JP4343401B2 - Electronic cylinder lock - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic cylinder lock that permits a locking and / or unlocking operation when a usable identification code is received from an inserted key.
[0002]
[Prior art]
Conventionally, a key storing an identification code and the validity of this key are judged, and if it is valid, the operation part of the key and the locking / unlocking mechanism of the lock body are linked and locked. Japanese Patent Application Laid-Open No. 8-158715 discloses an electronic cylinder lock that enables an unlocking operation.
According to this electronic cylinder lock, by inserting the key into the insertion portion, the insertion portion and the locking / unlocking mechanism can be connected. That is, when a valid key is inserted, the key can be rotated. When the operation is transmitted and the unlocking / unlocking operation is enabled, and the unauthorized key is inserted, the key rotation operation is not transmitted and the locking / unlocking operation is impossible. And if a key is extracted from an insertion part, the connection state with a locking / unlocking mechanism will be cancelled | released with the elastic force of the spring arrange | positioned inside an insertion part.
[0003]
[Problems to be solved by the invention]
However, according to the above-described conventional electronic cylinder lock, connection and release with the locking / unlocking mechanism are performed by the key inserted / removed with respect to the insertion portion, and operation with the key is required again after the locking / unlocking operation. In other words, the mechanism for returning to the unconnected state is a structure using a spring, and since this spring is arranged in the insertion portion where the key is inserted and removed, dust or the like enters the insertion portion, If trouble occurs in the operation, the return to the unconnected state is not performed. That is, even if the key is removed after the operation with a valid key, the connection state with the locking / unlocking mechanism cannot be released. There was a problem that would allow operation. Further, in such a state, there arises a problem that the unlocking / unlocking operation is possible even with a tool that is not a key, for example, a tool that can be inserted into an insertion portion such as a driver.
[0004]
Therefore, in order to solve the above problem, the present invention performs the unlocking / unlocking operation with the key only on the legitimate key, and the unlocking / unlocking operation is performed in a state where the key is removed without causing malfunction such as malfunction. An object of the present invention is to provide an electronic cylinder lock in which the connection state with the lock mechanism is reliably released.
[0005]
[Means for Solving the Problems]
Next, means for solving the above problems will be described with reference to the drawings corresponding to the embodiments.
The electronic cylinder lock 1 of the present invention includes a slot 15 into which the insertion portion 64 of the key 60 is inserted, and when receiving a legitimate identification code from the inserted key 60, the electronic cylinder lock 1 is operated to lock and / or unlock. In the permitted electronic cylinder lock,
The inner cylinder 10 that has the slot 15 and is rotated by the key 60 and the tail piece 50 that is interlocked and connected to the locking and unlocking mechanism in the lock box are connected by the key 60 having the legitimate identification code. A connecting means 18 that is connected when a locking operation and / or an unlocking operation are performed;
Connection release means 33 for releasing the connection state between the inner cylinder 10 and the tail piece 50 by the connection means 18 when the inner cylinder 10 is rotated after the locking and / or unlocking operations are performed,
It is characterized by comprising.
[0006]
The inner cylinder 10 preferably has a configuration in which the slot 15 into which the insertion portion 64 of the key 60 is inserted and the space portion 13 in which the connecting means 18 is arranged are separated by a partition wall.
[0007]
Further, the insertion portion 64 of the key 60 has a position where the key 60 can be inserted into and removed from the slot 15 of the inner cylinder 10, and the key 60 rotates at a predetermined position rotated by a predetermined angle from the position where the insertion is possible. A rotation stop means 6 for temporarily stopping may be provided, and the identification code may be received at the position of the rotation stop means 6. Further, the rotation stop means 6 may stop the rotation at the predetermined position. Detection means 7 and 65 for detecting the insertion portion 64 of the key 60 may be arranged.
[0008]
Further, the rotation stopping means 6 may be provided in both the right and left rotation directions with respect to the detachable position.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a schematic cross-sectional view showing an embodiment of an electronic cylinder lock according to the present invention.
The electronic cylinder lock 1 is generally composed of an outer cylinder 2, an inner cylinder 10, a tail piece 50, a connecting means 18, and a connection releasing means 33.
