CN112240132A - Bolt device, electric control lock and door - Google Patents

Abstract

The invention is suitable for the technical field of bolts, and provides a bolt device, which comprises: a fixing plate; the first coil and the second coil are fixedly arranged on the fixing plate; the bolt penetrates through the through hole of the first coil and the through hole of the second coil; and the controller is used for controlling the first coil or the second coil to be electrified, when the first coil is electrified, the plug pin moves towards the first direction, and when the second coil is electrified, the plug pin moves towards the second direction. The invention also provides an electric control lock and a door. Compared with the unlocking and locking of the traditional door lock, the bolt device controls the first coil or the second coil to be electrified through the controller, the first coil or the second coil consumes power and generates magnetic force to drive the bolt to move only at one moment of electrification, the bolt device does not need to be powered all the time to maintain the position of the bolt in order to generate the magnetic force, the power output and consumption are saved, the bolt still keeps in the original position after the bolt device is powered off, the bolt cannot be influenced by the power off, and the safety performance is high.

Description

Bolt device, electric control lock and door

Technical Field

The invention belongs to the field of bolts, and particularly relates to a bolt device, an electric control lock and a door.

Background

Along with the improvement of people's standard of living and the development of science and technology, in people's living environment, the lock no longer is limited to and needs traditional key to open, derives the electromagnetic lock and the electric control lock that accessible response was opened the door. When facing the entrance guard that comes the switch door through electromagnetic lock or electric control lock, people only need respond to through the entrance guard equipment that is suitable for and can open the door, have improved the convenience and the experience of people's life widely and have felt.

However, both electromagnetic and electrically controlled locks have some disadvantages, such as:

firstly, a compression spring, a bolt and an electromagnet are arranged in the electric control lock, when the electric control lock is powered on, the electromagnet generates magnetic force to drive the lock cylinder to lock, if the locking state is to be maintained, the electric control lock is required to be powered on all the time to maintain the magnetic force, larger power consumption exists, and when the electric control lock is powered off, the compression spring pushes the lock cylinder to return, so that the electric control lock is unlocked, and certain safety problems exist;

two, can produce magnetic force when the electromagnetic lock circular telegram, the iron plate that adsorbable set up on the door body closes the door, consequently when needs keep the door body to close, then need keep the production of magnetic force for the electromagnetic lock power supply all the time, so will produce great power consumption to, then can lose magnetic force when the electromagnetic lock outage, and lead to the door can't close, have certain safety problem equally.

Disclosure of Invention

The embodiment of the invention provides a bolt device, and aims to solve the technical problems that the existing electromagnetic lock and electric control lock need to be kept powered to ensure the opening and the locking of a lock body to generate larger power consumption, and the lock body cannot be closed during power failure to cause low safety performance.

The invention is thus achieved, a latch device comprising:

a fixing plate;

the first coil and the second coil are fixedly arranged on the fixing plate;

the bolt penetrates through the through hole of the first coil and the through hole of the second coil; and

the controller is used for controlling the first coil or the second coil to be electrified, when the first coil is electrified, the bolt moves towards a first direction, and when the second coil is electrified, the bolt moves towards a second direction.

The present invention also provides an electrically controlled lock, comprising:

the locking structure is matched with the bolt; and

the bolt device is described above.

Furthermore, the electric control lock also comprises a switch lock trigger mechanism connected with the controller.

Further, the switch lock trigger mechanism is a contact switch lock trigger mechanism and/or a non-contact switch lock trigger mechanism.

Furthermore, the non-contact switch lock triggering mechanism is an infrared sensor.

Furthermore, the electric control lock further comprises a shell, an infrared sensing window is formed in the shell, and infrared light emitted by the non-contact switch lock triggering mechanism penetrates through the infrared sensing window.

Furthermore, the bolt is also provided with a poking part which is used for pushing the bolt to move.

