CN212054153U

CN212054153U - Electric control lock body device

Info

Publication number: CN212054153U
Application number: CN201920374942.4U
Authority: CN
Inventors: 赵杰
Original assignee: Individual
Current assignee: Individual
Priority date: 2019-03-24
Filing date: 2019-03-24
Publication date: 2020-12-01
Anticipated expiration: 2029-03-24

Abstract

The utility model relates to an electric control lock body device, which solves the complex problem of the transmission parts of the full-automatic electric lock body on the market at present, and comprises an electric control gear, a latch bolt driving pin driven by the electric control gear, a latch bolt control block connected with the latch bolt driving pin and driven by the latch bolt driving pin, and an automatic latch bolt clutched with the latch bolt control block; comprises a transmission and control rack connected with and driven by an electric control gear, and a large square tongue driven by the transmission and control rack. The device can directly realize the driving of the motor to the latch bolt and the driving of the motor to the dead bolt, and has simple structure, convenient assembly and low cost.

Description

Electric control lock body device

Technical Field

The utility model belongs to the lock field relates to a lock body device that uses on full-automatic door lock body, in particular to automatically controlled lock body device.

Background

Most of lock bodies used by intelligent locks in the current market are of mechanical structures, and a small part of the lock bodies is internally provided with motors and clutch structures, but the lock bodies generally have complex structures, complex parts and high reject ratio, and bring inconvenience to production, assembly, use and after-sale.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model relates to an use full-automatic electric control lock body device on intelligent lock, this electric control lock body device need not be according to the left and right sides customization oblique tongue direction of the direction of opening the door, adjusts the lock body when also need not installing, can directly realize the drive of motor to oblique tongue, the drive of motor to the square tongue, simple structure, convenient assembling, it is with low costs.

The utility model relates to an electric control lock device, which comprises an electric control gear, an oblique tongue driving pin driven by the electric control gear, an oblique tongue control block connected with the oblique tongue driving pin and driven by the oblique tongue driving pin, and an automatic oblique tongue clutched with the oblique tongue control block; comprises a transmission and control rack connected with and driven by an electric control gear, and a large square tongue driven by the transmission and control rack.

Further automatic latch tongues are provided with: controlling the flange; the oblique tongue control block is provided with: a stop pin; when the latch bolt control block moves upwards to a specified position, the blocking edge is controlled to be abutted against the blocking pin; when the latch bolt control block moves downwards to a set position, the control flange is not abutted against the stop pin.

The further automatic oblique bolt comprises a rotating central shaft and a door locking vertical flange, and when the automatic oblique bolt rotates around the rotating central shaft, the door locking vertical flange rotates positively and negatively to different end positions along with the automatic oblique bolt, so that the conversion between a vertical locking function and a stressed inclined plane unlocking can be realized.

Specifically, the automatic latch tongue is provided with: the door-touching inclined flange, the supporting round hole and the limiting flange; the device still includes automatic oblique tongue seat 7, has on the automatic oblique tongue seat 7: the support circular shaft, the lower limiting flange, the upper limiting flange and the locking guide groove.

Through the matching of the supporting round hole and the supporting round shaft, the automatic oblique tongue is sleeved on the automatic oblique tongue seat 7, and the automatic oblique tongue can rotate relative to the automatic oblique tongue seat 7; the oblique tongue control block is arranged in a locking guide groove of the automatic oblique tongue seat 7, and can move up and down in the locking guide groove. The automatic latch bolt is provided with a door locking vertical flange which can be switched between a vertical locking function and a stressed inclined plane for unlocking when rotating forwards and backwards to different end positions along with the automatic latch bolt.

By adopting the structure, when the oblique stop edge of the touch door on the automatic oblique tongue is pushed and bumped by the thrust of the touch door generated by closing the door and the like, the automatic oblique tongue cannot rotate clockwise relative to the automatic oblique tongue seat 7 because the limit stop edge is abutted against the lower limit stop edge, and the thrust of the touch door pushes the automatic oblique tongue seat 7 of the automatic oblique tongue and the oblique tongue control block to integrally move downwards due to the inclined surface action of the oblique stop edge of the touch door, so that the automatic door closing is realized.

Furthermore, a first control inclined guide groove is arranged on the inclined tongue control block, and the inclined tongue driving pin is provided with: the transmission driving pin is arranged in the first control inclined guide groove and drives the first control inclined guide groove to move longitudinally when moving transversely;

furthermore, a transmission straight flange is arranged on the latch bolt driving pin, and a transmission straight flange is arranged on the transmission control rack; because the outgoing straight flange is abutted against the incoming straight flange, when the transmission and control rack moves leftwards, the oblique tongue is driven to drive the driving pin to move leftwards.