The electronic cylinder lock 1 described in the present embodiment normally has a key hole 14 in a vertical state, and is locked and / or unlocked by rotating 90 ° clockwise from this state. Will be described.
[0010]
First, the key 60 used for the electronic cylinder lock 1 will be described.
As shown in FIGS. 2A and 2B, the key 60 is substantially constituted by a gripping portion 61 and an insertion portion 64, and is formed in a substantially plate shape.
The grip 61 has a small battery 62, for example, a button-shaped battery, and an electronic circuit 63 that operates by receiving power supply from the battery 62.
The electronic circuit 63 stores a unique identification code of the key 60 itself, and includes a signal generation circuit that transmits a signal to a transmission antenna 66 described later.
[0011]
In addition, the insertion unit 64 includes a reed switch 65 as a detection sensor connected to the electronic circuit 63 and a transmission antenna 66 that transmits a signal from the signal generation circuit. The electronic circuit 63 does not normally operate with the battery 62 as a power source, but is powered on by a reed switch 65.
As shown in FIGS. 2 (a) and 2 (b), the insertion portion 64 is formed in a substantially rectangular plate shape and extends outward in the width direction in a substantially flange shape on a base portion 64a adjacent to the grip portion 61. A pair of retaining pieces 67 are provided.
[0012]
Next, the outer cylinder 2 which comprises the electronic cylinder lock 1 is formed in a substantially cylindrical shape, and is fixed to a lock main body (not shown).
One end 2a of the outer cylinder 2 is formed on the outdoor surface of the door, for example, and a circular hole 3 is formed through which the insertion portion 64 of the key 60 described above for performing the operation of locking and unlocking the electronic cylinder lock 1 is passed. Has been.
[0013]
As shown in the developed view of the outer cylinder 2 in FIG. 3, a pair of upper and lower cutouts 4 that are opposed to the center in the inner peripheral edge portion are formed in the hole portion 3. The distance between the notches 4 and 4 is set to be the width of the retaining piece 67 in the insertion portion 64 of the key 60, that is, the insertion portion 64 of the key 60 can be inserted and removed at the position of the notches 4 and 4. In this way, it is a position where it can be inserted and removed.
Further, the inner peripheral edge portion of the hole portion 3 has a shape having a thickness in the axial direction of the outer cylinder 2, and a guide groove 5 is formed on the peripheral surface of the inner peripheral edge portion.
[0014]
As shown in FIG. 1B, the guide groove 5 is formed in a substantially Z shape, and is formed continuously with the notch 4 which is a detachable position. That is, the concave groove 5a is formed straight from the position of the notch 4 to the position of about 45 ° along the circumferential direction of the inner peripheral edge, and the straight reaching the position of 90 ° in the circumferential direction from this 45 ° position. Concave grooves 5b are formed and are continuously formed through stepped portions 5c formed in the axial direction at 45 ° positions of these grooves.
[0015]
The guide grooves 5 are provided in the respective cutouts 4, that is, formed so as to face each other as shown in FIG. A retaining piece 67 protruding from the insertion portion 64 of the key 60 entering from the notches 4 and 4 is guided and slidably moved in the guide grooves 5 and 5, that is, this guide. While the retaining piece 67 is moving in the grooves 5 and 5, the key 60 cannot be removed in the axial direction.
[0016]
In addition, the step part 5c used as the 45 degree position of these guide grooves 5 and 5 comprises the control wall 6 as a rotation stop means. In addition, the outer cylinder 2 is provided with a magnet 7 at a position corresponding to a groove hole 15 portion of the inner cylinder 10 which will be described later, as well as being positioned on the inner peripheral surface 2c corresponding to the restriction wall 6. Yes. This magnet 7 constitutes a detecting means together with the reed switch 65 of the insertion portion 64 of the key 60 and detects the rotational position of the key 60.