Furthermore, the electric control lock further comprises a door opening and closing state indicating device connected with the bolt, and the door opening and closing state indicating device is used for indicating the opening and closing state of the electric control lock.

The present invention also provides a door, comprising:

a partition plate;

a door body; and

in the electrically controlled lock, the bolt device is arranged on the door body or the partition plate.

Compared with the locking of traditional door locks such as an electric control lock and an electromagnetic lock, the power-on control device has the advantages that the controller controls the first coil or the second coil to be powered on under different conditions, the first coil or the second coil only consumes power at the instant of power on and generates magnetic force to complete driving movement of the bolt, so that the bolt device does not need to be powered on all the time to maintain the position of the bolt in order to generate the magnetic force, the power output is saved, the power consumption is reduced, the bolt still keeps the original position after the bolt device is powered off, the influence of power-off is avoided, and the safety performance is higher.

Drawings

FIG. 1 is a perspective view of a latch assembly according to an embodiment of the present invention;

FIG. 2 is a schematic exploded perspective view of an electric control lock according to an embodiment of the present invention;

FIG. 3 is a schematic perspective view of an electrically controlled lock according to an embodiment of the present invention;

FIG. 4 is a schematic cross-sectional view taken along line A-A of FIG. 3;

FIG. 5 is a schematic plan view of an electrically controlled lock according to an embodiment of the present invention;

fig. 6 is a schematic plan view of a door according to an embodiment of the present invention.

Detailed Description

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

Example one

Referring to fig. 1 to 3, a latch device 10 of the present invention includes a fixing plate 11, a first coil 12, a second coil 13, a latch 14 and a controller 15. The first coil 12 and the second coil 13 are fixed to the fixing plate 11. The first end 141 of the plug 14 penetrates through the first through hole 121 of the first coil 12, and the second end 142 penetrates through the second through hole 131 of the second coil 13. The controller 15 is configured to control the first coil 12 or the second coil 13 to be energized, and the pin 14 moves in the first direction when the first coil 12 is energized, and the pin 14 moves in the second direction when the second coil 13 is energized.

Compared with the unlocking and locking of traditional door locks such as an electric control lock and an electromagnetic lock, the bolt device 10 of the invention controls the first coil 12 or the second coil 13 to be electrified through the controller 15 under two different conditions, the first coil 12 or the second coil 13 only consumes power at the moment of electrification, and magnetic force is generated to complete the driving motion of the bolt 14 at the same time of electrification, so that the bolt device 10 is not required to be powered all the time in order to generate magnetic force to maintain the position of the bolt 14, the power output is saved, and the power consumption is reduced. In addition, after the power is cut off, the latch 14 is still kept at the original position and is not influenced by the power failure, and the safety performance is high. The driving time of the first coil 12 or the second coil 13 to the bolt 14 is less than 0.1 second, the hour power consumption is less than 0.005WH, the energy consumption is low, and the energy-saving effect is good.

Specifically, the fixing plate 11 is used for fixing the first coil 12 and the second coil 13, which can prevent the first coil and the second coil from moving and causing the latch 14 to be skewed. The latch 10 may be connected to a power source to power the first coil 12 and the second coil 13. The plug 14 is made of metal, and a first end 141 and a second end 142 thereof respectively penetrate through the first via hole 121 of the first coil 12 and the second via hole 131 of the second coil 13.

In the latch device 10 according to the embodiment of the present invention, the controller 15 includes a first driving circuit and a second driving circuit, the first coil 12 is connected to the first driving circuit and is controlled by the first driving circuit to conduct current, the first coil 12 is responsible for unlocking, the second coil 13 is connected to the second driving circuit and is controlled by the second driving circuit to conduct current, and the second coil 13 is responsible for locking.

