CN210109895U - Electronic verification device - Google Patents

Abstract

The utility model provides an electronic verification device to make corresponding operation according to user's relevant data, include: a mirror for the user to align with the verification location; a starting component for collecting the relevant data of the user after aligning the position in a power supply mode; and a response component, which is driven by the starting component to execute the corresponding operation of the starting component after collection and after verification, wherein the response component comprises an unlocking component, the unlocking component is controlled by the starting component to operate, the starting component is cooperatively arranged on the mirror, the starting component is used for pertinently collecting the relevant data of the user and judging whether an unlocking instruction is output, the response component is used for executing the unlocking instruction after obtaining energy and the unlocking instruction from the starting component, and the requirement of electronic collection power supply can be met without self-prepared energy sources, so that intelligent collection and identification are realized, and safe and convenient verification unlocking is further provided.

Description

Electronic verification device

Technical Field

The present invention relates to electronic devices, and more particularly to a self-powered electronic verification device, such as an electronic lock.

Background

With the development of intelligent technologies, many traditional devices are developing into electronics so as to adapt to the trend of the internet of things. However, although many devices can be directly electronic, the electronic realization of most devices or articles is contrary to the living habits, and the use of these devices represents having to accept new life styles.

Taking the existing electronic door lock as an example, as shown in fig. 1, the existing electronic door lock needs to use a battery as an energy source, otherwise the electronic card is inoperable. If the battery is not replaced in time, the door lock can not work normally. Further, the position where the battery is replaced is basically set on the indoor side, and is not replaceable from the outside. Special door opening unlocking is usually required at this time. Some mechanical locks and electronic locks are overlaid to prevent such embarrassment, but obviously are not convenient life style pursued by technical development.

On the one hand, batteries obviously have many disadvantages as energy sources. The battery remains on continuously after it is connected and does not perform adequately for unlocking such intermittent power applications. The battery that is switched on most of the time is not actually operating. But also needs attention in the aspects of environmental protection and recycling. On the other hand, besides the electronic card, there are fingerprint recognition, face recognition, network command and other collection and processing methods, and some methods also require relatively high voltage or relatively continuous power supply. It can be said that the more intelligent the way the more stable and high quality power supply is needed. However, under the circumstances that further development is needed in terms of battery materials, how to acquire the required energy and use the energy efficiently is also an important aspect.

The usage of the electronic door lock is different from the usage of the traditional door lock. Because it requires power to operate. Some designs attempt to convert mechanical energy into electrical energy, temporarily provide some energy source, knob-type french power drives, and the like. Yet another problem is that the user is unlikely to apply force continuously and will not be accepted by the market. However, simple user action does not produce enough power or voltage to drive an intelligent device.

In particular, in the face recognition method, it is certain that a screen is required to display an image effect to preliminarily verify whether the face of the user is photographed, thereby determining each element of the face. During normal use operation, the face of the user can be subjected to posture adjustment according to the screen image and the preliminary result, and when all elements of the face are collected, verification is just started. However, driving the screen requires sufficient power, and repeated multiple acquisitions and identifications also require continuous power. Therefore, the existing face recognition method cannot be used by a common electronic verification device. In addition to the greatest problem of power consumption, there is also a problem of an excessive number of verifications. By adopting the existing face recognition mode, the user not only needs to repeatedly adjust the posture according to the preliminary result, but also basically cannot continue to use the face recognition device once the verification fails too much. That is, the user and the identification device need to be repeatedly engaged with each other, and the authentication speed is not increased even if the use time is longer.

The existing face recognition device needs to be additionally connected with a power supply to drive a display and a camera. If the power is cut off, the display and the camera can not work, and the verification can not be carried out. Although some powered devices may generate power during use, the micro-generator does not continuously drive the display to operate. Instead, the intermittent power supply may damage the display and the verification may not be performed. It is also troublesome to separately energize camera and display, not only can not solve user cooperation problem, but also can promote installation cost. If the face verification algorithm is optimized, the research and development cost is also improved, and the face verification algorithm is certainly not accepted by the market.

Therefore, it is difficult to design the existing electronic verification, such as door lock, box lock, cabinet lock, etc., with high-level intelligence, and the stability and safety of power supply must be considered in a balanced manner.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main advantage lies in providing an electronic verification device, wherein need not to satisfy the electronization and gather the power supply demand by the self-contained energy, realizes intelligent collection and discernment, and then provides safe and convenient verification unblock.

Another advantage of the present invention is to provide an electronic verification device, wherein adopt face identification mode and avoid the high power consumption, convenience of customers face habitually cooperates the identification operation, along with the live time increases, the man-machine degree of adaptability can promote.

Another advantage of the utility model is that an electronic verification device is provided, wherein adopt face identification mode need not to gather user face repeatedly and carry out preliminary result judgement, probably realize accurately ground face and aim at, and then probably realize that the single is gathered and can be verified the effect.

Another advantage of the present invention is to provide an electronic verification apparatus, wherein under the condition that can not cause the damage to electronic device, the required energy consumption of face recognition mode is extremely low, and the required supply duration is also shorter.

Another advantage of the present invention is to provide an electronic verification device, wherein the electronic verification device is triggered and collects user data such as images in an electronic manner, and is suitable for locking and unlocking occasions.

Another advantage of the present invention is to provide an electronic verification device, wherein the unlocking action is utilized to provide necessary energy driving for the electronic device, so as to avoid the situation of power shortage and incapability of working, and the embarrassment of power shortage is not necessary to be solved through an additional mechanical structure.