[0017]
Further, the other end 2b of the outer cylinder 2 is provided with a through hole 8 having an inner diameter slightly smaller than the inner diameter of the outer cylinder 2, and a tail piece 50 described later is rotatably passed therethrough. . Further, a cylindrical cam 36 constituting a connection release means 33 described later is formed on the inner peripheral surface 2 c of the outer cylinder 2. The cylindrical cam 36 is formed with a concave portion 37 with respect to the inner peripheral surface 2c, and is formed within a range of about 90 ° in the circumferential direction as shown in the development view of the outer cylinder 2 in FIG. A pair is formed at a position interval facing each other.
[0018]
Next, the inner cylinder 10 is formed in a substantially cylindrical shape having an outer diameter substantially equal to the inner diameter of the outer cylinder 2, and is rotatably provided in the outer cylinder 2. In a state having a slight clearance with the peripheral surface 2c, and with a lubricant such as grease between the outer peripheral surface 10c of the inner tube and the inner peripheral surface 2c of the outer tube 2, It is provided so that it can rotate smoothly.
[0019]
The inner cylinder 2 has a partition wall 11 formed in the center in the axial direction in the inner space, and has a shape that does not penetrate from one end 10a to the other end 10b. The inner space 2 has a space portion 12 on one end side and a space portion 13 on the other end side. Separated configuration.
The space portion 12 on the one end side is located on the one end 2a side of the outer cylinder 2, and a substantially slit-shaped key hole 14 is formed on the end surface to constitute the groove hole 15 into which the insertion portion 64 of the key 60 is inserted. ing.
In the slot 15, an identification code transmitted from the transmission antenna 66 of the key 60 is received in a bowl-like space that is a position that does not interfere with the insertion portion 64 of the key 60 to be inserted, and the connecting means 18 described later. A receiving antenna 20 is disposed for transmission to the terminal.
[0020]
Further, the connecting means 18 and the releasing means 33 are disposed in the space 13 on the other end side 10b.
The connecting means 18 is generally constituted by an electronic circuit unit 19, a control mechanism unit 22, and a connecting mechanism unit 26.
The electronic circuit 19 has the receiving antenna 20 formed in a loop shape, for example, connected through the partition wall 11 and stores an identification code unique to the comparison calculation means, the drive signal output means, and the cylinder lock. Consists of storage means.
[0021]
The control mechanism 22 has a swinging claw 23 that is formed in a hook shape and a base end is swingable and is disposed along the axial direction in the space 13. The control mechanism 22 swings the swinging claw 23. The actuator 24 is moved. In the control mechanism 22, the actuator 24 is driven based on the signal sent from the drive signal output means of the electronic circuit 19, and the swing claw 23 is swung.
The swinging claw 23 is provided with an urging member (not shown) such as a torsion coil spring, and in a normal state, the urging force of the urging member is brought into a state parallel to the axial direction. Maintained.
[0022]
The coupling mechanism portion 26 is generally composed of a moving block 27 and a meshing clutch 32.
The moving block 27 is provided so as to be slidable in the axial direction in the space 13 on the other end side of the inner cylinder 10, and is formed in, for example, a substantially cylindrical shape.
[0023]
On one end face 27a of the moving block 27, an engaging claw 28 having a tip formed in a hook shape at a substantial center is projected in the axial direction. The engagement claw 28 is adapted to engage with the swing claw 23.
Further, an urging member 29 made of a compression coil spring is disposed between one end surface 27 a of the moving block 27 and the partition wall 11. By this urging member 29, the moving block 27 is always urged toward the other end side 10 b of the inner cylinder 10.
[0024]
On the other end face of the moving block 27, a shaft body 31 extends in the axial direction at the center, and one of the meshing clutches 32 is disposed at the tip of the shaft body 31.
In the meshing clutch 32, for example, rectangular teeth are continuously formed in the circumferential direction on the surfaces of a pair of disks facing each other, and interlocking coupling is performed by meshing the teeth facing each other, and one clutch plate 32a moves. The other clutch plate 32b is connected to the shaft body 31 of the block 27, and is provided on a tail piece 50 described later.
[0025]
Further, a pair of pins 34, 34 extending outward are provided on each side surface having a positional relationship of 180 ° with respect to the center of the moving block 27.