Referring to fig. 1, 2 and 6, when the latch 10 is powered up: when the electronic control lock 100 needs to be locked, the bolt 14 needs to be driven to move rightwards in fig. 6, at this time, the second driving circuit works and controls the current conduction of the second coil 13 for a certain time, so that the second coil 13 generates magnetic force to drive the bolt 14 to move rightwards and extend out of the bolt device 10 for a certain distance, and the first coil 12 is in a current off state at this time; when the latch device 10 needs to be opened, the latch 14 needs to be driven to move leftward in fig. 6, at this time, the first driving circuit operates and controls the current of the first coil 12 to be conducted for a certain period of time, so that the first coil 12 generates a magnetic force to drive the latch 14 to move leftward and return, and the second coil 13 is in a current-off state at this time. In other embodiments, the first coil 12 may be configured to lock and the second coil 13 may be configured to unlock, and is not limited herein.

In the embodiment of the present invention, please refer to fig. 6, wherein the first direction is a left direction of the figure, and the second direction is a right direction of the figure; in other embodiments, the first direction and the second direction may also be other opposite directions, and are not limited herein.

Example two

Referring to fig. 1, 2 and 6, an electrically controlled lock 100 according to an embodiment of the present invention includes a deadbolt assembly 10 and a lock-out structure 20 cooperating with the deadbolt assembly.

In the electric control lock 100 according to the embodiment of the present invention, compared with the locking of the conventional door locks such as the electric control lock and the electromagnetic lock, the first coil 12 or the second coil 13 is controlled by the controller 15 under different conditions to turn on or off the current, the first coil 12 or the second coil 13 consumes power only at the instant of power supply, and generates a magnetic force to complete the driving motion of the plug 14 while the first coil 12 or the second coil 13 is powered on. When the electric control lock 100 is applied to a scene of opening and closing a door, an entrance guard and the like, the electric control lock 100 does not need to be powered all the time in order to generate magnetic force to maintain the position of the bolt 14, namely, the electric control lock 100 does not need to be continuously powered in order to keep locked, so that the power output is saved, the power consumption is reduced, even after the electric control lock 100 is powered off, the bolt 14 still keeps the original position, the influence of power failure cannot be caused, and the safety performance is high.

Specifically, according to different requirements, the electric control lock 100 may be disposed inside or outside the door of a related place or a related object, and if the electric control lock 100 is disposed on the door lock, the electric control lock may be disposed outside the door lock, so that the user can conveniently open the door from the outside. In one embodiment, the electric control lock 100 further includes a housing 30, and the housing 30 is used for accommodating the latch assembly 10, the controller 15 and other structures of the electric control lock 100, so as to reduce the influence of external moisture, impurities, external force and other factors on the components in the electric control lock 100, and enable the electric control lock 100 to form a whole, which is more compact and integrated and is convenient for installation and disassembly. The housing 30 can be made of metal or plastic and has certain strength and hardness, so that the internal structure of the electric control lock 100 can be effectively protected; of course, in other embodiments, the housing 30 may be made of other materials.

The shell 30 (the bolt 14) and the locking structure 20 are respectively arranged on different parts of the door body, and the door body is simply and effectively closed or opened through the cooperation of the bolt 14 and the locking structure 20. The locking structure 20 may be a hole, a groove, a cavity, or the like formed on the other side of the door body, and may be configured to cooperate with the latch 14 for locking, or may be a component having a hole, a groove, a cavity, or the like.

When the electrically controlled lock 100 is used in a toilet, for example, when a user uses the toilet, before sensing with the electrically controlled lock 100, the user can firstly push the toilet door, where the electrically controlled lock 100 is installed, to a set position by hand or foot to align the bolt 14 with the locking structure 20, and then sensing with the switch lock triggering mechanism 40, so that the bolt 14 can be directly moved to extend into the locking structure 20 to lock the toilet; when the user finishes using the toilet, sensing with the electric lock 100 again, the bolt 14 can return directly and disengage from the locking structure 20 to open the toilet.