Another advantage of the present invention is to provide an electronic verification device, wherein the unlocking action is utilized to trigger the verification process, so as to realize the intelligent verification method of face recognition and the like and make the corresponding work, for example, through the verification of the back unlocking and the like.

Another advantage of the present invention is to provide an electronic authentication apparatus, wherein the electric energy is generated by a simple action of a user without additionally increasing an operation step or an operation burden.

Another advantage of the present invention is to provide an electronic authentication device, wherein the data matched with the electronic authentication device is stored in advance to determine whether to unlock through authentication, and the electronic authentication device can also unlock through network authentication.

Another advantage of the present invention is to provide an electronic verification device, wherein the unlocking action at every turn is verified, thereby realizing the validity and safety of verification.

Another advantage of the present invention is to provide an electronic verification device, wherein the energy of the unlocking does not need to be additionally provided when the electronic verification device is unlocked.

Another advantage of the utility model is to provide an electronic verification device, wherein for the user provides face identification's basis of referring, before not opening the collection, the user can adjust face position by oneself and observe whether can be by accurate collection.

Another advantage of the present invention is to provide an electronic verification device, wherein the electronic verification device provides a starting means, extracts the energy basis for electronic collection from the user action, and provides energy storage for subsequent processing and unlocking.

Another advantage of the present invention is to provide an electronic authentication device, wherein the electronic authentication device provides a response component, based on the collection of the starting component and the corresponding operation after the processing result is verified, the result can be effectively executed after the guarantee is verified, and no additional user operation or energy supply is needed.

Another advantage of the present invention is to provide an electronic verification device, wherein the starting means can realize that image acquisition, fingerprint collection, radio frequency identification gather and so on different kinds of electronic data acquire, and then realize the electronization and verify.

Another advantage of the present invention is to provide an electronic authentication device, wherein the electronic authentication device further comprises a device housing, which effectively protects the actuating member and the response member from being damaged and disabling the authentication.

Another advantage of the present invention is to provide an electronic verification device, wherein the electronic verification device does not need extra circuits when being installed, reduces the change or damage to the installation environment, and is friendly and simple to the installation environment.

The other advantages and features of the invention will be fully apparent from the following detailed description and realized by means of the instruments and combinations particularly pointed out in the appended claims.

According to the utility model discloses an aspect can realize aforementioned purpose and other purposes and advantage the utility model discloses an electronic verification device to make corresponding operation according to user's relevant data, include:

a mirror for the user to align with the verification location;

a starting component for collecting the relevant data of the user after aligning the position in a power supply mode; and

a response component, which is driven by the starting component to execute the corresponding operation after the collection and the corresponding operation after the verification of the starting component, wherein the response component comprises an unlocking component, the unlocking component is controlled by the starting component to operate, wherein the starting component is cooperatively arranged on the mirror, the starting component is used for purposefully collecting the relevant data of the user and judging whether to output an unlocking instruction, and the response component executes the unlocking instruction after obtaining energy and the unlocking instruction from the starting component.

According to an embodiment of the present invention, the starting means comprises a power supply member, a collecting device and a control device, wherein the collecting device and the control device are respectively connected to the power supply member in an energizable manner, wherein the power supply member is operated to supply energy, so that the power supply member is operated to supply energy, the collecting device and the control device obtain electric energy to cooperatively verify the work.

According to the utility model discloses an embodiment, the starting member is rotated the back and is provided the electric energy and gather user's face data, and judge whether user's face data satisfies the unblock condition.

According to an embodiment of the present invention, the electronic authentication device further comprises a device housing, wherein the mirror is disposed on an outer surface of the device housing, and wherein the activating means collects data related to the user through the outer surface of the device housing.

According to the utility model discloses an embodiment, the starting member is operated and provides the electric energy and gather after triggering user's relevant data and judge whether output unlocking instruction.

According to an embodiment of the present invention, the energy supply member is at least selected from one of the combination of the power generation element and the battery element, wherein the collection device includes an image collector, wherein the image collector collects the data related to the user after the energy supply member obtains the energy.

According to an embodiment of the invention, the image collector is implemented as a camera, wherein the collection orientation of the camera partially overlaps with the mirror reflection direction.

According to an embodiment of the invention, the mirror is attached to a surface of the device housing in such a way that the orientation of the mirror coincides with the orientation of the camera.

According to an embodiment of the present invention, the control device is set up and control the response component by pre-programming, wherein if the data that the collection device obtained is verified by the control device and passes, then the control device controls the response component and unlocks, wherein if the data that the collection device obtained is verified by the control device and can not pass, then the control device handles the data of gathering and transmits to the outside.

According to an embodiment of the present invention, the response member includes a latch assembly, wherein the unlocking assembly is controlled by the control device to drive the latch assembly, wherein when the control device issues an unlocking command, the unlocking assembly is driven to release the position restriction of the latch assembly, and the latch assembly receives the energy of the energy supply member and is pushed back to the inside of the device housing.

According to an embodiment of the present invention, the power supply member includes a driving portion, a transmission portion, a power generation portion and a power storage portion, wherein the driving portion is drivingly connected to the transmission portion, and the power generation portion is connected to the transmission portion to obtain kinetic energy, wherein the power generation portion after obtaining kinetic energy further provides electric energy to the collection device and the control device, wherein the power storage portion is connected to the transmission portion and the response member between the unlocking components.