Further, the electric control gear is provided with: a gear; the transmission and control rack is provided with: the rack is used for transmitting the control moving pin, the gear is meshed with the rack, and when the motor rotates, the gear rotates to drive the transmission and control rack to move transversely.

By adopting the structure, when the motor rotates and the electric control gear rotates and simultaneously drives the transmission and control rack to transversely move leftwards, the transmission straight flange abuts against the transmission straight flange and pushes the transmission straight flange to enable the oblique tongue driving pin to transversely move leftwards, and meanwhile, the transmission driving pin drives the first control oblique guide groove to longitudinally move when transversely moving, so that the oblique tongue control block moves downwards, the oblique tongue control block does not abut against the automatic oblique tongue at the moment, the automatic oblique tongue can clockwise rotate relative to the automatic oblique tongue seat 7, and due to the inclined surface effect of the oblique flange of the door touch, the door touch thrust pushes the automatic oblique tongue seat 7 and the oblique tongue control block to integrally move downwards and return into the shell, thereby achieving the unlocking purpose.

Furthermore, the transmission control rack is provided with a transmission control movable pin which is assembled in the large square tongue, and the large square tongue is driven to move up and down when the transmission control movable pin moves transversely.

Furthermore, a first self-locking straight flange, a second control inclined guide groove and a second self-locking straight flange are arranged on the large square bolt; the first self-locking straight flange on the large square tongue can be abutted against the outgoing control moving pin on the transmission and control rack; meanwhile, the outgoing control moving pin can move left and right in a second self-locking straight flange on the large square tongue; the transmission control moving pin on the transmission control rack can be abutted against the second self-locking straight flange on the large square tongue.

Specifically, the large square bolt is provided with a first self-locking straight flange which can abut against a transmission control moving pin on the transmission control rack, and when the transmission control moving pin is free from external force and abuts against the first self-locking straight flange, the large square bolt keeps the state of extending out of the door.

Specifically, the large square bolt is provided with a second self-locking straight flange which can be abutted against the transmission control moving pin on the transmission control rack, and when the transmission control moving pin is not subjected to external force and is abutted against the second self-locking straight flange, the large square bolt keeps a retracted door locking state.

Specifically, the large square bolt is provided with a second control inclined guide groove which can be abutted against an outgoing control moving pin on the transmission control rack, and when the outgoing control moving pin moves transversely leftwards or rightwards under the action of external force, the second control inclined guide groove is an inclined guide groove, so that the large square bolt is driven to move downwards or upwards to perform door opening or door locking actions.

By adopting the structure, when the motor rotates, the electric control gear rotates and simultaneously drives the transmission and control rack to transversely move leftwards, and the transmission and control movable pin on the transmission and control rack drives the large square bolt to move, so that the effect of unlocking the door by passing the large square bolt in and out of the lock shell is achieved.

Drawings

FIG. 1 is an assembly view of the components of the present invention;

FIG. 2 is a schematic view of the self-locking state of the large square tongue of the present invention;

FIG. 3 is a schematic view of the unlocking process of the big square bolt of the present invention;

FIG. 4 is a schematic view of the big square bolt unlocking of the present invention;

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

As shown in fig. 1, an electrically controlled lock device comprises an electrically controlled gear 4, a latch bolt driving pin 3 driven by the electrically controlled gear 4, a latch bolt control block 2 connected with the latch bolt driving pin 3 and driven by the latch bolt driving pin 3, and an automatic latch bolt 1 clutched with the latch bolt control block 2; comprises a transmission and control rack 5 which is connected with the electric control gear 4 and driven by the electric control gear 4, and a large square tongue 6 which is driven by the transmission and control rack 5.

As shown in fig. 1, the latch control block 2 further has a first control latch guide groove 22, and the latch driving pin 3 has: the transmission driving pin 31 is installed in the first control inclined guide groove 22, and when the transmission driving pin 31 moves transversely, the transmission driving pin 31 drives the first control inclined guide groove 22 to move longitudinally; the latch bolt driving pin 3 is provided with a transmitting-in straight flange 32, and the transmission control rack 5 is provided with a transmitting-out straight flange 52; since the outgoing straight rib 52 abuts against the incoming straight rib 32, the transmission and control rack 5 moves leftwards and drives the latch bolt driving pin 3 to move leftwards. The electric control gear 4 is provided with: a gear 41; the transmission and control rack 5 is provided with: the rack 51 is transmitted out of the control moving pin 53, the gear 41 is meshed with the rack 51, and when the motor rotates, the gear 41 rotates to drive the transmission and control rack 5 to move transversely.