Further, referring to fig. 4 and 6, the latch 14 is formed with a toggle portion 143. It can be understood that when the electric control lock 100 is powered off, the first coil 12 and the second coil 13 are both in a power-off state, and at this time, the bolt 14 is not affected by magnetic force and still in the original position, if the original electric control lock 100 is in a locking state, when the user wants to open the electric control lock 100, the bolt 14 can be manually moved by toggling the toggle part 143 formed on the bolt 14, so that the electric control lock 100 is opened. The first coil 12 and the second coil 13 consume power only at a moment of action, so that the unlocking or locking duration time of the electric control lock 100 is less than 0.1 second, the hourly power consumption is less than 0.005WH, the electric control lock 100 consumes less energy, and the energy-saving effect is better.

In an embodiment, the controller 15 may be a single chip microcomputer, the single chip microcomputer has a better data processing capability and control capability, and the specific selected model may be, for example, STM8S207CBT6, ATMEGA168PA-AU, STM8L151C8T6, and the like, which is not limited herein.

EXAMPLE III

Further, referring to fig. 2 and 4, the electrically controlled lock 100 further includes a switch lock triggering mechanism 40 connected to the controller 15.

Specifically, in this embodiment, the switch lock trigger mechanism 40 may receive a switch lock trigger from the outside, and when the switch lock trigger is received, an unlocking or locking sensing signal may be sent to the controller 15, where the sensing signal may be an electrical signal or the like. The controller 15 can control the current on-off of the first coil 12 or the second coil 13 according to the unlocking or locking sensing signal, that is, according to different conditions, so as to control the movement of the bolt 14, thereby achieving the purpose of controlling the unlocking or locking of the electric control lock 100.

Illustratively, when the controller 15 receives the latching trigger signal of the switch latch trigger mechanism 40, the controller 15 controls the current of the second coil 13 to be conducted for a certain time, so that the second coil 13 generates a magnetic force to drive the bolt 14 to move rightwards and extend out of the electric control latch 100 for a certain distance, and the first coil 12 is in a current off state at this time; when the controller 15 receives the unlocking trigger signal of the switch lock trigger mechanism 40, the current of the first coil 12 is controlled to be conducted for a certain period of time, so that the first coil 12 generates magnetic force to drive the latch device 10 to move leftwards and return, and the second coil 13 is in a current off state at this time.

Example four

Further, the switch lock trigger mechanism 40 is a contact switch lock trigger mechanism 40 and/or a non-contact switch lock trigger mechanism 40.

It can be understood that the contact switch lock triggering mechanism 40 needs the user to perform the triggering induction with the electric control lock 100 by means of contact, and the contact may be fingerprint identification induction, password input, touch control on/off of current, and the like; the non-contact switch lock triggering mechanism 40 is used for triggering and sensing the user with the electric control lock 100 in a non-contact manner, and the non-contact sensing manner includes, but is not limited to, infrared sensing, voice control, visual sensing, wireless (WIFI, bluetooth, 4G/5G, etc.) sensing, and the like.

By connecting the switch lock trigger mechanism 40 with the controller 15, and connecting the controller 15 with the first coil 12 and the second coil 13, when a user and the switch lock trigger mechanism 40 generate contact or non-contact induction, the first coil 12 and the second coil 13 can be controlled by the controller 15, so as to achieve the purpose of controlling the closing and opening of the electric control lock 100 by the contact induction triggering or the non-contact induction triggering in different scenes.

In the embodiment shown in fig. 2, the switch lock trigger mechanism 40 is a non-contact switch lock trigger mechanism 40. The contact switch lock trigger mechanism 40 and the non-contact switch lock trigger mechanism 40 may be used alone or in combination in different usage scenarios, and are not limited herein.

In an implementation scenario of the electrically controlled lock 100, the electrically controlled lock 100 may be used for a toilet door in a public place, and in this case, the switch lock triggering mechanism 40 is a non-contact switch lock triggering mechanism 40. Generally, at present, toilets in public places, such as station or railway station toilets, park toilets, hospital ward toilets, market toilets, cinema toilets and the like, are locked and closed through simple mechanical structures, such as door bolts and the like. When the user uses the toilet, he needs to actively insert and open the bolt by hand, and the user inevitably touches a specific part of the bolt.