According to the utility model discloses an embodiment, transmission portion will the partial energy that drive division obtained reaches electricity generation portion, partial energy reaches power storage portion.

According to an embodiment of the present invention, the electronic verification device further comprises a sound box disposed in the device housing and connected to the control device, wherein the power generation unit further provides electric energy to the sound box after obtaining the kinetic energy.

According to an embodiment of the invention, the collecting device comprises a fingerprint collector, wherein the fingerprint collector follows the energy supply device obtains energy and works.

According to an embodiment of the present invention, the collection device includes a wireless signal collector, wherein the wireless signal collector is followed the energy supply device obtains the energy and works.

According to an embodiment of the present invention, the control device comprises a calculation processor and an output manager, wherein the calculation processor obtains the acquired data from the acquisition device, and then sends an execution instruction to the output manager according to the pre-programming of the calculation processor, wherein the output manager is connected to the unlocking assembly.

According to an embodiment of the invention, the control device comprises a calculation processor and an output manager, wherein the calculation processor obtains the acquired data from the acquisition device and then sends the execution instruction to the output manager according to a pre-programming of the calculation processor, wherein the output manager is connected to the sound.

According to another aspect of the present invention, the present invention further provides a verification method, according to the above-mentioned electronic verification apparatus, comprising:

I. after the user operates and triggers the energy supply piece, the electric energy converted by the energy supply piece is obtained, so that the acquisition device is started to acquire the electric energy;

II, according to the data acquired by the acquisition device, verifying whether an unlocking condition is met; and

if the unlocking condition is not met, outputting information which is not verified; and if the unlocking condition is met, giving an unlocking signal to the response component to unlock.

According to an embodiment of the present invention, step III further comprises the steps of: and III.1, if the unlocking condition is not met, sending a failure notice.

According to an embodiment of the present invention, step III further comprises the steps of:

if the unlocking condition is not met, sending a failure notice to the network from the local;

III.2, judging whether temporary authorization can be carried out according to the content of the failed notice; and

if yes, giving a locally verified instruction and waiting for reuse.

Further objects and advantages of the invention will be fully apparent from the ensuing description and drawings.

These and other objects, features and advantages of the present invention will become more fully apparent from the following detailed description, the accompanying drawings and the appended claims.

Drawings

Fig. 1 is a schematic view of an electronic door lock of the prior art.

Fig. 2 is an overall schematic view of an electronic authentication apparatus according to a preferred embodiment of the present invention.

Fig. 3 is a schematic cross-sectional view of an electronic proof device according to the preferred embodiment of the present invention.

Fig. 4 is a schematic block diagram of an electronic proof device according to the preferred embodiment of the present invention.

Fig. 5 is a schematic flow chart of the electronic authentication apparatus according to the preferred embodiment of the present invention.

Fig. 6 is a flow chart illustrating an authentication method of the electronic authentication apparatus according to the preferred embodiment of the present invention.

Fig. 7 is a flow chart illustrating an authentication method of the electronic authentication apparatus according to the preferred embodiment of the present invention.

Fig. 8 is a schematic application diagram of the electronic authentication apparatus according to the preferred embodiment of the present invention.

Fig. 9 is a schematic side cross-sectional view of an electronic proof device according to one possible approach of the preferred embodiment of the present invention.

Fig. 10 is a schematic side cross-sectional view of an electronic proof device according to one possible approach of the preferred embodiment of the present invention.

Fig. 11 is a schematic side cross-sectional view of an electronic proof device according to one possible approach of the preferred embodiment of the present invention.

Fig. 12 is a functional block diagram of an electronic proof device according to the preferred embodiment of the present invention.

Fig. 13A to 13D are schematic partial flow charts of the electronic authentication apparatus according to the preferred embodiment of the present invention.

Fig. 14 is a schematic partial cross-sectional view of an electronic proof device according to the preferred embodiment of the present invention.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention, as defined in the following description, may be applied to other embodiments, variations, modifications, equivalents and other technical solutions without departing from the spirit and scope of the invention.

It will be understood by those skilled in the art that in the present disclosure, the terms "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, as the terms are used in the description to indicate that the referenced device or element must have the specified orientation, be constructed and operated in the specified orientation, and not for the purpose of limitation.

It is understood that the terms "a" and "an" should be interpreted as meaning that a number of one element or element is one in one embodiment, while a number of other elements is one in another embodiment, and the terms "a" and "an" should not be interpreted as limiting the number.

The utility model provides an electronic verification device utilizes the unblock action to produce the electric energy and supply the use of electronic collection equipment to use intelligent verification mode under the passive condition. Further, the electronic authentication device is adapted to be installed at a position requiring locking and unlocking, for example, a door window, a cabinet, and the like. For convenience of explanation, the preferred embodiment is illustrated with a door lock, as shown in FIG. 2. That is, the electronic authentication device is implemented as a door lock to operate. And after the user is verified by the electronic verification device, the electronic verification device gives an unlocking action, so that the user can open the door lock. Preferably, the electronic verification device utilizes a biological identification mode for verification and has a high anti-prying function.

The electronic authentication device in the preferred embodiment, as shown in fig. 2 and 3, comprises a device housing 10, an actuating member 20 and a response member 30, wherein the actuating member 20 is mounted to the device housing 10, and wherein the locking member 30 is drivably disposed to the device housing 10 by the actuating member 20. The locking member 30 may extend out of the device housing 10 so that the device housing 10 may be locked by being fixed by the protruding locking member 30. It should be noted that after the actuating member 20 is operated by the user, the user needs to be identified, so as to drive the locking member 30 back to the inside of the device housing 10 to complete the unlocking. That is, the electronic authentication device does not require changing the usage habit of the user, and can complete the electronic authentication without the power supply and retract the response member 30 to unlock the electronic authentication device.