These pins 34, 34 pass through a pair of guide slits 35, 35 formed on the peripheral wall of the inner cylinder 10, and each tip protrudes from the outer peripheral surface 10 c of the inner cylinder 10. Each guide slit 35, 35 is formed in a straight line parallel to the axial direction, and supports each pin 34, 34 so as to be slidable in the same direction as the axial direction. That is, the movement block 27 moves in the axial direction within the inner cylinder 10. It is designed to provide guidance.
[0026]
And these pins 34 and 34 comprise the connection release means 33 with the cylindrical cam 36 which consists of a recessed part formed in the outer cylinder inner peripheral surface 2c mentioned above.
The cylindrical cam 36 will be described in detail. As shown in the development view of the outer cylinder 2 in FIG. 3, the cylindrical cam 36 includes a concave portion 37 continuously formed in the circumferential direction R of the inner peripheral surface 2c at 90 °. The pin 34 is configured to have a pair of opposing ends corresponding to 34 and set to a depth at which the tip ends of the pins 34 are inserted. As shown in FIG. 3, these concave portions 37 are formed in a substantially trapezoidal shape that connects the narrow portion 39 and the large portion 41 by the oblique side portion 43, and are formed in the notch 4 formed at one end 2 a of the outer cylinder 2. It is formed within a range of about 90 ° in the circumferential direction R having the same length as the guide groove 15 from the corresponding position. The small width portion 39 of each concave portion 37 is located at a position corresponding to the notch 4 formed in the one end 2a of the outer cylinder 2 in the axial direction S, and is widened from the small width portion 39 to the other end side 2 of the outer cylinder 2. In this way, the hypotenuse part 43 is continuously formed, and the large part 41 and the narrow part 39 are continuously formed at the hypotenuse part 43, and a pair of straight and short straight lines having the same direction as the circumferential direction R perpendicular to the axial direction S are formed. The side parts 45 and 47 have, the long side 45 side is located in the one end side 2a of the outer cylinder 2, and the short side 47 is located in the other end side 2b. The distance in the circumferential direction R of the short side 47 is about 45 °, and the distance in the circumferential direction of the oblique side 43 is also about 45 °. In the cylindrical cam 36 formed of the concave portion 37, the interval in the axial direction S between the long side 45 and the short side 47 is a stroke, the short side 47 side is in a position where the clutch 32 is connected, and the long side 45 is connected. Will be in a position to release.
The tip of the pin 34 can be moved in the recess 37 and can slide on the side portions 43, 45, 47.
[0027]
Next, the tail piece 50 is formed in a substantially disk shape, and on one plate surface, the other clutch plate 32b of the meshing clutch 32 that constitutes the connecting means described above is formed, and on the other plate surface. Is formed with a protruding portion 51 having a predetermined shape.
The tail piece 50 is provided inside the other end side 2b of the outer cylinder 2 so that its periphery is rotatably supported. A connecting portion 51 passes through a through hole 8 drilled in the other end 2b. Projects outward in the direction.
The connecting portion 51 of the tail piece 50 is interlocked and connected to a locking / unlocking mechanism (not shown). That is, the tail piece 50 rotates to move a locking member such as a dead bolt that makes up the lock body. It is connected to the member.
[0028]
Next, the operation of the electronic cylinder lock 1 will be described.
First, when the key 60 is not inserted and the lock body is in the locked state or the unlocked state, as shown in FIG. 5, the engagement clutch 32 is not engaged with each other, and the inner cylinder 10 and the tailpiece 50 are not engaged. Is a state in which the connection is released, the engagement claw 28 and the swing claw 23 are engaged, and each pin 34 of the moving block 27 is located in the small width portion 39 of the cylindrical cam 36. It is said.
[0029]
Next, when unlocking from the locked state of the lock body, or when locking from the unlocked state, the key 60 is first inserted into the slot 15 of the inner cylinder 10 as shown in FIG.
When the insertion portion 64 of the key 60 is inserted into the groove hole 15, the retaining piece 67 protruding from the insertion portion 64 enters the guide groove 5 from the notch 4 of the outer cylinder 2.
In this state, the connecting means 18 in the inner cylinder 10 does not operate, and the inner cylinder 10 and the tail piece 50 are not connected as shown in FIG.