However, since the flow of people in public places is large, when different users use the same toilet, the users can easily get infected by touching the door bolt, and the germs carried by others or the germs in the toilet are infected, so as to cause cross infection.

At this time, the electric control lock 100 may be disposed inside a door of a toilet in a public place, that is, inside a toilet, so as to prevent the toilet from being opened by other users from outside the toilet when the user uses the toilet. Be applied to public place bathroom with electric control lock 100 to carry out non-contact's response through between non-contact switch lock trigger mechanism 40 and the user and trigger, the user need not to touch electric control lock 100 voluntarily, can open and close through power drive bolt device 10 after electric control lock 100 is gone up the electricity, the cross infection's that has avoided current public place to need the user to touch the keeper voluntarily effectively, and electric control lock 100's structure is comparatively simple, and power consumption is low, also easily installation dismantlement, the construction degree of difficulty has been reduced.

EXAMPLE five

Further, the non-contact switch lock trigger mechanism 40 is an infrared sensor.

In this embodiment, the infrared sensor is set as the non-contact switch lock trigger mechanism 40, and the non-contact switch lock trigger mechanism 40 is connected to the controller 15, and the infrared sensor can sense the human body, so that the purpose of controlling the electric control lock 100 to open and close by the human body is achieved through infrared trigger sensing.

Illustratively, the electric control lock 100 is disposed on the door body, and after the electric control lock 100 is powered on, in a standby state:

when the hand of the user approaches the infrared sensing area of the non-contact switch lock trigger mechanism 40, the controller 15 receives a sensing signal sent by the non-contact switch lock trigger mechanism 40, the second driving circuit works to control the second coil 13 to be electrified, the second coil 13 generates magnetic force to drive the bolt 14 to extend out of the electric control lock 100 for a certain distance, and at the moment, the door body is blocked by the bolt 14 and is locked;

when the hand of the user approaches the infrared sensing area of the non-contact switch lock triggering mechanism 40 again, the controller 15 receives the sensing signal again, the first driving circuit works to control the first coil 12 to be powered on, the first coil 12 generates magnetic force to drive the latch device 10 to return, and at this time, the door body is unlocked without being blocked by the latch device 10. Through the closed-loop control of locking and unlocking, the electronic control lock 100 locks and unlocks the toilet door, and non-contact sensing between a user and the non-contact switch lock trigger mechanism 40 is realized.

In one embodiment, when the electric control lock 100 is applied to a toilet door in a public place, the infrared sensor may be a short-distance infrared sensor capable of emitting infrared light at a relatively strong distance to sense a person or an object within a set, short sensing distance and emit a sensing signal, so as to effectively avoid misoperation.

Moreover, the electric control lock 100 can only sense the user within a close sensing distance set by the close-distance infrared sensor, so that the condition that the user triggers the sensing by mistake in the toilet to open the toilet door by mistake if the sensing distance is too large can be avoided. The close-range infrared induction is a mature induction technology, has a good induction effect, and the close-range infrared induction sensor is relatively low in price, so that the production cost of the electric control lock 100 is reduced.

In one embodiment, the sensing distance L of the near infrared sensor is: l is more than 0cm and less than or equal to 50 cm.

Within the sensing distance L, the user can be prevented from erroneously triggering the switch lock trigger mechanism 40 in the toilet. In other embodiments, the sensing distance L of the non-contact switch lock triggering mechanism 40 may also be specifically set according to actual requirements, and is not limited to the above sensing distance L.

Still further, the contactless switch latch trigger mechanism 40 may further include one or more of a visual sensor, a microphone, and a wireless communication module.