More preferably, the activation member 20 is rotatable relative to the device housing 10. By means of the rotational movement of the activation member 20, the activation member 20 gets energy and thus verifies whether it is unlocked. If the activation member 20 is verified, the response member 30 receives an unlock signal to retract. If the activation member 20 fails verification, although energized, the response member 30 does not receive a signal and remains protruding, and thus remains locked. Further, the device housing 10 has an electronics housing 13 and a lock housing 14, wherein the activation member 20 is partially secured relative to the electronics housing 13, and wherein the response member 30 is partially received in the lock housing 14. That is, individual contact with the electronics housing 13 does not activate the response member 30 located in the key cylinder housing 14, providing a physical basis for some tamper resistance. It should be noted that the device housing 10 has a plurality of fixing holes for positioning the activating member 20 and the responding member 30, but does not affect the protection of the maneuvering member 20 and the responding member 30.

In the preferred embodiment, the device housing 10 has an outer surface 11 and an inner surface 12, which are relatively in the outer and inner door positions, respectively. The activation member 20 partially protrudes from the outer surface 11 of the device housing 10 for the user to rotate the activation member 20. And the responsive member 30 is disposed within the device housing 10 and laterally projects between the outer surface 11 and the inner surface 12. The device case 10 and the activation member 20 are adaptively mounted according to the occasion where the electronic authentication device is mounted.

In particular, the activation means 20 comprises an energizing means 21, a harvesting means 22 and a control means 23, as shown in fig. 4, wherein the activation source 21 is operated to store energy, wherein the harvesting means 22 and the control means 23 are respectively galvanically connectable to the activation source 21 for the purpose of cooperatively performing a verification operation of the harvesting means 22 and the control means 23 after the activation source 21 has been operated. That is, the energy supply means 21 supplies the required electric energy to the collecting means 22 and the control means 23.

Preferably, in the preferred embodiment, the energy supplying member 21 is an electricity generating element. The energy supplied by the energy supply means 21 is harvested and used by the harvesting means 22 and the control means 23. Moreover, the control means 23 more preferably manages the use of electrical energy. It is worth mentioning that the energy supply unit 21 receives the one-time rotation energy of the user and converts the energy into electric energy. It will be appreciated by those skilled in the art that the electrical energy provided by the energy supply means 21 has a certain amount of limitation, but is sufficient for the harvesting means 22 and the control means 23 to be used. For example, in the preferred embodiment the capture device 22 includes an image capture device 221. The image collector 221 is embodied as a camera. In other words, the display electronics are not set as feedback required for image recognition. Therefore, the electric energy provided by the energy supply part 21 is enough to provide working energy for the image collector 221, so that the image collector 221 can collect the biological data of the human face towards the user after the energy supply part 21 is operated.

Preferably, in a further embodiment, the energy supply means 21 is a battery. After the energy supply device 21 is awakened by the operation of the user, the acquisition device 22 and the control device 23 obtain working energy. For example, the user presses a connection switch of the battery, so that the battery is accessed to supply power.

The control means 23 are pre-programmed to drive the response member 30. When the acquisition device 22 obtains the user authentication data, the control device 23 performs corresponding operations according to the preprogramming. If the data obtained by the acquisition means 22 is verified by the control means 23, the control means 23 drives the response member 30 to unlock. If the data obtained by the acquisition device 22 is verified by the control device 23 to fail, the control device 23 will process the acquired data and transmit it to the outside. For example, the control device 23 further drives a sound 40 to sound, so that the operating user knows that the unlocking is the result. For another example, the control device 23 further uploads the collected data to the cloud, so that the user obtains the information of the unlocking failure from the mobile portable device 90.

In addition, the response component 31 comprises an unlocking assembly 31 and a locking bolt assembly 32, wherein the unlocking assembly 31 is controlled by the control device 23 to drive the action of the locking bolt assembly 32. The energy of the energy supply member 21 can drive the unlocking assembly 31 to drive the latch bolt assembly 32. In the event that the control device 23 does not issue an unlock signal, the latch bolt assembly 32 will remain in a convex locked state. In the case that the control device 23 sends an unlocking signal, the unlocking assembly 31 is driven to unlock the position of the latch bolt assembly 32, and then the latch bolt assembly 32 can be retracted by receiving the energy of the energy supplying device 21. It is worth mentioning that the unlocking energy source of the latch bolt assembly 32 comes from the energy supplying member 21, not the unlocking assembly 31. The latch bolt assembly 32 is not easily unlocked but requires rotation of the energy supplying member 21 when the unlocking assembly 31 is broken. Of course, in a more preferred embodiment, when the unlocking assembly 31 is broken, the rotation of the energy supply member 21 is also broken, and the latch bolt assembly 32 cannot be unlocked.

Specifically, the work flow of the electronic authentication apparatus is as shown in fig. 5 and 6. The verification method of the electronic verification device comprises the following steps:

I. the user rotates the energy supply member 21, and the collecting device 22 obtains the electric energy converted by the energy supply member 21;

ii, according to the data acquired by the acquisition device 22, the user is verified whether the unlocking condition is satisfied; and

if the unlocking condition is not met, outputting information which is not verified; if the unlocking condition is satisfied, an unlocking signal is given to the response member 30 to unlock.

