown in FIG. The position sensor 160 is installed to sense the sensor dog 161 in a state in which the operation table 121 is rotated to the lock position. The position sensor 160 may be a hall sensor. In this case, the sensor dog 161 may be provided with a permanent magnet. The hall sensor can sense whether the operating rod 121 is in the locked position according to whether or not the permanent magnet of the sensor dog 161 is detected.

As another example, the position sensor 160 may be an optical sensor including a light emitting portion and a light receiving portion. In this case, the light emitting portion and the light receiving portion may be arranged to enter the sensor dog 161 in a state in which the operating rod 121 is rotated to the lock position. The light emitting unit and the light receiving unit can detect whether the operation pad 121 is in the locked position by sensing whether the sensor dog 161 is entering or exiting. In addition, the position sensor 160 may be configured in a variety of ways to perform the functions described above.

When it is determined that the operation unit 121 is in the locked position based on the information detected by the position sensor 160, the power control unit 170 cuts off the power required for authentication of the digital door lock. When it is determined that the operation unit 121 is switched from the locked position to the unlocked position, the power control unit 170 supplies again the power required for authentication of the digital door lock.

Thus, when the user locks the lock assembly by switching the operation lever 121 from the unlock position to the lock position using the card slot key 10, the digital door lock becomes unusable. In this state, the operation card 121 can be switched to the unlocking position only by using the card pocket card 10 again in order to unlock the card bundle, thereby further enhancing the security.

A process of operating the key recognition device 120 by the handle device 110 in the door lock 100 will now be described. Here, the operating rod 121 receives the rotational motion in the forward direction from the handle 110, rotates from the locked position to the unlocked position, receives the rotational movement in the reverse direction from the handle 110, As shown in FIG.

The user inserts the hole card key 10 into the key inserting portion 130 of the key recognizing device 120 and inserts the handle 112 of the handle device 110 After rotating from the initial position to the operating position, release it. Then, the key recognition device 120 receives the rotational force of the handle 110 and performs recognition of the card 10, and when the recognition is successful, the rotational force of the handle 110 is transmitted to the operation base 121 . At this time, if the forward rotational motion from the handgrip device 110 is transmitted to the key recognition device 120, the operation base 121 rotates from the locked position to the unlocked position by the forward rotational motion. Thereby, the lock assembly can be switched from the locked state to the unlocked state by the operation member 121. [

If the rotational movement in the reverse direction from the handle device 110 is transmitted to the key recognition device 120, the operation band 121 rotates counterclockwise from the locked position by the reverse rotational movement. At this time, the lock assembly can idle the operation table 121 and detect the idle state of the operation table 121 and provide the digital door lock. The digital door lock can notify the user that it is locked. In this state, when the user rotates the handle 112, which is automatically returned to the initial position, to the operation position again, the forward rotational motion from the handle device 110 is transmitted to the key recognition device 120. Then, the operation unit 121 is rotated to the unlocking position by the forward rotational motion, so that the lock assembly can be switched from the locked state to the unlocked state.

In this way, when the through card key 10 is valid, the user can conveniently switch the lock assembly from the locked state to the unlocked state by turning the knob 112 once or twice in the same manner. When the operation card 121 is in the unlocking position and the card slot key 10 is enabled, if the user rotates the knob 112 once or twice in the same manner, the lock assembly is released from the unlocked state It can be conveniently switched to the locked state.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

10 .. Notch card key 110 .. Handle device
111 .. case 112 .. handle
113 .. Returning elastic member 114 .. Drive gear
115. One-way rotation induction unit 116. Motion transmission unit
120 .. Key recognition device 121 .. Operation stand
130. A key inserting unit 140. A key recognizing unit
150 .. key return operation part 160 .. position sensor
170. Power control unit

Claims (7)

A case mounted on the outdoor side of the door;
A handle rotatably reciprocating between an initial position and an operating position outside the case;
A resilient member for returning the handle in a direction in which the handle is returned to the initial position in the case;
A drive gear disposed coaxially with the rotational center shaft of the handle in the case and relatively rotatable with respect to the handle;
A one-direction rotation inducing unit for transmitting the rotational force of the handle to the driving gear to rotate the driving gear in one direction only while the knob is rotated from the initial position to the operating position in one rotation of the knob; And
A motion transmission unit that receives a rotational motion of the driving gear and alternately outputs rotational motion in a forward direction and rotational motion in a reverse direction each time the knob rotates once;
And the door lock handle device of the through card key recognition method.
The method according to claim 1,
The one-
A rotation block fixed on the same axis as the rotational center axis of the handle and rotatably supported on the case,
A rotation control plate fixed to the inside of the driving gear and rotatable together with the driving gear and having latching grooves arranged at an angle equal to a maximum rotation angle of the handle,
An engaging pin provided on the rotating block so as to be slidable in a radial direction of the rotating block so as to be inserted into or separated from any one of the engaging grooves;
A first latching elastic member for applying an elastic force to the latching pin such that the latching pin is separated from any one of the latching grooves while the knob is rotated from the initial position to the operating position,
And an elastic member for a second latching pin for applying an elastic force to the latching pin such that the latching pin is inserted into a subsequent latching groove of the latching grooves while the knob is rotated from the operation position to the initial position. A key recognition type door lock handle device.
3. The method of claim 2,
And a stopper block selectively inserted into the first and second stopper grooves formed around the rotation block,
The first stopper groove restricts the handle to rotate from the initial position on the left side of the door to the operating position in a counterclockwise direction with the stopper block sandwiched therebetween,
Wherein the second stopper groove restricts rotation of the handle from an initial position on the right side of the door to an operating position in a clockwise direction with the stopper block sandwiched therebetween.
The method according to claim 1,
Wherein the motion transmission unit comprises:
A driven gear engaged with the drive gear,
A cam member fixed to a rotating shaft of the driven gear,
A rack gear which is in close contact with the cam member and reciprocates in a sliding manner in accordance with the rotation of the cam member in one direction,
A rack gear guide portion for guiding the movement of the rack gear in a state in which the rack gear is in tight contact with the cam member,
And a pinion gear engaged with the rack gear.
5. The method of claim 4,
The rack gear guide portion
A movable pin protruding from a position away from the center of rotation of the cam member,
The rack gear being mounted to the case so as to be slidable in a direction parallel to the moving direction of the rack gear and guiding the movement of the movable pin to keep the rack gear in a state of being in tight contact with the cam member Wherein the guide block includes a guide block having a hole formed therein.
A handle device according to any one of claims 1 to 5,
An operating base which rotates in the forward and reverse directions to lock or unlock the catch bundle installed on the inside of the door;
A key insertion unit for inserting a through hole card key having a through hole pattern and a non-through hole pattern; And
And a controller for receiving a rotational motion from the motion transmitting part and performing a recognition operation on the card key card in a state where the card insertion key is inserted into the key inserting part to transmit the rotational motion of the motion transmitting part to the operation upon successful recognition A key recognition unit;
A door lock of a cardholder card key recognition method including a door key.
The method according to claim 6,
A position sensor for detecting whether the operating member is in a locking position for locking the cushion bundle; And
A power controller for shutting off a power source required for authentication of a digital door lock that locks or unlocks the lock assembly by digital authentication when it is determined that the operation console is in a lock position based on information detected from the position sensor;
Further comprising a keypad for receiving the card key.

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