Disclosure of Invention
The invention aims to at least solve one of the technical problems in the prior art and provide a full-automatic lock body which can select whether a mechanical part and a motor part are linked or not.
The technical scheme adopted by the embodiment of the invention for solving the technical problems is as follows:
According to a first aspect of the present invention, there is provided a fully automatic lock body comprising: a lock case; the lock tongue assembly is arranged on the lock shell in a sliding manner; the electronic driving assembly is arranged in the lock shell and can drive the lock tongue assembly to extend out for locking or retract for unlocking; the induction component is arranged in the lock shell and is electrically connected with the electronic driving component; the mechanical driving assembly is arranged in the lock shell and comprises a stirring assembly capable of stirring the lock tongue assembly and a transmission assembly rotationally arranged in the lock shell, the transmission assembly is connected with the stirring assembly, and the transmission assembly can be connected with an external rotation unlocking mechanism; the linkage control assembly is positioned in the lock shell and comprises a linkage driving mechanism and a linkage piece, wherein the linkage driving mechanism can drive the linkage piece to move to the position between the stirring assembly and the transmission assembly, so that the transmission assembly can drive the stirring assembly to rotate and unlock through the linkage piece when rotating.
The full-automatic lock body has the following beneficial effects: after receiving the electric signal, the electronic driving assembly drives the lock tongue assembly to retract, so that unlocking is performed. The external rotation unlocking mechanism is connected with the transmission assembly, and when the linkage piece moves between the stirring assembly and the transmission assembly, the transmission assembly can drive the stirring assembly to unlock, so that the external rotation unlocking mechanism has an unlocking function. Through operating the coordinated control subassembly, can select to let mechanical drive subassembly have the unblock function or not have the unblock function, consequently can select whether mechanical unlocking and electronic unlocking link to prevent two mutual interference, perhaps one side damages the problem that leads to another party to be unable to use.
According to the full-automatic lock body disclosed by the first aspect of the invention, the linkage driving mechanism comprises a rotatable connecting column and a linkage part, and a boss is arranged on the connecting column; the linkage part is connected with a reset mechanism; the transmission assembly comprises a first shifting block connected with the shifting assembly, a first baffle table is arranged on the first shifting block, and after the boss pushes the linkage part to move, the linkage part is positioned in the movement direction of the first baffle table and can drive the first baffle table to move.
According to the full-automatic lock body disclosed by the first aspect of the invention, the transmission assembly comprises a rotatable main shifting block, a second shifting block is fixedly connected to the main shifting block, a first strip-shaped hole is formed in the second shifting block, and the linkage piece is movably arranged in the first strip-shaped hole.
According to the full-automatic lock body disclosed by the first aspect of the invention, the linkage part is provided with the second strip-shaped hole, the section shape of the second strip-shaped hole is arc-shaped, the arc direction is the same as the rotation direction of the main shifting block, and the linkage part is movably arranged in the second strip-shaped hole.
According to the full-automatic lock body disclosed by the first aspect of the invention, the induction component is further arranged in the lock shell and comprises an induction lock tongue and a tact switch, the tact switch is electrically connected with the electronic driving component, and the induction lock tongue is arranged on the lock shell in a sliding manner and can slide to be abutted against the tact switch.
According to the full-automatic lock body disclosed by the first aspect of the invention, a duplex gear is arranged in the lock shell, the duplex gear comprises a first tooth part and a second tooth part, and the transmission assembly is provided with a meshing tooth part meshed with the first tooth part; the electronic driving assembly is connected with a rack, and the rack is meshed with the second tooth part; the duplex gear or the rack is provided with a connecting part connected with the stirring assembly.
According to the full-automatic lock body disclosed by the first aspect of the invention, the poking assembly comprises a first poking block and a second poking block, the first poking block is hinged with the second poking block, and a tail plate is arranged on the first poking block and/or the second poking block; the spring bolt assembly comprises a first spring bolt, a connecting spring for driving the first spring bolt and the second spring bolt to clamp the first spring bolt is arranged between the first toggle block and the second toggle block, and a reset spring is connected to the first spring bolt.
According to the full-automatic lock body disclosed by the first aspect of the invention, the transmission assembly comprises a third shifting block, a second baffle table is arranged on the third shifting block, and the linkage piece is positioned in the movement direction of the second baffle table and can drive the second baffle table to move; the tail end of the tail plate is positioned in the movement direction of the third shifting block and can be shifted by the third shifting block.