Specifically, first, the power supply member 21 is driven, that is, the user rotates the power supply member 21 so that kinetic energy is obtained. The collection device 22 obtains a source of operating energy to collect information about the user attempting to authenticate. The harvesting device 22 will not start to operate without the user turning the energy supply 21. It will be appreciated that the wake-up of the operation of the harvesting device 22 is the energy supply of the energy supply 21. Furthermore, the energy source of the energy supply device 21 not only supplies the collecting device 22, but also supplies the control device 23 with operating energy. According to a pre-programming, the control means 23 take the data acquired by the acquisition means 22 to authenticate the user. If the verification is not passed, the output is not passed. If the verification is passed, an unlocking signal is given to the response component 30, so that unlocking is realized after the verification is passed. Furthermore, the unlocking energy source required for the unlocking member 30 is also derived from the rotation of the energy supply member 21. For example, the control device 23 gives an electromagnet signal to release the restriction of the response member 30 after the authentication is passed.

Each time the energizing member 21 is driven to rotate through an angle of α, preferably α is 25 to 45, a single rotation of the energizing member 21 is further supplied to the collection means 22 and the control means 23, which need to use electric power this time.

More specifically, the power supplying member 21 includes a driving portion 211, a transmission portion 212, a power generating portion 213 and a power storing portion 214. The driving part 211 is drivingly connected to the transmission part 212, and the power generating part 213 is connected to the transmission part 212 to obtain kinetic energy. The power generation unit 213 that has obtained the kinetic energy further supplies electric energy to the collection device 22 and the control device 23. The power storing part 214 is connected between the transmission part 212 and the unlocking assembly 31 of the response member 30 to transmit kinetic energy from the driving part 211 to the latch bolt assembly 32 so that the latch bolt assembly 32 can be driven by a rotational energy source. That is, the power storing part 214 is prepared to provide the energy source for driving the latch bolt assembly 32 to unlock to the unlocking assembly 31 by the partial kinetic energy obtained from the transmission part 212. Of course, in the case where the user is authenticated, the power reservoir 214 does not energize the unlocking assembly 31 or the latch bolt assembly 32 of the responsive member 30. That is, breaking the unlocking assembly 31 alone does not provide energy to unlock the latch bolt assembly 32.

Further, in the preferred embodiment, the driving part 211 is implemented as a rotating handle, so that the rotational energy of the user is transmitted to the power generating part 213 by the transmission part 212, and the other part of the energy is transmitted to the power storing part 214 by the transmission part 212.

The verification method step III of the electronic verification device outputs the information that the verification fails if the unlocking condition is not satisfied, further comprising the steps of:

and III.1, if the unlocking condition is not met, sending a failure notice.

That is, in the case where the power supply unit 21 of the activating member 20 is driven to operate the collecting unit 22 but fails to be verified by the control unit 23, the control unit 23 can give a notification by a communication unit or a sound unit or the like.

For example, the user turns the driving portion 211, and the collecting device 23 obtains enough starting energy. But the user information does not correspond to the data preprogrammed by the control device 23, the control device 23 outputs to the audio unit 40. From the outward appearance, the user unblanks unsuccessfully, obtains certain audio warning.

More specifically, the work flow of the electronic authentication apparatus is as shown in fig. 7 and 8. Step III of the authentication method of the electronic authentication apparatus further comprises the steps of:

if the unlocking condition is not met, sending a failure notice to the network from the local;

III.2, judging whether temporary authorization can be carried out according to the content of the failed notice; and

if yes, giving a locally verified instruction and waiting for reuse.

In other words, for a temporary user who does not pass, the electronic authentication apparatus provides a notification of the failure to an authorized user through a network. If the authorized user agrees with the unlocking request of the temporary user, the local part is subjected to corresponding verification information. When the user drives the start-up building 20 again, the acquisition means 22 of the start-up building 20 will acquire again, and the control means 23 authenticates the user with the already enriched authorization information. It should be noted that in the preferred embodiment, the failed notification is the image identification information, and the authorized user also authorizes the image identification information, for example, grants the right to pass the authentication twice, so that the authentication can be passed after acquiring the consistent image identification information again. Of course, authorized users may make one, multiple, or even permanent pass authentication opportunities.

For example, the owner, as an authorized user, can obtain a non-passing notice through the network and give a verified instruction on his own. When the outsider turns the driving part 211 to activate the capturing device 22, the control device 23 verifies the captured image because the image information of the outsider is not stored locally, and the control device 23 notifies the owner through the network. It is worth mentioning that the owner can obtain the information that someone tries to unlock the lock, and can also obtain specific image information, which is beneficial to the targeted authorization of the owner. Moreover, the owner gives authorization to the local according to the specific image information, and the next unlocking can not be passed. And equivalently, more storage which can be authorized is added into the local data, and the verification is passed when the unlocking condition is met in the next unlocking. Therefore, after driving the energy supply member 21 again, the capturing device 22 is activated again to capture the image, and the control device 23 has been temporarily instructed to pass the corresponding image information. That is, each verification operation is from each rotation of the energy source, and the corresponding energy is enough to satisfy each acquisition and control process without additional energy source.

