JP2000328822A - Coded lock device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To re-confirm the set content of an unlock code train by preventing complication and enlargement of internal mechanism by demolishing the unlock code train for the first time by using an operating tool. SOLUTION: On a front plate 3, there is a lug 16 for driving operational drive, four dials 50 for setting an unlock code train, and a push-button 31 for actuator 30 is arranged. When the lug 16 is operated after setting the unlock code train by the operation of each dial 50, a latch 1 is operated to close by the drive of operational drive, and the set unlock code train is memorized. Then, when the push-button 31 of the actuator 30 is pressed, the alignment of the unlock code train is destroyed while the unlock code train is kept memorized and a locked condition occurs.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lock device for use in a locker or a safe, and more particularly, the present invention relates to a code capable of setting an arbitrary unlock code sequence using a plurality of dials. It relates to a lock device.

[0002]

2. Description of the Related Art Conventionally, this kind of code lock device is, for example,
The latch is attached to the door of the lending locker, and the latch is pivoted forward and reverse to open and close by the shooting operation at the time of unlocking and locking, and is engaged and disengaged with the receiving bracket provided on the main body of the lending locker. This code lock device has a plurality of dials located at the front of the door, and by manually operating these dials,
The setting of the unlock code string is performed at the time of locking, and the alignment of the unlock code string is performed at the time of unlocking. The unlock code sequence set at the time of locking is stored by the storage mechanism.

At the time of locking, first, a plurality of dials are manually operated to set a desired unlocking code string, and then, when a photographing operation is performed, the latch engages with the receiving bracket of the main body,
The set unlock code sequence is stored in the storage mechanism. Next, when the unlock code string is appropriately broken by manually operating each dial, a locked state is formed by the lock mechanism while the unlock code string is stored and held. At the time of unlocking, if the unlocking code string is aligned by manually operating a plurality of dials, the locking mechanism will be in the unlocked state. Next, take a shooting operation and set the latch to the receiving bracket of the main body. Remove more.

However, in the case of the above-mentioned code locking device, at the time of the locking operation, it is mistaken that the locking is completed only by the shooting operation of engaging the latch with the receiving metal of the main body, and the unlock code string is broken. Sometimes you forget. As a result, the user is left in the unlocked state and is exposed to the danger of theft.

In order to solve such a problem, the applicant recently stores the set unlock code string in a storage mechanism when a shooting operation is performed after setting the unlock code string at the time of locking. At the same time, forcibly rotate each dial,
A code lock device configured to automatically break an unlock code sequence has been proposed (Japanese Patent No. 2564238 and Japanese Patent No. 276).
No. 9810).

[0006]

However, this type of code locking device has a structure in which the unlock code sequence is stored and the unlock code sequence is broken only by the shooting operation at the time of locking. There is a problem that the mechanism becomes complicated and large, and it takes time to manufacture and adjust. In addition, the unlocking code string is automatically broken by the shooting operation at the time of locking, so it is securely locked, but since the setting contents of the unlocking code string can not be reconfirmed after the shooting operation, the lock is locked in a hurry If you perform an operation,
A situation occurs in which the unlock code string is not memorized, which causes a trouble.

[0007] The present invention has been made in view of the above problem, and provided with a dedicated operating tool for breaking an unlock code sequence,
A structure that breaks the unlock code sequence only after operating this operating tool prevents the internal mechanism from becoming complicated and large, and enables the code lock to reliably reconfirm the settings of the unlock code sequence. It is intended to provide a device.

[0008]

According to the present invention, there is provided an operation drive unit driven by an operation for opening and closing a latch, setting of an unlock code sequence at the time of locking and alignment of the unlock code sequence at the time of unlocking. A plurality of dials pivoted for
A storage mechanism for storing an unlock code string set in response to the drive of the operation drive unit, and a unlocked code string formed in the locked state by forming a locked state by breaking the unlock code string after the operation of the storage mechanism A lock mechanism having a lock mechanism for forming an unlocked state by aligning the operation tools, an operation tool operated to break the unlock code string, and a predetermined angle by operating the operation tool. A rotary drive shaft; and a power transmission mechanism for transmitting the rotation of the rotary drive shaft to each dial and rotating each dial integrally. The power transmission mechanism, while the rotary drive shaft is rotated by a predetermined angle,
A control mechanism for controlling the rotation angle of each dial so as to rotate each dial from the current angular position to a predetermined angular position is included.

According to a second aspect of the present invention, the control mechanism comprises:
The dials are simultaneously rotated together with the rotation of the rotation drive shaft, and each time the rotation of each dial reaches a predetermined angular position, the rotation of each dial with the rotation drive shaft is individually released. It is of a configuration.

According to a third aspect of the present invention, the control mechanism comprises:
When the rotary drive shaft has rotated to the angular position corresponding to the current angular position of each dial, the individual rotation of each dial starts individually, and when the rotation of each dial reaches the predetermined angular position, it rotates. In this configuration, the rotation of the drive shaft is stopped.

[0011]

The unlock code sequence is set with a plurality of dials, the operation drive unit is driven to store the unlock code sequence in the storage mechanism, and then the operating tool is operated. Rotate by an angle. The rotation of the rotary drive shaft is transmitted to each dial by a power transmission mechanism, and each dial rotates integrally with the rotary drive shaft. In this case, while the rotary drive shaft rotates by a predetermined angle, each dial rotates from the current angular position to the predetermined angular position, so that the unlock code string is broken and becomes another code string, and the lock is locked. A state is formed.

According to the second aspect of the present invention, when the rotary drive shaft is rotated by the operation of the operating tool, the respective dials are simultaneously rotated together with the rotation of the rotary drive shaft, and the unlock code sequence is changed. Forcibly broken. Each time the rotation of each dial reaches a predetermined angular position, each dial is individually released from integral rotation with the rotation drive shaft, so that it finally becomes another predetermined code string,
A locked state is formed.

According to the third aspect of the present invention, when the rotary drive shaft rotates to the angular position corresponding to the current angular position of each dial, each dial individually starts rotating integrally, and each dial rotates. When the movement reaches the predetermined angular position, the rotation of the rotary drive shaft stops, so that the unlock code sequence is broken and becomes another predetermined code sequence, and the locked state is formed.