[0030]
Next, when the key 60 is rotated, the retaining piece 67 of the key 60 is slid and guided by the guide groove 5 of the outer cylinder 2. In this embodiment, it is rotated in the clockwise direction in FIG. At this time, since the retaining piece 67 passes through the guide groove 5, the key 60 cannot be removed in the axial direction.
[0031]
When the rotation of the key 60 reaches 45 °, the retaining piece 67 comes into contact with the regulating wall 6 in the guide groove 5 and the rotation of the key 60 is temporarily stopped as shown in FIG.
Then, the reed switch 65 disposed in the insertion portion 64 of the key 60 detects this by the magnet 7 provided in the outer cylinder 2 corresponding to this position, and the circuit 63 in the key 60 is energized. That is, the operation state is set. As a result, the electronic circuit 63 in the key 60 transmits a signal including the stored identification code from the transmission coil.
[0032]
The receiving antenna 20 in the slot 15 of the inner cylinder 10 receives this transmitted signal, so that power is supplied and the electronic circuit 19 in the space 13 of the inner cylinder 10 is activated, and the transmitted signal is The included identification code is received.
[0033]
The identification code transmitted and received from the key 60 used is compared with the identification code stored in the electronic circuit 19 in the inner cylinder 10, and the identification code stored in the inner cylinder 10 is compared with the identification code stored in the inner cylinder 10. If they match and are correct, the key 60 is valid for the electronic cylinder lock 1.
When the electronic circuit 19 determines that the key 60 is valid, the electronic circuit 19 outputs a drive signal to the actuator 24. The actuator 24 operates when receiving the drive signal, and swings the swing claw 23.
[0034]
When the swinging claw 23 swings, the engagement state with the engaging claw 28 is released, whereby the moving block 27 is moved in the direction of the other end 10b of the inner cylinder 10 by the biasing force of the biasing member 29.
When the moving block 27 is moved, as shown in FIG. 7, one of the mesh clutch 32 and the other clutch plate 32a, 32b mesh with each other, that is, the inner cylinder 10 and the tail piece 50 are connected to each other, and the key 60 is disengaged. The lock mechanism is linked and connected.
At the same time, the pins 34 protruding from the moving block 27 move in the axial direction and move to the short side 47 of the large portion 41 of the cylindrical cam 36.
The actuator 24 once swings the swinging claw 23, and after the engagement state with the engaging claw 28 is released, the operation is finished, and the swinging claw 23 is axially moved by the biasing force of the biasing member. It returns to the state parallel to the direction.
[0035]
Next, the key 60 is further rotated by 45 °, that is, 90 ° from the position where the key 60 is inserted, but the retaining piece 67 of the key 60 is in contact with the regulating wall 6 in the guide groove 5. The key 60 is inserted further into the back and then rotated 45 ° in the clockwise direction in FIG.
In this state, as described above, the key 60 and the locking / unlocking mechanism are rotated through the connection state of the inner cylinder 10 and the tail piece 50. In other words, when the key 60 is rotated, Then, the movement of the lock member such as a dead bolt is performed.
At this time, each pin 34 of the moving block 27 moves in the circumferential direction on the short side 47 of the cylindrical cam 36 as shown in FIG.
The lock body is unlocked or locked.
[0036]
Next, to remove the key 60 from this state, since the retaining piece 67 of the key 60 is in the guide groove 5, the key 60 is rotated in the reverse direction (counterclockwise in FIG. 9). It becomes.
When the key 60 is rotated in the reverse direction (counterclockwise direction), first, rotation of 45 ° is performed as shown in FIG.
During this operation, the retaining piece 67 of the key 60 moves in the guide groove 5, and at the same time, each pin 34 moves in the circumferential direction along the short side portion 47 of the cylindrical cam 36. That is, since the moving block 27 does not move, the meshing clutch 32 is engaged with each other.
[0037]
Next, since the restriction wall 6 is in the guide groove 5 at the 45 ° position, the key 60 is moved slightly in the pulling direction, the retaining piece 67 of the key 60 is moved along the guide groove 5, and then the key is further moved. 60 is rotated counterclockwise.