More forms of non-contact sensing between the electrically controlled lock 100 and the user can be achieved by the non-contact switch lock triggering mechanism 40 of the above example. Specifically, a visual sensor, such as a camera, a video camera, etc., may implement non-contact sensing between the electronic control lock 100 and a user in a video or image manner; a microphone such as a loudspeaker, a loudspeaker and the like can realize non-contact induction between the electric control lock 100 and a user in a voice control mode; the wireless communication module, such as WIFI, bluetooth, radio frequency, 4G/5G, zigbee, etc., realizes the non-contact induction between the electric control lock 100 and the user through a wireless communication mode.

It should be noted that the above examples of the non-contact switch lock triggering mechanism 40 can be used in combination to achieve diversified sensing between the electric control lock 100 and the user.

EXAMPLE six

Further, referring to fig. 2 to 5, the housing 30 is provided with an infrared sensing window 31, and the infrared light emitted by the non-contact switch lock triggering mechanism 40 passes through the infrared sensing window 31.

The non-contact type switch lock triggering mechanism 40 (i.e., the infrared sensor) corresponds to the infrared sensing window 31, so that the infrared light emitted therefrom can pass through the infrared sensing window 31 toward a set direction, so that a user can perform non-contact type switch door in the set direction. Meanwhile, the non-contact switch lock trigger mechanism 40 is arranged corresponding to the infrared sensing window 31, so that the influence on the sensing effect of the non-contact switch lock trigger mechanism 40 due to the shielding of infrared light emitted by the non-contact switch lock trigger mechanism 40 by the electric control lock 100 or other parts of the shell 30 can be avoided.

More, the infrared sensing window 31 may further be embedded with a spacing element 32 that does not affect infrared light transmission, and the spacing element 32 may be made of transparent materials such as glass and plastic, and has certain strength and hardness, so that the non-contact switch lock trigger mechanism 40 inside the infrared sensing window 31 may be protected on the premise that infrared light transmission is not affected.

EXAMPLE seven

Furthermore, the electric control lock 100 further comprises a door opening and closing state indicating device connected with the bolt 14, and the door opening and closing state indicating device is used for indicating the opening and closing state of the electric control lock 100.

Specifically, the door opening and closing indicating device may be an indicating block moving left and right along with the plug 14, the indicating block may be wholly or partially exposed from the casing 30, and may be marked with "someone" or "nobody", or marked with "red" or "green" or the like to indicate different characters or different colors of different use states of the door body, and through the different characters or colors, the user is intuitively reminded of the current use state of the door body, that is, the opening and closing states of the door body and the electric control lock 100.

Illustratively, when the electrically controlled lock 100 is applied to a toilet, if a user uses the toilet, the door opening and closing state indicating device moves along with the bolt 14, the marked part which is originally displayed as "nobody" moves and is hidden in the housing 30, and the marked part which is originally hidden in the housing 30 changes into an exposed display; when no one uses the toilet, the door opening and closing state indicating device moves and hides the marked part which is originally shown as 'person' in the shell 30 along with the return of the bolt 14, and the marked part which is originally hidden in the shell 30 becomes exposed and displayed. In this way, indication of the use state of the toilet with or without a person is achieved in a simple and effective mechanical manner.

In one embodiment, the door opening and closing status indicator may also be connected to the controller 15, and in this case, the door opening and closing status indicator may be a display screen. Illustratively, when a trigger induction occurs between the switch lock trigger mechanism 40 and the user and an induction signal is generated, the controller 15 controls the door opening and closing state indicating device to change the displayed content according to the induction signal, wherein the displayed content may be characters, images, background colors, and the like, such as displayed "no people" characters, and the change is displayed as "people" characters; or by a "green" background that shows no people, a "red" background that shows people, etc.

Further, referring to fig. 2 and fig. 4, the electric control lock 100 further includes a power supply device 60. In the present embodiment, the power supply device 60 is a battery compartment and a dry battery. In one embodiment, the battery is a rechargeable battery. In another embodiment, the power supply device may be an external AC device, such as an external adapter, for supplying 12V power.