[0014]

1 and 2 show the appearance of a code lock device according to an embodiment of the present invention, and FIGS. 3 to 6 show the internal structure of the code lock device. This code lock device is attached to, for example, a door portion of a locker for rent, and a latch 1 of the code lock device rotates forward and backward by 90 degrees to engage and disengage with a receiving metal fitting 2 attached to a main body of the locker for rent. .

In the following description, a state in which the latch 1 is engaged with the receiving bracket 2 is a "closed state", a state in which the "closed state" is locked and held is a "locked state", and an unlocked state. The state is referred to as an “unlocked state”, and the state in which the latch 1 is detached from the receiving bracket 2 is referred to as an “open state”. The operation from “open state” to “locked state” through “closed state” is referred to as “locking operation”, and the operation from “closed state” to “open state” through “unlocked state” is referred to as “unlock operation”. " 1 to 6 show the appearance and internal structure of the code lock device in the "open state", and FIGS. 7 to 18 show the locking and unlocking sequence starting from the operation of setting the unlock code sequence in the "open state". The internal structure of each state up to the completion of the operation is shown step by step.

In the code lock device of the illustrated example, the upper surface opening of the box-shaped case 9 is closed by the front plate 3. A circular opening 4 is provided near one end of the front plate 3, four window holes 5 are provided from the center to the other end, and a rectangular opening 6 is provided below the opening 5.
Are provided respectively.

Inside the box-like case 9, an operation drive unit 10 is provided at the position of the circular opening 4, and a sign lock mechanism is provided at the position of the four window holes 5, and at the position of the rectangular opening 6. The operation tool 30 and the zero return mechanism 40 are incorporated respectively. From the circular opening 4, the cylindrical body 1 constituting the operation drive unit 10 is formed.
The upper end of 1 protrudes above the front plate 3. Tubular body 11
The camera 16 for locking and unlocking operations is attached to the camera. The shooting 16 is rotated in an angle range of 90 degrees. 3 and 4 show a state in which the photographing 16 has been removed.

The shooting 16 has a keyhole 17 for inserting a master key. The master key is used for emergency processing when the person who sets the unlock code string forgets the unlock code string. If a cylinder lock mechanism is incorporated in the operation drive unit 10, not only the master key but also a key for unlocking the cylinder lock is inserted into the key hole 17.

At the position of each window 5, four dials 50 used for setting an unlock code string are arranged. Each window hole 5
From above, the dial operation plate 51 of each dial 50 projects above the front plate 3. Each window hole 5 has a dial operation plate 5
1 has a long hole 7 protruding therefrom, and a rectangular hole 8 continuous with the long hole 7. From each rectangular hole 8, a code (a number from “0” to “9” in this embodiment) shown on each dial 50 appears.

The push button 31 of the operating tool 30 projects from the rectangular opening 6 onto the front plate 3. This push button 31
Is pressed during the locking operation to break the set unlock code sequence and lock. The operation of the push button 31 breaks the unlock code sequence, and sets the code sequence in which four “0” are arranged (hereinafter, referred to as “initial code sequence”). In this embodiment, even when the push button 31 is pressed after the end of the unlocking operation, the unlocking code string is broken and returns to the initial code string.

The lock device of the illustrated example has a structure for locking and a structure for setting and storing an unlock code sequence.
Includes a zero return mechanism for breaking the unlock code sequence and returning to the initial code sequence. Hereinafter, the operation drive unit 10, the operating shaft 20,
Four dials 50, a storage mechanism 60, a lock mechanism 80,
Each component such as the operation tool 30 and the zero return mechanism 40 will be sequentially described.

(1) Structure of the Operation Driving Unit 10 The operation driving unit 10 is constituted by a tubular body 11 which rotates integrally with the unlocking operation and the locking operation by the photographing 16. The cylindrical body 11 has a configuration in which an outer cylinder 13 is fitted on an outer periphery of an inner cylinder 12. Although not shown, a lock mechanism that operates by inserting a master key is incorporated in the inner cylinder 12. This lock mechanism has a plurality of disk tumblers, and when the master key is not inserted, all the disk tumblers are engaged with the grooves provided on the inner peripheral surface of the outer cylinder 13 and the inner cylinder 12 The tube 13 is integrated. When the master key is inserted, all of the disk tumblers are actuated and disengaged from the grooves of the outer cylinder 13, so that only the inner cylinder 12 can rotate independently.

On the outer peripheral surface of the outer cylinder 13, a first concave portion 14 facing the direction of the operating shaft 20 when the cylindrical body 11 is in the “open state” angular position, and the cylindrical body 11 Second recess 1 facing the operating shaft 20 when in the "position" angular position
5 are provided. The first concave portion 14 has a size in which the distal end of the operating shaft 20 and a front bush 61 described later fit together, and the second concave portion 15 has a size in which only the distal end of the operating shaft 20 fits. Each is formed.

(2) Structure of the Working Shaft 20 The working shaft 20 abuts on the outer peripheral surface of the tubular body 11,
Further, it has a hemispherical tip surface 21 that can be fitted into each of the first and second concave portions 14 and 15. A support shaft 22 protrudes from a base end of the operation shaft 20. The support shaft 22 is supported by a bearing 23 provided on a rear support plate 27 so as not to rotate. The front end portion of the operating shaft 20 is supported by a front bush 61, and the front bush 61 is supported by a bearing hole 24 formed in the front support plate 25. The operating shaft 20 is capable of reciprocating in a horizontal direction orthogonal to the operation drive unit 10. A compression spring 26 is mounted on the support shaft 22, and the operating shaft 20 is constantly urged toward the operation drive unit 10 by the spring force. On the peripheral surface of the operating shaft 20, four protrusions 82 constituting the lock mechanism 80 are integrally provided at the same angular position at regular intervals.