According to the full-automatic lock body disclosed by the first aspect of the invention, the connecting block is arranged on the rack, and the tail end of the tail plate is positioned in the moving direction of the connecting block and can drive the connecting block to move.
According to the full-automatic lock body disclosed by the first aspect of the invention, the lock tongue assembly comprises a second lock tongue, the transmission assembly comprises a linkage plate, the second lock tongue is arranged on the linkage plate, and an opening is formed in the linkage plate;
the connecting portion comprises a connecting rod, one end of the connecting rod is fixed on the duplex gear, and the other end of the connecting rod is movably installed in the opening.
Drawings
The invention will be described in further detail with reference to the drawings and the detailed description.
FIG. 1 is a schematic diagram of an internal structure according to one embodiment;
FIG. 2 is a third dial-block connection schematic according to an embodiment;
FIG. 3 is a first dial-block connection schematic according to an embodiment;
FIG. 4 is an exploded schematic view according to one embodiment;
FIG. 5 is a schematic diagram of an unlocked state according to one embodiment;
FIG. 6 is a schematic diagram of a locked state according to one embodiment.
Reference numerals: the lock case 10, the motor 20, the screw 21, the screw nut 22, the rack 31, the toggle assembly 40, the first toggle block 41, the second toggle block 42, the tail plate 43, the first lock tongue 44, the linkage plate 45, the second lock tongue 46, the opening 47, the lock tongue assembly 48, the duplex gear 50, the first tooth part 51, the second tooth part 52, the main toggle block 66, the transmission assembly 60, the second toggle block 61, the third toggle block 62, the first toggle block 63, the slide block 64, the slide groove 65, the linkage driving mechanism 70, the connecting post 71, the boss 72, the linkage part 73, the linkage piece 74, the reset mechanism 75, the first bar hole 81, the second bar hole 82, the second block 83, the first block 84, the sensing assembly 90, the sensing lock tongue 91, and the tact switch 92.
Detailed Description
Reference will now be made in detail to the present embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein the accompanying drawings are used to supplement the description of the written description so that one can intuitively and intuitively understand each technical feature and overall technical scheme of the present invention, but not to limit the scope of the present invention.
In the description of the present invention, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present invention and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.
In the description of the present invention, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.
In the description of the present invention, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present invention can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.
Referring to fig. 1, a fully automatic lock body includes: a lock case 10; a latch bolt assembly 48 slidably disposed on the lock housing 10; an electronic drive assembly disposed within the lock housing 10 and capable of driving the latch bolt assembly 48 to extend for locking or retract for unlocking; the induction component 90 is arranged in the lock shell 10 and is electrically connected with the electronic driving component; the mechanical driving assembly is arranged in the lock shell 10 and comprises a stirring assembly 40 capable of stirring the lock tongue assembly 48 and a transmission assembly 60 rotatably arranged in the lock shell 10, the transmission assembly 60 is connected with the stirring assembly 40, and the transmission assembly 60 can be connected with an external rotation unlocking mechanism; the linkage control assembly is located in the lock case 10 and comprises a linkage driving mechanism 70 and a linkage piece 74, wherein the linkage driving mechanism 70 can drive the linkage piece 74 to move between the stirring assembly 40 and the transmission assembly 60, so that the stirring assembly 40 can be driven to rotate and unlock by the linkage piece 74 when the transmission assembly 60 rotates. The sensing assembly 90 will send an electrical signal to the electronic drive assembly when it senses the proximity of the door frame like member. The electronic drive assembly in turn retracts the latch bolt assembly 48 to unlock the lock. The external rotation unlocking mechanism is connected with the transmission assembly 60, and when the linkage piece 74 moves between the stirring assembly 40 and the transmission assembly 60, the transmission assembly 60 can drive the stirring assembly 40 to unlock, so that the external rotation unlocking mechanism has an unlocking function. Through operating the coordinated control subassembly, can select to let mechanical drive subassembly have the unblock function or not have the unblock function, consequently can select whether mechanical unlocking and electronic unlocking link to prevent two mutual interference, perhaps one side damages the problem that leads to another party to be unable to use.
In some embodiments, the deadbolt unit includes a first deadbolt 44 and a second deadbolt 46, each of which are independent. The first latch tongue 44 and the second latch tongue 46 may form a double locking effect, thereby enhancing reliability of the lock body.