The automatic latch bolt 1 is provided with: a control flange 13; the oblique tongue control block 2 is provided with: a stopper pin 21; when the latch bolt control block 2 moves to a designated position leftwards, the control flange 13 is abutted against the stop pin 21; when the latch bolt control block 2 moves rightwards to the set position, the control rib 13 and the stop pin 21 do not abut against each other. Automatic oblique tongue 1 includes rotation center axle 14, the perpendicular flange 11 of lock door, bumps oblique flange 12 of door, supports round hole, spacing flange, and the device still includes automatic oblique tongue seat 7, has on the automatic oblique tongue seat 7: the support circular shaft, the lower limiting flange, the upper limiting flange and the locking guide groove. When the automatic latch bolt 1 rotates around the rotating central shaft, the vertical retaining edge 11 of the lock door can be switched between the vertical locking function and the forced inclined plane unlocking when rotating forward and backward to different end positions along with the automatic latch bolt 1. Through the matching of the supporting round hole and the supporting round shaft, the automatic oblique tongue 1 is sleeved on the automatic oblique tongue seat 7, and the automatic oblique tongue 1 can rotate relative to the automatic oblique tongue seat 7; the oblique tongue control block 2 is arranged in a locking guide groove of the automatic oblique tongue seat 7, and the oblique tongue control block 2 can move left and right in the locking guide groove. The automatic latch bolt 1 is provided with a door locking vertical flange 11, and the door locking vertical flange 11 can be switched between a vertical locking function and a stressed inclined plane unlocking function when rotating forwards and backwards to different end positions along with the automatic latch bolt 1. The transmission control rack 5 is provided with a transmission control moving pin 53, the transmission control moving pin 53 is assembled in the large square tongue 6, and when the transmission control moving pin 53 moves transversely, the large square tongue 6 is driven to move up and down.

As shown in fig. 1, the large square tongue 6 is provided with a first self-locking straight rib 61, a second control inclined guide groove 62 and a second self-locking straight rib 63; the first self-locking straight flange 61 on the big square bolt 6 can be propped against the transmission control moving pin 53 on the transmission control rack 5; meanwhile, the outgoing control moving pin 53 can move left and right in the second self-locking straight flange 63 on the large square tongue 6; the transmission control moving pin 53 on the transmission control rack 5 can be abutted against the second self-locking straight rib 63 on the large square tongue 6.

As shown in fig. 1, the large square tongue 6 is punched outwards and extends to the door locking position outside the lock body; because the first self-locking straight flange 61 on the large square tongue 6 is abutted against the outgoing control moving pin 53 on the transmission and control rack 5, the large square tongue 6 cannot move up and down and retract into the lock body, namely, the large square tongue 6 is self-locked. While the outgoing control moving pin 53 can move left and right in the second self-locking straight rib 63 on the large square tongue 6.

As shown in fig. 2, the large tongue 6 is provided with a first self-locking straight rib 61 which can abut against the outgoing control moving pin 53 on the transmission and control rack 5, the electric control gear 4 rotates clockwise, and the transmission and control rack 5 is driven to move leftwards due to the meshing of the gear 41 and the rack 51; the transmission control moving pin 53 on the transmission control rack 5 is abutted against the second control inclined guide groove 62 on the large square tongue 6, so that the large square tongue 6 is driven to move downwards to retract into the lock body, namely to retract the square tongue.

As shown in fig. 3, the big square tongue 6 is provided with a second self-locking straight flange 63 which can abut against the transmission control moving pin 53 on the transmission control rack 5, the electric control gear 4 continuously rotates clockwise, the transmission control rack 5 is driven to continuously move leftwards due to the meshing of the gear 41 and the rack 51, the big square tongue 6 cannot move up and down due to the fact that the transmission control moving pin 53 on the transmission control rack 5 abuts against the second self-locking straight flange 63 on the big square tongue 6, and the big square tongue 6 is moved back into the lock body and cannot move up and down to be ejected out under the action of external force, namely 6 the big square tongue is self-locked; while the outgoing control moving pin 53 can move left and right in the second self-locking straight rib 63 on the large square tongue 6.