(3) Configuration of Dials 50 Each of the four dials 50 is rotatably provided on the operating shaft 20 via a lock gear 52. Each dial 50 has a cylindrical wall 54, as shown in FIGS.
A dial operation plate 51 and a driven gear 53 are provided at one end of
Each is integrally formed. The driven gear 53 constitutes a zero return mechanism 40 described later. Symbols “0” to “9” are shown on the outer peripheral surface of the cylindrical wall 54 at each equiangular position. The end face of the other end of the cylindrical wall 54 has ten recesses 6.
4 are formed. These depressions 64 constitute a storage mechanism 60 described later.

(4) Configuration of Storage Mechanism 60 The storage mechanism 60 is a mechanism for freely setting and storing a desired unlocking code string, and includes a displacement mechanism for reciprocally displacing each lock gear 52, An engagement mechanism for setting the engagement angle state between the dial 50 and each lock gear 52 is provided. Here, the unlock code sequence refers to a sequence of codes that set the code lock to the “unlocked state” when the dials are aligned, among the sequence of codes of the dials 50 appearing in the window holes 5. In the following description, the code of each dial 50 constituting the unlock code sequence may be simply referred to as “unlock code”.

The displacement mechanism includes first and second concave portions 14 and 15 formed on the outer peripheral surface of the cylindrical body 11 and an operating shaft 20.
Front bush 61 slidably fitted to the tip of the
And a compression spring 63 that urges each lock gear 52 through the rear bush 62 toward the operation drive unit 10. The open end of the front bush 61 abuts against the outer peripheral surface of the tubular body 11. The rear end edge of the front bush 61 contacts the leading lock gear 52. A front end surface 21 of the operating shaft 20 protrudes from a front end opening of the front bush 61.

In the "open state" shown in FIGS. 3 and 4,
The first concave portion 14 of the tubular body 11 faces the direction of the operating shaft 20. The operating shaft 20 is driven by the spring force of the compression spring 26,
Each lock gear 52 and front bush 61 are provided with a compression spring 6.
By the spring force of No. 3, each is pushed and displaced in the direction of the tubular body 11, and the distal end surface 21 of the operating shaft 20 and the distal end edge of the front bush 61 are fitted into the first concave portion 14. In this state, both the operating shaft 20 and each lock gear 52 are displaced toward the operation drive unit 10 (hereinafter, referred to as a “first displacement state”).

FIGS. 8 and 9 show a state at the time of transition from the “open state” to the “closed state”. In this state,
Neither of the recesses 14, 15 of the cylindrical body 11 faces the direction of the operating shaft 20, and the distal end surface 21 of the operating shaft 20 and the distal end edge of the front bush 61 ride on the outer peripheral surface of the cylindrical body 11. Abut. In this state, both the operating shaft 20 and each lock gear 52 are in a state of being displaced to the side opposite to the operation drive unit 10 (hereinafter, referred to as a “second displacement state”).

In the "closed state" shown in FIGS. 10 and 11, the second concave portion 15 of the cylindrical body 11 faces the direction of the operating shaft 20. The second concave portion 15 is provided on the distal end surface 21 of the operating shaft 20.
Is fitted, but the front edge of the front bush 61 is formed so as not to fit, so that only the operating shaft 20 is pushed by the spring force of the compression spring 26 and displaced toward the tubular body 11,
The tip surface 21 fits into the second recess 15. In this state, only the operation shaft 20 is displaced toward the operation drive unit 10 (hereinafter, referred to as a “third displacement state”).

Next, the meshing mechanism is shown in FIGS.
As shown in FIGS. 21 and 22, ten recesses 64 formed on the inner peripheral surface of the cylindrical wall 54 of each dial 50 are provided.
As shown in FIG. 7, each of the lock gears 52 includes ten protrusions 65 protruding from the outer peripheral surface. The engagement angle position between the recess 64 of each dial 50 and the protrusion 65 of each lock gear 52, that is, the dial 50 with respect to the lock gear 52
Since there are a number of fitting angle positions corresponding to the number of codes, the unlocking code can be set in ten ways according to the fitting angle positions of the two.

When the lock gear 52 is in the "open state" of FIGS.
Of the respective dials 50.
Does not mesh with the protrusion 65 of each lock gear 52,
The connection between each dial 50 and each lock gear 52 is cut off. As a result, each dial 50 in the "open state"
Is in a state where it can be rotated by itself, and FIG.
As shown in (1), an arbitrary unlock code can be set. In the example shown in FIG. 7, only the two dials 50 corresponding to the lower two digits are rotated to set the unlock code string of “0055”.

At the time of transition from the “open state” to the “closed state” shown in FIGS. 8 and 9, since each lock gear 52 is in the “second displacement state” displaced to the opposite side to the operation drive unit 10, The depression 64 of the dial 50 and the projection 65 of each lock gear 52 are engaged with each other, and the set unlock code sequence is stored.

Also in the "closed state" shown in FIGS. 10 and 11, the lock gears 52 maintain the state of being displaced to the side opposite to the operation drive unit 10, so that the recess 64 of each dial 50 and each lock gear 52 Of the unlocking code string is retained in a state in which it is engaged with the protruding member 65 of FIG.

(5) Configuration of Lock Mechanism 80 When the lock mechanism 80 is in the "closed state", the codes of the respective dials 50 appearing in the respective window holes 5 are all unlock codes (an unlock code sequence is generated). Operation), the operation of the operation drive unit 10 is permitted. On the other hand, when the code of any of the dials 50 appearing in each window hole 5 is not the unlock code (when the unlock code sequence is broken), the operation drive is performed. The operation of the unit 10 is regulated.

The lock mechanism 80 of this embodiment has four protrusions 82 projecting from the shaft peripheral surface of the operating shaft 20 and a protrusion provided on the inner peripheral surface at one end of each lock gear 52 in the axial direction. An outer peripheral groove 83 provided on the inner peripheral surface at the other end of each lock gear 52; a linear groove 84 provided on the inner peripheral surface at the rear end of the front bush 61; A second concave portion 15 formed on the outer peripheral surface of the body 11.