It should be noted that, in the preferred embodiment, the control device 23 can process the collected information as local information. In another possible solution, the control device 23 transmits the wirelessly collected information to a local gateway or a local router, reducing the energy consumption of the electronic authentication apparatus. Therefore, the local in the above method steps may refer to the electronic authentication apparatus itself, or may refer to the network environment where the electronic authentication apparatus is located, and no physical level limitation is given here. That is, the electronic verification device itself may communicate directly with the cloud network, or may communicate with the cloud through a secondary or tertiary gateway. The user's portable device 90 may further communicate with the cloud or gateway to complete the task of receiving notifications or granting authorization.

As shown in fig. 9, the outer surface 11 of the device housing 10 is further provided with a mirror 50, wherein the orientation of the mirror 50 is identical to the orientation of the image collector 221. That is, the user faces the mirror 50, that is, the image collector 221. The user can understand the range of the image collector 221 by observing the mirror 50 of the device housing 10. Preferably, the collection orientation of the image collector 221 partially overlaps with the reflection direction of the mirror 50. More, the image collector 221 is preset with optical parameters such as a viewing range and a focal length. As much as possible, the range of the image acquired by the image acquirer 221 is similar to the image reflected by the mirror 50. Therefore, the image collector 221 does not need to feed back the acquired image to the user, and the required energy consumption is saved.

Also, the mirror 50 intuitively reflects the face range of the user so that the user can adjust in accordance with the collection range of the image collector 221. Preferably, the mirror 50 has a number of markings to facilitate the user in locating a particular position of the face.

It is worth mentioning that the device housing 10 is pre-positioned such that the mirror 50 is fixed to reflect an image range similar to the image collector 221. The electronic placing cavity 13 of the device shell 10 is also correspondingly provided with the placing position of the image collector 221. That is, by the design of the device housing 10, the collection range of the image collector 221 is ensured to be similar to the reflection range of the mirror 50, the steps and processes in assembly and manufacture are simplified, and the adjustment cost after the image collector 221 and the mirror 50 are installed is reduced.

Preferably, the mirror 50 is implemented as a single-sided projection mirror, i.e. the image collector 221 can obtain user image data through the mirror 50, and the mirror 50 can also reflect the user image for reference. In this way, the user can directly know whether the image collector 221 has obtained the face data, and the energy supply is not required.

Therefore, the rotational energy of the energy supply device 21 can directly drive the image collector 221 and the control device 23 to consume energy, thereby realizing intelligent verification and unlocking.

More preferably, the user reflects the collection effect of the image collector 221 through the mirror 50 to determine in advance, and then rotates the energy supply member 21, so that the image collector 221 can directly obtain the required face data of the user, and the control device 23 realizes intelligent unlocking after verification. That is, the user can confirm the capturing effect of the image capturing device 221 by observing the reflection range of the mirror 50. In other words, the verification is performed by aligning the collecting device 22 and then rotating the energy supplying member 21. The user does not have to light the electronic authentication device first but rather authenticates similar to inserting a key first and then turning it. The electronic verification device is more in line with the unlocking habit of the user, does not need to access energy all the time, does not need to wait for awakening of the user all the time, and can ensure the full utilization of the energy and the effectiveness of intelligent verification.

More particularly, no power feedback image acquisition is required, either by authorized users or by temporary users. The specific identification and processing of the image acquisition information are handed to local for carrying out. The rotational energy obtained by the energy supply unit 21 is sufficient to drive the image capturing unit 221.

In addition, the acquisition means 22 further comprises a wireless signal acquisition means 223, the wireless signal acquisition means 223 being implemented as an RFID identification device. The wireless signal acquisition device 223 is disposed in the device housing 10 proximate the exterior surface 11. Similar to the operation of the image capturing device 222, when the energy supplying device 21 is driven, the wireless signal capturing device 223 obtains electric energy for identification.

The pickup device 22 further includes a fingerprint collector 222, and the fingerprint collector 222 is disposed on the driving portion 211 so that the fingerprint collector 222 can be directly aligned after the user rotates the device.

As shown in fig. 10 and 11, the type of the pickup device 22 is not limited. The acquisition mode of the combination form is not influenced. The image collector 221, the fingerprint collector 222 and the wireless signal collecting device 223 can cooperatively obtain data for further processing by the control device 23.

For example, the acquisition device 22 selects at least one of the following combinations: image sensor, RFID sensor, NFC sensor, proximity sensor, motion sensor, sound sensor, iris sensor, palm print sensor. Further, the acquisition device 22 may be connected to a wireless data exchanger to transmit the acquired data. That is, the acquisition device 22 verifies the corresponding operation in a manner selected from at least one of the following combinations: password verification, biological verification and cloud and mobile phone authorization verification.

As shown in fig. 12, the control device 23 includes a calculation processor 231 and an output manager 232, wherein the calculation processor 231 obtains the acquired data from the acquisition device 22, and then issues an execution instruction to the output manager 231 according to the preprogramming of the calculation processor 231. The output manager 232 is connected to peripheral loads, such as the audio 40 and the power store 214 or the unlocking member 31.

It is worth mentioning that the wake-up of the computing processor 231 is based on the power supply of the activation means 20. More, the control device 23 further comprises an energy storage manager 232, wherein the energy storage manager 232 is connected between the power generation part 213 and the calculation processor 231. After the kinetic energy of the driving part 211 is introduced into the power generating part 213 by the transmission part 212, the energy storage manager 232 guides the electric energy provided by the power generating part 213 to the calculating processor 231 and the collecting device 22 to wake up the calculating processor 231 and the collecting device 22. The energy storage manager 231 preferably provides a form of voltage suitable for the calculation processor 231 and the acquisition device 22. That is, the energy storage manager 231 is a rectifying circuit device, which assists in protecting the operational requirements of the computing processor 231 and the acquisition device 22.