In some embodiments, referring to fig. 1 and 4, the linkage drive mechanism 70 includes a rotatable connection post 71 and a linkage portion 73, with a boss 72 provided on the connection post 71; the reset mechanism 75 is connected to the linkage part 73; the transmission assembly 60 comprises a first shifting block 63 connected with the shifting assembly 40, a first baffle table 84 is arranged on the first shifting block 63, and after the boss 72 pushes the linkage part 73 to move, the linkage piece 74 is positioned in the movement direction of the first baffle table 84 and can drive the linkage part to move. When the connecting post 71 rotates, the boss 72 is driven to rotate, so that the linkage part 73 is gradually pushed or released. After the linkage 73 moves, the linkage 74 will be located in the moving direction of the first block 84. Because the linkage member 74 is located in the installation area, the rotation of the linkage member 74 can drive the first baffle table 84 to move, so as to drive the first shifting block 63 to move, and further complete locking or unlocking.
In certain embodiments, referring to fig. 1, the reset mechanism 75 comprises a spring wire. The spring wire is wound around the linking portion 73 and abuts against the inner wall of the lock case 10.
In some embodiments, referring to fig. 1 and 4, the transmission assembly 60 includes a main dial 66 that is rotatable, a second dial 61 is fixedly connected to the main dial 66, a first bar-shaped hole 81 is provided on the second dial 61, and the linkage member 74 is movably mounted in the first bar-shaped hole 81. The inner space of the first bar-shaped hole 81 is the installation area. The linkage 74 is positioned within the first bar aperture 81. When the linkage part 73 pushes the linkage member 74 to move, the linkage member 74 moves along the center line direction of the first bar-shaped hole 81 so as to approach or separate from the first blocking table 84. When the main dial 66 rotates, the first bar-shaped hole 81 also rotates along with the main dial, so that the linkage 74 is driven to rotate.
In some embodiments, referring to fig. 3 and 4, the linkage part 73 is provided with a second bar-shaped hole 82, the cross-section of the second bar-shaped hole 82 is arc-shaped, the arc direction is the same as the rotation direction of the main dial 66, and the linkage member 74 is movably mounted in the second bar-shaped hole 82. When the main dial 66 drives the linkage member 74 to rotate through the inner wall of the first bar-shaped hole 81, the linkage member 74 moves in the second bar-shaped hole 82. When the linkage 73 moves, the inner wall of the second bar-shaped hole 82 pushes the linkage 74 to move in the first bar-shaped hole 81.
In some embodiments, referring to fig. 4, the first bar-shaped hole 81 is shaped as a straight bar, and a length center line of the first bar-shaped hole 81 is parallel to a movement direction of the linkage 73. The first straight hole 81 allows the linkage 74 to move only linearly with respect to the main dial 66, so that the linkage 73 can move only linearly with respect to the main dial 66, and thus it is ensured that the movement track of the linkage 73 is not excessively disturbed.
In certain embodiments, referring to fig. 1 and 4, a duplex gear 50 is disposed within the lock housing 10, the duplex gear 50 including a first tooth 51 and a second tooth 52, and a drive assembly 60 having meshing teeth for meshing with the first tooth 51; the electronic driving assembly is connected with a rack 31, and the rack 31 is meshed with the second tooth part 52; the duplex gear 50 is provided with a connection portion to the toggle assembly 40. The first tooth portion 51 is connected with the engagement tooth portion, the second tooth portion 52 is connected with the rack 31, and the connecting portion is connected with the locking portion, so that the duplex gear 50 is simultaneously connected with the lock tongue assembly 48, the driving assembly and the first shifting block 63, and the three can be linked through the duplex gear 50.
In some embodiments, referring to fig. 1 and 2, the driving assembly includes a motor 20, the motor 20 is disposed in the lock housing 10, an output shaft of the motor 20 is connected to a screw 21, a screw nut 22 is screwed on the screw 21, and a rack 31 is relatively fixed to the screw nut 22.
In certain embodiments, referring to fig. 3 and 4, latch bolt assembly 48 includes a second latch bolt 46, and drive assembly 60 includes a interlock plate 45, second latch bolt 46 being mounted on interlock plate 45, interlock plate 45 having an opening 47 therein; the connecting portion includes a connecting rod, one end of which is fixed to the duplex gear 50, and the other end of which is movably installed in the opening 47. When the duplex gear 50 rotates, the connecting rod will be driven to move, and after the connecting rod moves in the opening 47 to abut against the inner wall of the opening, the connecting rod will push the linkage plate 45 to move so as to drive the lock tongue to move, thus completing the locking or unlocking process.
In some embodiments, the number of the second bolts 46 is three, the three second bolts 46 are all disposed on the linkage plate 45, and the three second bolts 46 are all main pulling blocks.