Each of the projections 82 of the operating shaft 20 is in the "open state" shown in FIGS. 3 and 4, and also in the transition from the "open state" to the "closed state" shown in FIGS. , Each of the lock gears 52 is engaged with the corresponding one of the protrusion engagement grooves 81 of the lock gears 52.
Is regulated. When in the “open state”, since each dial 50 is disconnected from the lock gear 52,
Each dial 50 can be rotated to set and change the unlock code. On the other hand, at the time of transition from the “open state” to the “closed state”, the turning operation of each dial 50 is restricted because each dial 50 is engaged with each lock gear 52.

When the "closed state" shown in FIGS. 10 and 11 is reached, each protrusion 82 of the operating shaft 20 escapes from the protrusion engagement groove 81 of each lock gear 52, and the circumferential groove 8 of the adjacent lock gear 52
The lock gears 52 are rotatable with respect to the operating shaft 20 because the lock gears 52 enter the inside of the linear groove 84 of the front bush 61. At this time, each dial 50 is
And the unlock code is stored and held.

In this "closed state", when the zero return mechanism 40 is operated by operating the operation tool 30, which will be described later, the respective dials 50 and the respective lock gears 52 rotate integrally to break the unlock code sequence. Each protrusion 82 and the protrusion engagement groove 81 of each lock gear 52 are displaced in the circumferential direction, and a locked state is generated. If it is attempted to rotate the photographing 16 in the “open state” in this state of misalignment, the displacement of the operating shaft 20 in the proximal direction is restricted by the misalignment between the projection 82 and the projection engaging groove 81, The tip surface 21 of the operating shaft 20 is the second concave portion 1 of the cylindrical body 11.
5, the cylindrical body 11 cannot rotate, and the operation of the photographing 16 is impossible.

(6) Configuration of the Operating Tool 30 The operating tool 30 has a push button 31 that projects from the opening 6 of the front plate 3 onto the front plate 3. This push button 31
As shown in FIG. 5 and FIG. 6, on the lower surface of the first and second operation pieces 32,
33 are integrally provided so as to protrude. First operation piece 3
2 has a square shaft shape, and a tapered pressing surface 34 is formed on the lower end surface. The second operation piece 33 has a plate shape, and a rack gear 35 is formed on one side edge. 15 and 16
17 shows a state in which the operation tool 30 is being operated, and FIGS. 17 and 18 show a final state in which the operation of the operation tool 30 is completed.

(7) Configuration of Zero Return Mechanism When the push button 31 of the operation tool 30 is pressed in the "closed state", the zero return mechanism 40 forcibly rotates each dial 50 to align the dial 50. Breaking the unlock code string of
This is for rotating each dial 50 to a predetermined angular position to return to the initial code string in which “0” is arranged in the four window holes 5.

In this embodiment, the window 5 of each dial 50
In this configuration, each dial 50 is forcibly rotated to an angular position at which “0” appears, but the present invention is not limited to this, and another predetermined code (for example, “1”) is assigned to each window hole 5. It may have a configuration to appear. Further, in this embodiment, even when the push button 31 of the operating tool 30 is pressed after the shift from the “closed state” to the “open state” by the unlocking operation,
Similarly, the unlocked code string in the aligned state is broken and returned to the initial code string.

To realize the above-described operation of returning to zero,
As shown in FIGS. 3, 5 and 6, the zero return mechanism 40 of this embodiment includes a rotary drive shaft 41 that reciprocates and rotates in association with the vertical movement of the operating tool 30 by the push button 31.
And a power transmission mechanism 42 that transmits the rotation of the rotary drive shaft 41 to each dial 50 and integrally rotates each dial 50.

The rotation drive shaft 41 is provided in parallel with the operation shaft 20, and the tip of the rotation drive shaft 41 is located directly below the first operation piece 32 of the operation tool 30. Operation tool 3
When the first operating piece 32 is lowered by pressing 0, the pressing surface 34 of the first operating piece 32 has a tapered shape, and as shown in FIGS. Is displaced by pushing its distal end in the proximal direction. A compression spring 43 is mounted on the base end of the rotation drive shaft 41. When the first operation piece 32 is lifted and returned, the rotation drive shaft 41 is moved toward the operation tool 30 by the spring force of the compression spring 43. Will be returned.

The operating tool 30 is attached to the tip of the rotary drive shaft 41.
A pinion gear 44 is mounted corresponding to a position below the second operation piece 33. The rotation drive shaft 41 and the pinion gear 44 rotate integrally at least 180 degrees, but the rotation drive shaft 41 is free to reciprocate with respect to the pinion gear 44. When the operation tool 30 is pressed, the second operation piece 33
Is lowered, the rack gear 34 of the second operation piece 33 meshes with the pinion gear 44 as shown in FIGS. 15 to 18, and the linear motion of the second operation piece 33 is converted into the rotational motion of the rotary drive shaft 41. . A compression spring 36 is mounted on the operation tool 30. When the pressing force on the operation tool 30 is released, the operation tool 30 is pushed up by the spring force of the compression spring 36 and returns.

The power transmission mechanism 42 includes a dial 50
4 is rotatably provided at a position corresponding to each of the driven gears 53 integrally formed on the rotary drive shaft 41 and the respective dials 50.
Drive gears 45, the rotary drive shaft 41 and each drive gear 45
And a clutch mechanism 71 interposed therebetween.
The clutch mechanism 71 forms a control mechanism 70 with a notch 55 described later formed in the driven gear 53. The control mechanism 70 controls the rotation of the rotary drive shaft 41 by a predetermined angle from the angular position where the unlock code appears in the window 5 to the angular position where “0” appears in the window 5. Dial 50
The turning angle of each dial 50 is controlled so that the. In this embodiment, the dials 50 are simultaneously rotated together with the rotation of the rotary drive shaft 41, and each time the dial 50 reaches the angular position where “0” appears in the window hole 5, In this configuration, the integral rotation with the drive shaft 41 is individually released.

Each drive gear 45 meshes with a driven gear 53 of each dial 50, and is freely rotatable on the rotary drive shaft 41. The rotary drive shaft 41 is free to reciprocate with respect to each drive gear 45. Each drive gear 45 has a boss 46
Are formed integrally, and a plurality of (in this embodiment, ten) cut grooves 72 constituting the clutch mechanism 71 are formed on the end face of the boss portion 46 at a constant angle.