More specifically, the control device 23 further includes a communication manager 234, and the communication manager 234 is communicably connected between the network and the calculation processor 231, so that the judgment result of the calculation processor 231 can be uploaded and the network instruction can be transmitted to the calculation processor 231. Further, after the portable device 90 accesses the network, the portable device 90 can communicate with the computing processor 231 of the control device 23.

Specifically, when the user rotates the driving portion 211, the transmission portion 212 transmits kinetic energy to the power generation portion 213, and the power generation portion 213 provides electric energy to start the collecting device 22. Meanwhile, the power storage part 214 obtains energy from the driving part 211 to wait for unlocking. After the electric energy provided by the power generation part 213 is processed by the energy storage manager 232 and adaptively converted, the calculation processor 231 and the collection device 22 are started. For example, the image acquirer 221 photographs user face information. The control means 23 verifies the acquired image. If the image information is not stored locally, the communication manager 234 of the control device 23 sends a notification to the portable device 90 via a network. Also, the output manager 233 transmits a ringing instruction to the sound 40 so that the user is notified of the failure. After the network transmits an authorization command to the communication manager 234, the controller 23 obtains a temporary command after the driver 211 is driven by the porcelain. The acquisition means 22 are activated again for acquisition and the control means 23 give a pass through of the corresponding image information. That is, each verification operation is performed by the driving part 211 to rotate the energy source, and the corresponding energy is enough to satisfy each acquisition and control process without additional energy source. The computing processor 231 issues an authorization instruction to the output manager 233 after verification. The unlocking assembly 31 obtains a verified instruction and then carries out unlocking operation on the bolt assembly 32.

More specifically, as shown in fig. 13A to 14, the unlocking assembly 31 includes an electromagnetic lever 311 and a thrust lever 312, wherein the electromagnetic lever 311 is controlled by the output manager 233 to be retractable on one side of the thrust lever 312, and wherein the thrust lever 312 is movably disposed on one side of the latch bolt assembly 32. The thrust rod 312 is connected to the power store 214 to be pushed by the power store 213 if verification passes. That is, in a state where the verification fails, the thrust rod 312 is blocked by the electromagnetic rod 311 and cannot move. Once the verification is passed, the electromagnetic lever 311 releases the thrust lever 311, so that the thrust lever 311 is moved by receiving the energy of the power storage 213.

The latch bolt assembly 32 includes a main body 321 and a reset member 322, wherein the main body 321 is telescopically disposed in the lock cylinder chamber of the device housing 10, and wherein the reset member 322 is disposed between the main body 321 and the device housing 10 and maintains a tendency to push the main body 321 outward.

The main body 321 has a protrusion 3211 at one side thereof, and a slope 3212 at an end thereof protruding from the device case 10. In a normal state, the main body 321 is pushed out by the reset member 322 to protrude from the device case 10 and be locked.

When the unlocking state is required, the electromagnetic rod 311 releases the blocking of the thrust rod 312, the thrust rod 312 is pushed by the force storage part 213, the protrusion 3211 of the main body 321 is pushed by the push rod 312, the main body 321 is retracted, and the reset piece 322 is compressed, so that the main body 321 temporarily releases the locking state. When the unlocking is completed, the reset piece 322 pushes the main body 321 back to the original position to keep the locking. It should be noted that after the main body 321 is extended and reset, the pushing rod 312 is blocked by the electromagnetic rod 311 again.

In the locked state, the positional relationship between the unlocking assembly 31 and the latch bolt assembly 32 is as shown in fig. 14. In the preferred embodiment, the force storage portion 214 and the return member 322 are each implemented as a spring to store energy and provide return energy. Specifically, in the locked state, the spring of the restoring member 322 pushes out the main body 321. Also, the spring of the force storage part 214 pulls the thrust rod 312 to be adjacent to the projection 3211 of the body 321, but the thrust rod 312 cannot push the projection 3211 to retract because the thrust rod 312 is blocked in the pushing direction by the electromagnetic rod 311. When the driving part 211 is rotated, the transmission part 212 converts the rotation into the pulling of the spring of the force storage part 214. The pulling of the spring of the force storage portion will pull the thrust rod 312 to push the main body 321 backwards, but the thrust rod 312 cannot move because of the blockage of the electromagnetic rod 311. Once the control means 23 has verified that the retraction of the electromagnetic rod 311 is performed, the thrust rod 312 will move unimpeded. Then, the thrust rod 312 is pulled rearward by the tensile force of the spring stored in the force storage part 214, and the projection 3211 of the main body 321 is pushed and retracted, thereby pressing the spring of the restoring member 322. After the driving part 211 is reset, the pulling force of the force storage part 214 to the thrust rod 312 is also lost, the main body 321 is not pushed, and the reset piece 322 pushes out the main body 321.

It is worth mentioning that the electric energy required by the electromagnetic rod 311 also comes from the energy supply member 21, because the electromagnetic rod 311 is released instantaneously, and the electric energy required is very small. And the instantaneous release, the thrust rod 312 can get out of the way. Although the electronic verification device is not supplied with battery energy, the electronic verification device can meet the requirement of electronic acquisition and power supply, realize intelligent acquisition and identification and further provide safe and convenient verification and unlocking.