At this time, each pin 34 moves along the oblique side 43 of the cylindrical cam 36, whereby the moving block 27 resists the urging force of the urging member 29 from the other end side 10 b of the inner cylinder 10 to the partition wall 11. To the side (one end side 10a). At the same time, the meshing clutches 32 meshing with each other are moved away from the meshed state, that is, the coupled state between the tailpiece 50 and the inner cylinder 10 is released.
[0038]
Then, as shown in FIG. 10, when the rotation of the key 60 is returned to the position where the key 60 is inserted, each pin 34 returns to the small width portion 39, and the engaging claw 28 of the moving block 27 swings. It engages with the claw 23 and returns to the initial position.
Thereafter, the operation is completed by pulling out the key 60.
[0039]
Next, when an unauthorized key 60 is used for the electronic cylinder lock 1, the key 60 is inserted into the slot 15 and rotated by 45 ° in the same manner as described above, as shown in FIG. When paused at position 6, an identification code is transmitted from the electronic circuit in the key 60, and this identification code is received in the inner cylinder 10.
[0040]
If the electronic circuit 20 in the inner cylinder 10 determines that the identification code of the key 60 is not valid, the drive signal is not transmitted to the actuator 24.
As a result, the engaged state of the swinging claw 23 and the engaging claw 28 is not released, and the moving block 27 does not move in the inner cylinder 10.
[0041]
Even when the moving block 27 does not move, the key 60 can be further rotated 45 ° (rotated 90 ° from the key insertion position) by moving the retaining piece 67 along the guide groove 5. As shown in FIG. 12, the meshing clutch 32 is not engaged, and each pin 34 also moves along the long side portion 45 of the cylindrical cam 36.
In other words, in the case of the invalid key 60, the inner cylinder 10 and the tail piece 50 are rotated without being connected, and the idling state is obtained.
As a result, the locking / unlocking mechanism is not operated, and operations such as unauthorized unlocking are surely invalidated.
[0042]
Even if the key 60 to be used is a key that does not include the electronic circuit 63 having a very similar outer shape, the key 60 can be rotated, but the electronic circuit 19 in the inner cylinder 10 does not work. Therefore, the inner cylinder 10 and the tail piece 50 are not connected to each other, and the unlocking / unlocking operation using the key is invalid, and an unauthorized unlocking operation or the like can be prevented.
[0043]
Therefore, in the electronic cylinder lock 1 configured as described above, after the locking / unlocking operation is performed by the operation of the connecting means 18 using the valid key 60, the key 60 is removed in order to remove the key 60. When the turning operation is performed, the connection state between the inner cylinder 10 and the tail piece 50 is mechanically released by the pin 34 as the connection release means 33 and the cylindrical cam 36, and therefore, the normal state in which the operation with the key 60 is not performed. Then, the key 60 side and the locking / unlocking mechanism are always in a disconnected state, and safety as a locking device can be ensured.
[0044]
In addition, the inner cylinder 10 has a structure including the partition wall 11, and the slot 15 into which the key 60 is inserted and removed is separated from the mechanism part constituting the connecting means 18 for connecting the inner cylinder 10 and the tailpiece 50. Since it is configured, even if dust enters the slot 15, there is no mechanical operation in the slot 15, there is only a non-contact type electrical coupling, and there is a problem such as generation of malfunction due to dust. Therefore, the occurrence of malfunctions can be prevented.
[0045]
Further, the location where the validity of the key 60 is determined is a position rotated by a certain angle from the position where the key 60 is inserted, and the rotation of the key 60 is physically paused at this position. The electronic circuit 19, 63 can be linked between the key 60 and the inner cylinder 10 at the position of the restriction wall 6, which is the stop position, that is, ensuring the communication time for transmitting / receiving the identification code, and the key 60. It is possible to secure a time for supplying power from the terminal, reliably determine the legitimacy of the key 60, and ensure the subsequent operation of locking and unlocking.
[0046]
Further, by arranging the magnet 7 as the detecting means at the first stop position of the rotation of the key 60, it is possible to obtain the transmission / reception timing of the identification code and the like, as in the above embodiment. According to the configuration in combination with the reed switch 65, it is possible to manage the on / off of the power supply of the circuit itself and to prevent the battery 62 built in the key 60 from being consumed.