Since the driven gear 53 and the driving gear 45 have a gear ratio of 1: 2, the driven gear 53 makes one rotation while the driving gear 45 makes a half rotation. As shown in FIG. 6, a dial 5 is provided on the tooth surface on the outer periphery of each driven gear 53.
The notch portion 55 is formed so that when the zero angle position becomes the angle position at which the zero appears in the window hole 5, the engagement with the corresponding drive gear 45 is released.

FIG. 14 shows the relationship between the drive gear 45 and the driven gear 53 when "5" appears in the window hole 5. The drive gear 45 and the driven gear 53 mesh with each other, and the driven gear 53 Is located on the opposite side of the drive gear 45. Due to the engagement between the driving gear 45 and the driven gear 53, the rotational force of the driving gear 45 is transmitted to the driven gear 53, and the dial 50 is rotated integrally.

FIG. 16 shows the relationship between the drive gear 45 and the driven gear 53 when "0" appears in the window hole 5. The cut-out portion 55 of the driven gear 53 is located at the position of the drive gear 45. In this case, the driving gear 45 and the driven gear 53 are disengaged from each other. When the drive gear 45 and the driven gear 53 are disengaged from each other, the rotation of the drive gear 45 is
3, and the dial 50 does not rotate integrally.

The clutch mechanism 71 includes a rotary drive shaft 41
Each drive gear 45 is disengaged from the rotary drive shaft 41 by the reciprocating motion of
This is for turning on and off the transmission of rotation. In this embodiment, mounting holes 73 of a predetermined length are respectively opened at positions corresponding to the respective driving gears 45 of the rotary drive shaft 41, and the boss portions 46 of the respective driving gears 45 are formed in the respective mounting grooves 73. Engagement piece 74 that engages with and disengages from cut groove 72
Attached.

The engaging piece 74 is a synthetic resin molded body having flexibility, and has a structure in which a fixed end portion 75 and a free end portion 76 at both ends are connected in an N-shape by a connecting portion 77. . The fixed end portion 75 is fixed to the groove end of the mounting groove 73 on the side of the operating tool 30, and the free end portion 76 is engaged with the groove end on the opposite side of the mounting groove 73 in a released state, and the bending of the connecting portion 77 is performed. By the operation and the restoring operation, the free end 76 slides back and forth in the axial direction inside the mounting groove 73. The free end 76 has both ends protruding from the peripheral surface of the rotary drive shaft 41, and the protrusions at both ends engage and disengage with the two cut grooves 72 at any one of the diagonal positions of the drive gear 45.

When the operating tool 30 is not operated, as shown in the "open state" shown in FIGS.
The free end 76 of the engagement piece 74 is not engaged with the cut groove 72 of the drive gear 45, but when the operating tool 30 is operated as shown in FIGS. The portion 76 engages with one of the notches 72 of the drive gear 45.

When the code lock device of the present invention is implemented, a mechanism for operating each dial 50 intermittently to cause each code to appear and localize sequentially in the window hole 5 is incorporated. , So illustration and description are omitted here.

Needless to say, the operating tool 30 and the zero return mechanism 40, which are features of the present invention, are not limited to those of the above-described embodiment. For example, the operation tool 30 does not need to be a push button type as in this embodiment, but may be a lever or handle type. Also, the control mechanism 7
For the clutch mechanism 71 used for the zero, various configurations can be adopted. Further, the drive gear 45 and the driven gear 53 used in the power transmission mechanism 42 can be replaced with, for example, a gear using a belt.

FIGS. 23 to 44 show the internal structure and operation of the second embodiment in which another type of zero return mechanism 40 is incorporated. 23 to 27 are in the “open state”, and FIGS. 28 and 29 are in the setting of the unlock code string.
31 is a transition from the “open state” to the “closed state”, FIG. 31 is in the “closed state”, FIGS. 32 to 34 are at the start of operation of the operation tool 30, and FIGS. On the way, FIG.
FIG. 42 shows the state when the operation of the operation tool 30 is completed.
Indicates a time when the operation tool 30 returns. The code locking device of the second embodiment also has an operation drive unit 1 as in the first embodiment.
0, operating shaft 20, four dials 50, storage mechanism 60,
And a lock mechanism 80. In the second embodiment as well, the principle of storage of the unlock code string and the principle of locking and unlocking are the same as in the first embodiment. The detailed description is omitted by attaching the same reference numerals as the examples.

In the dial 50 of the second embodiment, as shown in FIG. 45, only a dial operating plate 51 is formed at one end of a cylindrical wall 54, and a driven gear 53 is provided at the other end of the cylindrical wall 54. Is provided. The driven gear 53 forms a power transmission mechanism 42 together with a drive gear 45 described later.

As shown in FIG. 27, in the operating tool 30 of the second embodiment, a first operating piece 32 provided on the lower surface of a push button 31 is constituted by a pair of legs 32a and 32b forming a square shaft. I have. Tapered pressing surfaces 34 as shown in FIG. 25 are formed on the lower end surfaces of the legs 32a and 32b, respectively. Each pressing surface 34 is in contact with the head 37a of the stop shaft 37 provided at the tip of the rotary drive shaft 41 from inside, and when the first operation piece 32 is lowered by pressing the push button 31, FIG.
34, the head 37a of the stop shaft 37 is pushed by the taper of each pressing surface 34, and the rotary drive shaft 41 is displaced in the direction of the drive operation unit 10. After that, FIGS.
As shown in FIG. 8, the shaft portion 37b of the stop shaft 37 slides into the gap between the legs 32a and 32b while the head 37a is supported by the operation piece 32, and the rotary drive shaft 41 is displaced. It is kept as it is.

The second operation piece 33 provided on the lower surface of the push button 31 has a rack gear 35 similar to that of the first embodiment, and this rack gear 35 is provided with a pinion gear 44 provided at the tip of the rotary drive shaft 41. And are engaged.