As shown in fig. 4, when the motor rotates clockwise, the electric control gear 4 rotates and drives the transmission and control rack 5 to move transversely leftward, the outgoing straight rib 52 abuts against the first incoming straight rib 32 and pushes the incoming straight rib 32, so that the latch bolt driving pin 3 moves laterally leftward, at the same time, since the outgoing drive pin 31 brings the second control inclined guide groove 22 to move longitudinally when moving laterally, thereby the oblique tongue control block 2 moves downwards, after the oblique tongue control block 2 moves downwards to the lowest end, the control flange 13 on the automatic oblique tongue 1 is not propped against the stop pin 21 on the oblique tongue control block 2 any more, when the vertical door-locking flange 11 on the automatic latch bolt 1 is pushed in the door-locking direction, the automatic latch bolt 1 can rotate around the rotating shaft by an angle, and after rotating from the position of the dotted line to the angle shown in the figure, the door locking vertical flange 11 and the door locking push collision force direction generate a large oblique angle which is not vertical, namely the door locking vertical flange 11 rotates to form an oblique flange which can be unlocked; the lock can be unlocked by pushing the door, and automatic unlocking is realized.

The same is true. The motor rotates reversely, and the reverse direction of the whole process is the reverse locking of the door.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modification, equivalent replacement or improvement made within the spirit and principle of the present invention should be included in the present invention.

Claims

1. An electric control lock body device is characterized by comprising an electric control gear, a latch bolt driving pin driven by the electric control gear, a latch bolt control block connected with the latch bolt driving pin and driven by the latch bolt driving pin, an automatic latch bolt clutched with the latch bolt control block, a transmission and control rack connected with the electric control gear and driven by the electric control gear, and a large square bolt driven by the transmission and control rack.

2. An electrically controlled lock body assembly according to claim 1 wherein: the automatic oblique tongue is provided with: controlling the flange; the oblique tongue control block is provided with: a stop pin; when the latch bolt control block moves upwards to a specified position, the blocking edge is controlled to be abutted against the blocking pin; when the latch bolt control block moves downwards to a set position, the control flange is not abutted against the stop pin.

3. An electrically controlled lock body assembly according to claim 2 wherein: the automatic oblique bolt comprises a rotating central shaft and a door locking vertical flange, and when the automatic oblique bolt rotates around the rotating central shaft and the door locking vertical flange rotates forwards and backwards to different end positions along with the automatic oblique bolt, the automatic oblique bolt can be switched between a vertical locking function and a stressed inclined plane unlocking function.

4. An electrically controlled lock body assembly according to claim 1 wherein: the oblique tongue control block is also provided with a first oblique control guide groove, and the oblique tongue driving pin is provided with: the transmission driving pin is installed in the first control inclined guide groove, and when the transmission driving pin moves transversely, the transmission driving pin drives the first control inclined guide groove to move longitudinally.

5. An electrically controlled lock body assembly according to claim 1 wherein: the oblique tongue driving pin is provided with a transmission straight flange, and the transmission control rack is provided with a transmission straight flange; because the outgoing straight flange is abutted against the incoming straight flange, when the transmission and control rack moves leftwards, the oblique tongue is driven to drive the driving pin to move leftwards.

6. An electrically controlled lock body assembly according to claim 1 wherein: the electric control gear is provided with: a gear; the transmission and control rack is provided with: and the gear is meshed with the rack, and when the motor rotates, the gear rotates to drive the transmission and control rack to transversely move.

7. An electrically controlled lock body assembly according to claim 6 wherein: the transmission control rack is provided with a transmission control movable pin which is assembled in the large square tongue, and when the transmission control movable pin moves transversely, the large square tongue is driven to move up and down.

8. An electrically controlled lock body assembly according to claim 7 wherein: the large square bolt is provided with a first self-locking straight flange which can be abutted against the transmission control moving pin on the transmission control rack, and when the transmission control moving pin is not subjected to external force and is abutted against the first self-locking straight flange, the large square bolt keeps the state of extending out of the door.

9. An electrically controlled lock body assembly according to claim 7 wherein: the large square bolt is provided with a second self-locking straight flange which can be abutted against the transmission control moving pin on the transmission control rack, and when the transmission control moving pin is not subjected to external force and is abutted against the second self-locking straight flange, the large square bolt keeps a retracted door locking state.

10. An electrically controlled lock body assembly according to claim 7 wherein: the large square bolt is provided with a second control inclined guide groove which can be abutted against an outgoing control moving pin on the transmission control rack, and when the outgoing control moving pin moves transversely leftwards or rightwards under the action of external force, the second control inclined guide groove is an inclined guide groove, so that the large square bolt is driven to move downwards or upwards to perform door opening or door locking actions.