[0047]
In the above-described embodiment, the rotation direction of the inner cylinder 10 with respect to the outer cylinder 2 has been described as a one-way configuration in the clockwise direction, but it may be in the opposite counterclockwise direction, and can be rotated in both directions. It is good also as a simple structure. If the inner cylinder 10 and the tail piece 50 can be coupled by such rotation in both directions, a mechanical coupling structure for locking and unlocking can be obtained on the cylinder lock side.
[0048]
Further, in the above-described embodiment, the example in which the coupling means 18 uses the structure of the meshing clutch 32 and the actuator 24 has been described. However, the configuration is not limited thereto, and the electronic circuit 19 in the inner cylinder 10 is used. As long as it is a structure that performs mechanical operation from an electrical signal, such as a structure that directly drives the actuator 24 with a drive control signal that is transmitted and connects with the tailpiece 50, or a structure that uses an electromagnetic clutch mechanism, Also good.
[0049]
Further, the connection release means 33 is not limited to the configuration of the above-described embodiment, and has a structure in which the connection state between the inner cylinder 10 and the tailpiece 50 is released when the key 60 is rotated after the locking / unlocking operation. If there is any other configuration, for example, when the rotation of the key 60 is returned, in the above embodiment, the power is supplied from the key 60 because the position is returned to the 45 ° position. And it is good also as a structure which cancels | releases the connected inner cylinder 10 and the tailpiece 50 using an actuator etc. of another structure.
[0050]
In the above-described embodiment, the example in which the battery 62 as the power source is provided inside the key 60 has been described. However, the inner cylinder 10, the outer cylinder 2, the lock body side, and the like may have a power source. . In this case, it is not necessary to consider the consumption of the battery 62 on the key 60 side, and the key 60 can be configured only with a structure including an identification code, and can be configured simply.
[0051]
Further, in the above-described embodiment, the rotation angle of the key 60 is configured to be about 45 ° position and about 90 ° position, and the regulation wall 6 (rotation stop means) for temporarily stopping the rotation at the 45 ° position is provided. Although shown as an example of a configuration, the position of the rotation angle that is the stop position of this rotation is not limited to this, for example, it is temporarily stopped at a 15 ° position, and the identification code is determined at that position. The locking / unlocking mechanism may be operated by rotating up to a 45 ° position.
[0052]
Further, in the above-described embodiment, in the operation of locking / unlocking with the key 60, when the key 60 is removed from the slot 15, the operation of slightly pulling out at the 45 ° position is required. Since the stroke for pulling out the key 60 at the time of the removal operation is a short one that is a step portion in the guide groove 5, an elastic member that does not easily cause malfunction due to dust, for example, in the depth of the groove 15 in the inner cylinder 10, for example, By arranging a hemispherical rubber member, a spherical plate spring, etc., it becomes possible to generate a repulsive force against the inserted part of the inserted key, thereby making it easy to remove the key It is possible to make it happen.
[0053]
【The invention's effect】
As described above, according to the electronic cylinder lock according to the present invention, after a locking / unlocking operation is performed by the operation of the connecting means using a valid key, the key is rotated to remove the key. When the operation is performed, the connection between the inner cylinder and the tail piece is released by the connection release means. The locking mechanism is disconnected and the safety of the locking device can be ensured.
[0054]
In addition, since the inner cylinder has a structure including a partition wall, the slot into which the key is inserted and removed and the mechanism part that constitutes the connecting means for connecting the inner cylinder and the tail piece are separated, so that dust is removed. Even if it penetrates into the slot, there is no mechanical operation etc. in this slot and it is only non-contact type electrical coupling, there is no malfunction such as causing malfunction due to dust, preventing malfunction occurrence be able to.
[0055]
Furthermore, the location where the validity of the key is determined is a position rotated by a certain angle from the position where the key is inserted, and the structure is such that the rotation of the key is physically paused at this position. It is possible to link each electronic circuit between the key and the inner cylinder at the position of a certain rotation stop means, that is, to secure communication time for transmission / reception of the identification code and time for power supply from the key. It can be ensured, the validity of the key can be determined with certainty, and the subsequent operation of locking and unlocking can be ensured.