In this embodiment, when the push button 31 of the operating tool 30 is pressed in the "closed state", the dials 50 are forcibly rotated to break the unlocked code sequence in the aligned state. At the same time, each dial 50 is rotated to a predetermined angular position to return to the initial code string in which “0” is lined up in the four window holes 5. Rotating rotary drive shaft 41, rotary drive shaft 41
And a power transmission mechanism 42 for transmitting the rotation of the dials to the respective dials 50 and rotating the respective dials 50 integrally. A tension spring 49 is attached to the rear end of the rotary drive shaft 41,
When 0 returns with the spring force of the compression spring 36 and returns,
The rotation drive shaft 41 is returned in the direction opposite to the operation tool 30 by the spring force of the tension spring 49.

The power transmission mechanism 42 includes a dial 50
, Driven gears 53, four drive gears 45 meshing with each driven gear 53, and a clutch mechanism 71 interposed between the rotary drive shaft 41 and each drive gear 45. Each of the drive gears 45 is freely slidable and rotatable with respect to the rotary drive shaft 41. The clutch mechanism 71 constitutes a control mechanism 70. When the rotation drive shaft 41 rotates to an angular position corresponding to the current angular position of each dial 50 in which the unlock code appears in the window hole 5, the clutch mechanism 71 constitutes. The configuration is such that the integral rotation of each dial 50 is started individually, and the rotation of the rotary drive shaft 41 is stopped when “0” reaches the angular position where it appears in the window hole 5.

In order to realize such an operation, in this embodiment, a disk-shaped drive plate 78 is attached to a position corresponding to each dial 50 of the rotary drive shaft 41 and the rotary drive shaft 4 is mounted.
1, and each driving gear 45 is provided with an engaging pin 47 facing the outer peripheral portion of the driving plate 78, and the engaging pin 47 is engaged with the outer peripheral edge of each driving plate 78. Two notched recesses 79 that engage and disengage with the pins 47
a, 79b are formed at diagonal positions.

The engagement pin 47 is supported by a compression spring 48 and is urged toward the drive plate 78. When the drive plate 78 moves toward the drive gear 45 integrally with the rotary drive shaft 41, if any one of the cutout recesses 79a, 79b of the drive plate 78 and the engagement pin 47 of the drive gear 45 face each other. Since the engaging pin 47 engages with the notch recess facing the driving gear 45, the driving gear 45 rotates integrally with the driving plate 78. On the other hand, the notch recess 79
If the positions a and 79b are misaligned, the engagement pin 47 slides in contact with the surface of the drive plate 78, and
When one of a and 79b comes to the opposing position, it engages with the notch recess.

The gear ratio between the driven gear 53 and the driving gear 45 is set to be 1: 2, and the driven gear 53 makes one rotation for every half rotation of the driving gear 45. Rotary drive shaft 41
25 and 26, the number of teeth and the pitch of the rack gear 35 and the pinion gear 44 are set so as to make a half rotation by the pressing operation of the operating tool 30, and in a standby state where the operating tool 30 is not pressed. As shown in FIG. 7, the mounting angle position of the drive plate 78 to the rotary drive shaft 41 is set so that one notch recess 79a is located on the front plate 3 side.

On the other hand, when each dial 50 is in the angular position where “0” appears in the window hole 5, the engagement pin 47 of the drive gear 45 is moved to each drive gear 45 so that the engagement pin 47 is located at the uppermost position. Is set. Therefore, when the engaging pin 47 at an arbitrary angular position engages with one of the notch recesses 79a, 79b of the drive plate 78 and rotates to the uppermost position, the sign of the dial 50 that appears in the window hole 5 is: It becomes "0".

Next, a series of operations during the locking operation of the code locking device of the first embodiment will be described in detail. Now, when the sign lock device is in the “open state” shown in FIGS. 1 to 6, the distal end surface 21 of the operating shaft 20 and the front bush 6
The front end edge of the first shaft 1 is fitted in the first concave portion 14 of the tubular body 11, and the operating shaft 20 and each lock gear 52 are in the “first displacement state” in which they are most displaced toward the operation drive unit 10. In this state, each of the dials 50 is in a freely rotatable state in which the engagement with each of the lock gears 52 is broken, that is, the indentation 6 of each of the dials 50.
Since the engagement between the lock gear 4 and the protrusion 65 of each lock gear 52 is released, the unlock code can be set freely.

When the dial operation plate 51 of each dial 50 is turned to set an arbitrary unlock code string such as “0055” shown in FIG. As shown in FIGS. 8 and 9, the distal end surface 21 of the operating shaft 20 and the distal end edge of the front bush 61 escape from the first concave portion 14 and ride on the outer peripheral surface of the cylindrical body 11. Come up and abut. For this reason, from "open state" to "closed state"
At this time, the operation shaft 20 and each lock gear 52 are displaced toward the base end of the operation shaft 20 in a “second displacement state”. In this "second displacement state", each dial 50 is in a state of being engaged with each lock gear 52, that is, in a state in which the recess 64 of each dial 50 and the projection 65 of each lock gear 52 are engaged. An unlock code string is stored. Further, since the four projections 82 of the operating shaft 20 are inserted into the projection engagement grooves 81 of each lock gear 52, the shooting 16
During the rotation operation, the rotation of each lock gear 52 is regulated.

When the camera is rotated to the "closed state", the distal end surface 21 of the operating shaft 20 is fitted into the second concave portion 15 of the cylindrical body 11, as shown in FIGS. However, the leading edge of the front bush 61 remains riding on the outer peripheral surface of the tubular body 11, and only the operating shaft 20 is displaced toward the operation drive unit 10, resulting in a “third displacement state”. In this “third displacement state”, each dial 50 is maintained in a state of being engaged with each lock gear 52, while the four protrusions 82 of the operating shaft 20 escape from the protrusion engagement grooves 81 of each lock gear 52. As a result, the respective dials 50 and the respective lock gears 52 can rotate integrally with the operating shaft 20. The above operation is the same not only in the first embodiment but also in the second embodiment.