It will be understood by those skilled in the art that the embodiments of the present invention as described above and shown in the drawings are given by way of example only and are not limiting of the present invention. The objects of the present invention have been fully and effectively accomplished. The functional and structural principles of the present invention have been shown and described in the embodiments without departing from the principles, embodiments of the present invention may have any deformation or modification.

Claims (22)

1. An electronic authentication device for performing corresponding operations according to related data of a user, comprising:

a starting member; and

a response component, which is driveably executed by the starting component to perform the corresponding operation acquired and verified by the starting component, wherein the response component comprises an unlocking component, the unlocking component is controlled by the starting component to perform the operation, the starting component acquires the relevant data of the user and judges whether to output the unlocking instruction, and the response component executes the unlocking instruction after acquiring the energy and the unlocking instruction from the starting component.

2. An electronic verification device as claimed in claim 1 wherein said activation means is electrically energizable to collect data relating to the user after alignment.

3. An electronic authentication device according to claim 1, wherein the activation means comprises an energizing means, a harvesting means and a control means, wherein the harvesting means and the control means are respectively electrically connectable to the energizing means, wherein the energizing means is operable to provide energy for the harvesting means and the control means to receive electrical energy for cooperatively performing the authentication operation after the energizing means is operated.

4. An electronic verification device as claimed in claim 3, wherein the activation member is rotated to provide electrical power to collect facial data of the user and determine whether the facial data of the user meets an unlock condition.

5. An electronic proof device according to claim 3, wherein the electronic proof device further comprises a mirror for a user to align with the proof position, wherein the actuating member is cooperatively disposed at the mirror.

6. An electronic authentication device according to claim 5, wherein the electronic authentication device further comprises a device housing, wherein the mirror is disposed on an outer surface of the device housing, wherein the activation member collects data relating to the user through the outer surface of the device housing.

7. An electronic authentication device according to claim 3, wherein the activation member is operated to provide power to collect data related to the user and determine whether to output an unlock instruction after being triggered.

8. An electronic authentication device according to claim 6, wherein the energy supply member is at least one selected from the group consisting of an electricity generating element and a battery element, and wherein the collecting means comprises an image collector, and wherein the image collector collects data related to the user after obtaining energy from the energy supply member.

9. An electronic proof device according to claim 8, wherein the image collector is implemented as a camera, wherein the collection orientation of the camera partially overlaps with the mirror reflection direction.

10. An electronic verification device as claimed in claim 9, wherein said mirror is affixed to a surface of said device housing in such a manner that the orientation of said mirror coincides with the orientation of said camera.

11. An electronic authentication apparatus according to claim 3, wherein the control means is pre-programmed to control the response means, wherein if the data obtained by the acquisition means is verified by the control means, the control means controls the response means to unlock, wherein if the data obtained by the acquisition means is not verified by the control means, the control means processes the acquired data to transmit to the outside.

12. An electronic authentication device according to claim 11, wherein the electronic authentication device further comprises a device housing, wherein the activation means collects data relating to the user through an outer surface of the device housing.

13. An electronic proof device according to claim 11, wherein the response member comprises a latch assembly, wherein the unlocking assembly is controlled by the control device to actuate the latch assembly, wherein in the case that the control device issues an unlocking command, the unlocking assembly is actuated to release the position restriction of the latch assembly, and the latch assembly receives the energy of the energy supply device and is pushed back to the inside of the device shell.

14. An electronic authentication device according to claim 3, wherein the power supply means comprises a driving portion, a transmission portion, a power generation portion and a power storage portion, wherein the driving portion is drivingly connected to the transmission portion, and the power generation portion is connected to the transmission portion to obtain kinetic energy, wherein the power generation portion after obtaining kinetic energy further supplies electric energy to the acquisition means and the control means, wherein the power storage portion is connected between the transmission portion and the unlocking member of the response member.

15. An electronic authentication device according to claim 14, wherein the transmission section transmits part of the energy obtained by the driving section to the power generation section, and part of the energy to the power storage section.

16. An electronic authentication device according to claim 14, wherein said electronic authentication device further comprises a sound, disposed in said device housing, and connected to said control means, wherein said power generation section, having obtained the kinetic energy, further supplies electric power to said sound.

17. An electronic verification device as claimed in claim 3 wherein said collection means includes a fingerprint collector, wherein said fingerprint collector is operable by receiving power from said power supply means.

18. An electronic verification device according to claim 3, wherein said acquisition means is selected from at least one of the following combinations: image sensor, RFID sensor, NFC sensor, proximity sensor, motion sensor, sound sensor, iris sensor, palm print sensor.

19. An electronic authentication device according to claim 2, wherein by the activation means, the authentication manner of the corresponding operation is selected from at least one of the following combinations: password verification, biological verification and cloud and mobile phone authorization verification.

20. An electronic verification device as claimed in claim 3, wherein said control means comprises a computing processor and an output manager, wherein said computing processor obtains the collected data from said collection means and issues execution instructions to said output manager in accordance with a pre-programming of said computing processor, wherein said output manager is connected to said unlocking assembly.

21. An electronic proof device according to claim 16, wherein the control means comprises a computing processor and an output manager, wherein the computing processor obtains the collected data from the collecting means and issues execution instructions to the output manager according to a pre-programming of the computing processor, wherein the output manager is connected to the sound.

22. An electronic authentication device according to any of claims 11-21, wherein the electronic authentication device further comprises a mirror for the user to align the authentication position.

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