Example nine

Referring to fig. 2 and 6, the door 1000 includes the electric control lock 100, a door body 200, and a partition 300, and the latch device 10 of the electric control lock 100 is disposed on the door body 200 or the partition 300.

The door 1000 of the embodiment of the present invention is provided with the electric control lock 100, and the first coil 12 or the second coil 13 is controlled by the controller 15 to be switched on or off under different conditions, so that the first coil 12 or the second coil 13 consumes power only at the instant of power supply, and generates magnetic force to complete the driving motion of the latch 14 while the first coil 12 or the second coil 13 is powered on. When the electric control lock 100 is applied to a scene of opening and closing a door, an entrance guard and the like, the electric control lock 100 does not need to be powered all the time in order to generate magnetic force to maintain the position of the bolt 14, namely, the electric control lock 100 does not need to be continuously powered in order to keep locked, so that the power output is saved, the power consumption is reduced, even after the electric control lock 100 is powered off, the bolt 14 still keeps the original position, the influence of power failure cannot be caused, and the safety performance is high.

When the door 1000 of the present embodiment is applied to a toilet in a public place, a user does not need to actively touch the electric control lock 100, and the electric control lock 100 can open and close the toilet door through electric driving under non-contact triggering, thereby effectively avoiding the problem of cross infection caused by the fact that the user actively touches the door bolt in the existing public toilet.

More, the electric control lock 100 can be fixed on the door 200 or the partition 300 by screw fastening, rivet fastening, adhesive bonding, snap fastening, etc., and the locking structure 20 is correspondingly disposed on the partition 300 or the door 200, and the electric control lock 100 is located at the inner side of the toilet. In one embodiment, the electric control lock 100 can be fixed on the door body 200 or the partition plate 300 by screwing screws, so that the stability is good, and the installation and the disassembly are convenient; in other embodiments, the electric control lock 100 may also be fixed to the door 200 or the partition 300 by other means, which is not limited herein. In the example of fig. 1, the electric control lock 100 is disposed on the door body 200, and the locking structure 20 is disposed on the partition 300; in other embodiments, the electrically controlled lock 100 may also be disposed on the partition 300, and the locking structure 20 is disposed on the door body 200, which is not limited in this respect.

In the description herein, references to the description of the terms "example one," "example two," etc. mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. A deadbolt assembly, comprising:

a fixing plate;

the first coil and the second coil are fixedly arranged on the fixing plate;

the bolt penetrates through the through hole of the first coil and the through hole of the second coil; and

the controller is used for controlling the first coil or the second coil to be electrified, when the first coil is electrified, the bolt moves towards a first direction, and when the second coil is electrified, the bolt moves towards a second direction.

2. An electrically controlled lock, comprising:

the locking structure is matched with the bolt; and

the latch mechanism of claim 1.

3. The electrically controlled lock of claim 2 further comprising a switch lock trigger mechanism coupled to the controller.

4. The electrically controlled lock according to claim 3, wherein the switch lock trigger mechanism is a contact switch lock trigger mechanism and/or a non-contact switch lock trigger mechanism.

5. The electrically controlled lock according to claim 4 wherein the non-contact switch lock trigger mechanism is an infrared sensor.

6. The electric control lock of claim 5, further comprising a housing, wherein the housing is provided with an infrared sensing window, and infrared light emitted by the non-contact switch lock trigger mechanism passes through the infrared sensing window.

7. The electrically controlled lock of claim 2 further comprising an open/close door status indicator means connected to said bolt for indicating the open/close lock status of said electrically controlled lock.

8. An electrically controlled lock according to claim 2 wherein the bolt is further provided with a toggle portion for urging movement of the bolt.

9. A door, comprising:

a partition plate;

a door body; and

an electrically controlled lock according to any one of claims 2 to 8 wherein the latching means of the electrically controlled lock is provided on the door or the partition.

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