Next, when the push button 31 of the operating tool 30 is pressed,
As shown in FIGS. 15 and 16, since the first operation piece 32 is lowered and the pressing surface 34 presses the rotary drive shaft 41, the rotary drive shaft 41 moves in the proximal direction, and each engagement of the clutch mechanism 71 is performed. The engagement piece 74 and the cut groove 72 of each drive gear 45 are engaged, and the rotary drive shaft 41 and each drive gear 45 are integrated.
After a short delay, the rack gear 35 of the second operating piece 33 meshes with the pinion gear 44 of the rotary drive shaft 41, so that the rotary drive shaft 41 rotates, and the driven gear 53 of each dial 50 is connected to each drive gear 45. It is in a state where it can rotate integrally.

In the specific example in which the unlock code string is set to “0055”, the driven gear 53 rotates integrally with the drive gear 45 for the two dials 50 in which “5” appears in the window hole 5. Dial 5 until the position "0" appears in the window 5.
When 0 rotates, the notch 55 of the driven gear 53 reaches the position of the drive gear 45, and the engagement between the drive gear 45 and the driven gear 53 is released. As a result, the rotation of the drive gear 45 is not transmitted to the driven gear 53, and the dial 50 stops rotating. As for the other dial 50 in which “0” appears in the window hole 5, the notch 55 of the driven gear 53 is located at the position of the driving gear 45 and the driving gear 45 and the driven gear 53 are disengaged from each other. The rotation of the drive gear 45 is not transmitted to the driven gear 53, and the dial 50 does not rotate. Therefore, the code appearing in the window 5 remains “0”.

Next, the second embodiment will be described.
In the "closed state" shown in FIG.
1, the first operation piece 32 is lowered and the pressing surface 34 is moved to the head 3 of the stop shaft 37 as shown in FIGS. 32 and 33.
7a is pushed, and the rotary drive shaft 41 is moved in the direction of the operation drive unit 10. As a result, each drive plate 78 approaches each drive gear 45, and if the position of the engagement pin 47 and one of the notch recesses 79a, 79b coincide, both can be engaged.

Prior to operation of the operating tool 30, FIGS.
In the "open state" shown in FIG. 7, the dial 50 is operated, and as shown in FIG.
When set to “5”, the two dials 50 of the lower two digits in which “5” appears in the window hole 5, as shown in FIG. 29, the cutout recesses 79 a and 79 b of the drive plate 78.
, The engagement pin 47 of the drive gear 45 is displaced. When the operating tool 30 is operated in this state, the engaging pin 4
7 comes into contact with the surface of the drive plate 78. When the rack gear 35 of the first operation piece 33 meshes with the pinion gear 44 of the rotary drive shaft 41 with a slight delay, the rotary drive shaft 41 rotates.

In the course of the half rotation of the rotary drive shaft 41, FIG.
As shown in FIG. 7, the engaging pin 47 is
Engage with. As a result, the drive gear 45 starts rotating,
Since the driven gear 53 of the dial 50 also rotates integrally with this, the unlock code is broken. 39 and FIG.
When the dial 50 is rotated to a position where “0” appears in the window hole 5, the rotation of the rotary drive shaft 41 stops as shown in FIG.

In each of the upper two digits of the dial 50 in which “0” appears in the window hole 5, the position of the engagement pin 47 of the drive gear 45 coincides with one of the notch recesses 79 a of the drive plate 78. As a result, the engagement pin 47 immediately engages with the notch recess 79 a of the drive plate 78. As a result, the drive gear 45 starts to rotate at the same time as the rotation of the rotary drive shaft 41, and the driven gear 53 of the dial 50 also rotates integrally therewith, so that the unlock code is broken. When the rotation drive shaft 41 makes a half rotation, “0” appears again in the window 5 as shown in FIGS. 39 and 40, and the rotation drive shaft 41 stops rotating.

When the pressing force of the pressing operation tool 30 is released, the spring force of the compression spring 36 acts, and the pressing tool 30 performs a return operation. At this time, however, the rotary drive shaft 41 makes a half turn in the opposite direction to the above. As shown in FIGS. 43 and 44, each of the dials 50 also simultaneously makes one rotation in the opposite direction, and
Appears as an initial code string.

Next, the operation during the unlocking operation will be described.
When the code lock device is in the locked state, each dial 50 is in a state of being engaged with each lock gear 52, and each of the lock gears 52 is in a state of being disengaged from the operating shaft 20. It is possible to arrange the set unlock code strings.

When the unlock code strings are aligned by rotating the dial operation plate 51 of each dial 50, each lock gear 5
The position of the second protrusion engaging groove 84 and the position of the corresponding protrusion 82 on the operating shaft 20 match, and an unlocked state is generated. When the photographing 16 is rotated in this state, the cylindrical body 11 rotates and returns to the “open state” shown in FIGS. In this “open state”, when the operating tool 30 is pressed, the respective dials 50 can be returned to zero by the operation of the zero return mechanism 40.

[0078]

As described above, according to the present invention, the operating tool for breaking the unlock code string is provided, and the unlock code string is broken by operating the operating tool. It is possible to reconfirm the setting contents of the lock code string, thereby preventing occurrence of trouble. In addition, since the operation of breaking the unlock code string is separated from the operation of storing the unlock code string, the internal mechanism is compared with the conventional example in which the unlock code string is stored and broken by the locking operation. Is simplified and miniaturized, and the number of steps required for production and adjustment is reduced.

According to the second aspect of the present invention, the dials are simultaneously rotated integrally with the rotation of the rotary drive shaft, and each time the rotation of each dial reaches a predetermined angular position, the rotary drive shaft of each dial is rotated. In addition, according to the third aspect of the invention, when the rotary drive shaft rotates to an angular position corresponding to the current angular position of each dial, the integral rotation of each dial is performed. Individually, and when the rotation of each dial reaches a predetermined angular position, the rotation of the rotary drive shaft is stopped.In addition to the above-described effects, the unlock code sequence is surely broken. In addition, there is an effect that it is possible to return to another predetermined code string.

[Brief description of the drawings]

FIG. 1 is a plan view showing the appearance of a code lock device according to an embodiment of the present invention.