In some embodiments, referring to fig. 1 and 2, the toggle assembly 40 includes a first toggle block 41 and a second toggle block 42, the first toggle block 41 and the second toggle block 42 are hinged, and a tail plate 43 is disposed on the first toggle block 41; the latch bolt assembly 48 includes a first latch bolt 44, a connecting spring for driving the first latch bolt 44 to clamp the first latch bolt 44 is arranged between the first toggle block 41 and the second toggle block 42, and a reset spring is connected to the first latch bolt 44. The first toggle block 41 and the second toggle block 42 are typically close to each other and clamp the first latch 44 under the action of the connecting spring. When the tail plate 43 is driven, the first toggle block 41 and the second toggle block 42 are far away from each other, so that the first lock tongue 44 is loosened, and the first lock tongue 44 can spring back into the lock case 10.
In some embodiments, the opposite side walls of the first latch 44 are sloped side walls (not shown) that gradually slope toward the center of the first latch 44 from the end near the connecting spring to the end outside the lock case 10. The sloped sidewall allows the first latch 44 to be moved and the sloped sidewall is subject to an external force such that the first latch 44 will be pressed back into the lock housing 10, thereby unlocking.
In some embodiments, two opposite side walls of the first lock tongue 44 are provided with a step (not shown in the drawings), the first toggle block 41 and the second toggle block 42 are abutted against the step, and the plane abutted by the return spring is parallel to the step. After the first toggle block 41 and the second toggle block 42 are abutted against the first lock tongue 44, the first lock tongue 44 cannot be pressed back into the lock case 10, so that the locking state is maintained. When the first toggle block 41 and the second toggle block 42 are far away from each other, the step position is released, and the first lock tongue 44 is pressed back into the lock case 10.
In some embodiments, referring to fig. 3, the transmission assembly 60 includes a third shifting block 62, and a second blocking table 83 is disposed on the third shifting block 62, and the linkage 74 is located in the movement direction of the second blocking table 83 and can drive the second blocking table to move; the end of the tail plate 43 is located in the direction of movement of the third dial 62 and can be shifted by the third dial 62. After the linkage part 73 moves to the movement direction of the second blocking platform 83, when the main shifting block 66 rotates, the linkage part 73 is driven to move through the installation area, so that the second blocking platform 83 and the third shifting block 62 are driven to move, and the tail plate 43 is driven to move, so that the first shifting block 41 and the second shifting block 42 are far away from each other. Thus, after the linkage 73 moves, the movement of the main dial 66 may drive the tail 43 to move, thereby operating the fixed state of the tongue.
In some embodiments, referring to FIG. 2, a slide groove 65 is provided on the third dial 62, a slide block 64 is provided on a side wall of the main dial 66, and the slide block 64 is movably mounted in the slide groove 65. When the linkage 73 is not moved, the main dial 66 rotates, and the slider 64 moves in the slide groove 65. When the main shifting block 66 rotates to a certain extent, the sliding block 64 drives the sliding groove 65 to move, so that the effect that the unlocking is not controlled by small-amplitude rotation of the handle and the unlocking is controlled by large-amplitude rotation of the handle is achieved.
In some embodiments, referring to fig. 1 and 3, a connection block is provided on the rack 31, and the end of the tail plate 43 is located in the movement direction of the connection block and can move the connection block. The movement of the rack 31 can drive the tail plate 43 to move, so that the first poking block 41 and the second poking block 42 are close to or far away from each other. Thus, the drive assembly may drive the locking or unlocking process.
In some embodiments, referring to fig. 1 and 3, an induction lock tongue 91 is disposed in the lock case 10, the induction lock tongue 91 is movably telescopic into the lock case 10, a tact switch 92 is further disposed in the movement direction of the induction lock tongue 91, and a coil spring is further connected between the lock case 10 and the induction lock tongue 91. The tact switch 92 is electrically connected to a control circuit (not shown) which is connected to the driving unit. After the sensing bolt 91 receives an external force, it is pressed into the lock case 10 and abuts against the tact switch 92. After the tact switch 92 is touched, an electrical signal is sent to the control circuit, and the control circuit enables the driving assembly to start to operate, so that the purposes of intelligent sensing and unlocking when the door is closed are achieved.
In some embodiments, the control circuit is electrically connected to a fingerprint sensor (not shown). When the fingerprint sensor senses the fingerprint of a user, the fingerprint sensor sends an electric signal to the control circuit so as to unlock.
The embodiments of the present invention have been described in detail above with reference to the accompanying drawings, but the present invention is not limited to the above embodiments or combinations, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit of the present invention.