[0056]
Further, by arranging the detection means at the first stop position of the key rotation described above, it is possible to obtain the transmission / reception timing of the identification code and the like, for example, if it is configured as a combination of a magnet and a reed switch, It is possible to manage the power on / off of the circuit itself, and to prevent the battery built in the key from being consumed.
[0057]
In addition, the lock rotation and unlocking operations can be performed individually by providing a temporary rotation position for the key at a fixed angular rotation position in both the left and right directions with respect to the position where the key can be inserted and removed. Therefore, a reliable operation state as a locking / unlocking device can be obtained.
[Brief description of the drawings]
FIG. 1 (a) is a schematic front view showing an embodiment of an electronic cylinder lock according to the present invention.
(B) Cross-sectional side view
FIG. 2 (a) is a schematic side view of a key used in the electronic cylinder lock.
(B) Plan view
FIG. 3 is an exploded view of an outer cylinder constituting the electronic cylinder lock.
FIG. 4 is an explanatory view for explaining the locking and unlocking operation of the electronic cylinder lock.
FIG. 5 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
FIG. 6 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
FIG. 7 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
FIG. 8 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
FIG. 9 is an explanatory view for explaining the locking and unlocking operation of the electronic cylinder lock.
FIG. 10 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
FIG. 11 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
FIG. 12 is an explanatory diagram for explaining the locking and unlocking operation of the electronic cylinder lock
[Explanation of symbols]
1 ... Electronic cylinder lock
6 ... Rotation stop means (regulation wall)
10 ... Inner cylinder
11 ... Bulkhead
13 ... Space
15 ... Slot
18 ... Connecting means
33 ... Connection release means
50 ... Tailpiece
60 ... Key
64 ... Insertion section

Claims (4)

In the electronic cylinder lock that includes a slot into which the key insertion portion is inserted, and that allows a locking and / or unlocking operation when a valid identification code is received from the inserted key,
The inner cylinder that has the slot and is rotated by the key and the tail piece that is interlocked and connected to the locking and unlocking mechanism in the lock box are locked and / or unlocked by the key having the legitimate identification code. Connecting means for connecting when the locking operation is performed;
A connection release means for releasing the connection state between the inner cylinder and the tail piece by the connection means when the inner cylinder is rotated after performing the locking and / or unlocking operation ;
Furthermore, the rotation stop for temporarily stopping the rotation by the key at a predetermined position rotated by a predetermined angle from the position where the key insertion portion can be inserted into and removed from the slot of the inner cylinder. Means,
A detecting unit arranged at the predetermined position where the rotation is stopped by the rotation stopping unit and detecting the key insertion portion;
The electronic cylinder lock , wherein the identification code is received when the detecting means detects the key insertion portion .   2. The electronic cylinder lock according to claim 1, wherein the inner cylinder is configured such that a slot into which the key insertion portion is inserted and a space portion in which the connecting means is disposed are separated by a partition wall. . The electronic cylinder lock according to claim 1 or 2 , wherein the rotation stopping means is provided in both the right and left rotation directions with respect to the detachable position. A retaining piece projecting from the key insertion portion, and the retaining piece is inserted in a state where the key insertion portion is inserted into the groove of the inner cylinder so as to guide the rotation operation of the key. A guide groove formed on the inner peripheral surface of the end portion of the outer cylinder into which the inner cylinder is inserted, and a step portion in which the guide groove is continuous with the back in the axial direction at a middle portion in the circumferential direction of the guide groove A regulation wall that constitutes the rotation stopping means is formed, and a guide groove is continuously formed in the circumferential direction in the axially back part of the step part,
By rotating the inserted key to the position of the restriction wall that constitutes the rotation stopping means, the detection means receives the identification code, the inner cylinder and the tail piece are connected, and the key The inner cylinder and the tail piece are connected to each other so that the locking / unlocking operation can be performed by pushing the shaft further into the back from the regulating wall and then rotating along the continuous portion of the guide groove. The electronic cylinder lock in any one of thru | or 3 .

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