FIG. 2 is a side view showing the appearance of the code lock device according to the embodiment of the present invention.

FIG. 3 is a horizontal sectional view showing an internal structure of the first embodiment in an “open state”.

FIG. 4 is a vertical sectional view taken along line AA of FIG. 3;

FIG. 5 is a vertical sectional view taken along the line BB of FIG. 3;

FIG. 6 is a side view showing a state of the operating tool and the zero return mechanism of the first embodiment in an “open state”.

FIG. 7 is a horizontal sectional view showing an internal structure of the first embodiment when an unlock code string is set.

FIG. 8 is a horizontal sectional view showing the internal structure of the first embodiment at the time of transition from “open state” to “closed state”.

FIG. 9 is a vertical sectional view taken along line CC in FIG. 8;

FIG. 10 is a horizontal cross-sectional view showing the internal structure of the first embodiment in a “closed state”.

FIG. 11 is a vertical sectional view taken along line DD of FIG. 10;

FIG. 12 is a horizontal sectional view showing the internal structure of the first embodiment when operating the operating tool.

FIG. 13 is a vertical sectional view taken along line EE in FIG. 12;

FIG. 14 is a side view showing the state of the operating tool and the zero return mechanism of the first embodiment when setting the unlock code string.

FIG. 15 is a vertical sectional view taken along line FF of FIG. 12;

FIG. 16 is a side view showing the state of the operating tool and the zero return mechanism of the first embodiment when operating the operating tool.

FIG. 17 is a vertical sectional view of the first embodiment at the end of the operation of the operating tool.

FIG. 18 is a side view showing the state of the operation tool and the zero return mechanism of the first embodiment at the end of the operation of the operation tool.

FIG. 19 is a side view of the dial according to the first embodiment.

FIG. 20 is a vertical sectional view of the dial of the first embodiment.

FIG. 21 is a side view of the lock gear according to the first embodiment.

FIG. 22 is a longitudinal sectional view of the lock gear of the first embodiment.

FIG. 23 is a horizontal sectional view showing the internal structure of the second embodiment in an “open state”.

FIG. 24 is a vertical sectional view taken along line GG of FIG. 23.

FIG. 25 is a vertical sectional view taken along the line HH in FIG. 23;

FIG. 26 is a side view showing the state of the zero return mechanism of the second embodiment in the “open state”.

FIG. 27 is a side view showing the state of the operating tool and the zero return mechanism of the second embodiment in the “open state”.

FIG. 28 is a horizontal sectional view showing the internal structure of the second embodiment when an unlock code sequence is set.

FIG. 29 is a side view showing the state of the zero return mechanism of the second embodiment when setting the unlock code sequence.

FIG. 30 is a horizontal sectional view showing the internal structure of the second embodiment at the time of transition from “open state” to “closed state”.

FIG. 31 is a horizontal sectional view showing the internal structure of the second embodiment in a “closed state”.

FIG. 32 is a horizontal sectional view showing the internal structure of the second embodiment at the time of starting operation of the operating tool.

FIG. 33 is a vertical sectional view taken along the line II of FIG. 32;

FIG. 34 is a side view showing the state of the operation tool and the zero return mechanism of the second embodiment at the start of operation of the operation tool.

FIG. 35 is a vertical sectional view showing the internal structure of the second embodiment during operation of an operating tool.

36 is a sectional view taken along line JJ of FIG. 35.

FIG. 37 is a side view showing the state of the zero return mechanism of the second embodiment during operation of the operating tool.

FIG. 38 is a side view showing the state of the operation tool and the zero return mechanism of the second embodiment during operation of the operation tool.

FIG. 39 is a vertical sectional view showing the internal structure of the second embodiment at the end of the operation of the operating tool.

40 is a cross-sectional view of FIG. 39 taken along the line KK.

FIG. 41 is a side view showing the state of the zero return mechanism of the second embodiment at the end of the operation of the operating tool.

FIG. 42 is a side view showing the state of the operation tool and the zero return mechanism of the second embodiment when the operation of the operation tool is completed.

FIG. 43 is a vertical sectional view of the second embodiment when the operating tool returns.

FIG. 44 is a side view showing the state of the zero return mechanism of the second embodiment when the operating tool returns.

FIG. 45 is a vertical sectional view of the dial of the second embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Latch 10 Operating part 30 Operating tool 40 Zero return mechanism 41 Rotation drive shaft 42 Power transmission mechanism 50 Dial 60 Storage mechanism 70 Control mechanism 80 Lock mechanism

Claims (3)

[Claims] 1. An operation drive unit driven by an operation for opening and closing a latch, and a rotating operation for setting an unlock code sequence when locking and aligning the unlock code sequence when unlocking. A plurality of dials, a storage mechanism for storing an unlock code sequence set in response to driving of the operation drive unit, and a locked state formed by breaking the unlock code sequence after the operation of the storage mechanism. An unlocking device including a lock mechanism that forms an unlocked state by aligning an unlocking code string in a state, wherein an operating tool operated to break the unlocking code string and a predetermined operation performed by operating the operating tool And a power transmission mechanism that transmits the rotation of the rotary drive shaft to each dial to rotate the respective dials together, wherein the power transmission mechanism is a rotary drive shaft. While the shaft rotates by a predetermined angle, Code lock device comprising a control mechanism for controlling the rotational angle of each dial to rotate the dial from the current angular position to a predetermined angular position. 2. The control mechanism according to claim 1, wherein each of the dials is simultaneously rotated together with the rotation of the rotary drive shaft, and each time the rotation of each dial reaches a predetermined angular position, the rotary drive shaft of each dial is rotated. 2. The code locking device according to claim 1, wherein said code locking device is configured to individually release the integral rotation with said code locking device. 3. The control mechanism according to claim 1, wherein when the rotary drive shaft is rotated to an angular position corresponding to the current angular position of each dial, the respective dials are individually started to rotate together, and the rotation of each dial is started. 2. The code lock device according to claim 1, wherein the rotation of the rotary drive shaft is stopped when the rotation reaches a predetermined angular position.