CN218160163U - Vibration switch trigger device and electronic atomizer - Google Patents

Abstract

The application provides a vibration switch trigger device and electronic atomizer. The vibration switch trigger device comprises a vibration trigger piece and a vibration component; the vibration trigger is provided with a vibration trigger conductive area; the vibration component comprises a vibration impact conductive piece and a collision point moving piece, the vibration impact conductive piece is connected with the collision point moving piece, the vibration impact conductive piece is used for being in impact contact with the vibration trigger conductive area when in vibration unlocking, and the collision point moving piece is connected with the vibration trigger piece. The vibration switch triggering device comprises a vibration switch triggering device, a vibration striking conductive piece, a vibration triggering conductive area, a vibration striking mechanism and a vibration striking mechanism.

Description

Vibration switch trigger device and electronic atomizer

Technical Field

The utility model relates to an atomizer technical field especially relates to a vibration switch trigger device and electronic atomizer.

Background

Along with the rapid development of electronic atomizers, the sales volume of electronic atomizers in society is also increasing year by year. The electronic atomizer with good quality and brand is popular with consumers and occupies a large market share. In the actual use process, in order to prevent the use of others at will, locking is generally performed in a locking manner.

However, the traditional locking mechanism is basically a mechanical button, the difficulty of unlocking and locking is too low, the use safety is low, and the traditional locking mechanism is very easy to unlock and use by other people.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, provide a vibration switch trigger device and electronic atomizer that effectively improve safety in utilization.

The purpose of the utility model is realized through the following technical scheme:

a vibration switch triggering device comprising: the vibration trigger piece and the vibration component are arranged on the base; the vibration trigger part is provided with a vibration trigger conductive area which is used for being connected with a first detection end of the vibration detector; the vibration assembly comprises a vibration impact conductive piece and a collision point moving piece, the vibration impact conductive piece is connected with the collision point moving piece, the vibration impact conductive piece is used for being in impact contact with the vibration trigger conduction region when in vibration unlocking, the vibration impact conductive piece is also used for being connected with a second detection end of the vibration detector, the collision point moving piece is connected with the vibration trigger piece, and the collision point moving piece is used for moving the vibration impact conductive piece to correspond to the vibration trigger conduction region when in vibration unlocking.

In one embodiment, the vibration trigger component comprises a bearing part and a vibration trigger conducting part which are connected with each other, the bearing part is connected with the collision point moving part, the vibration trigger conducting part is used for being in vibration abutment with the vibration collision conducting part, and the vibration trigger conducting part is further used for being electrically connected with a vibration trigger input end of the vibration detector.

In one embodiment, the number of the vibration triggering conductive parts is multiple, the multiple vibration triggering conductive parts are sequentially distributed along the moving direction of the bump point moving member, and each vibration triggering conductive part is used for being electrically connected with one triggering input end of the vibration detector.

In one embodiment, the vibration trigger further comprises a plurality of vibration trigger insulating parts, and one vibration trigger insulating part is arranged between any two adjacent vibration trigger conductive parts.

In one embodiment, the resistances of any two adjacent vibration trigger conductive parts are different.

In one embodiment, the resistance value of each vibration triggering conductive part is gradually increased along the moving direction of the bump point moving part.

In one embodiment, the vibration trigger member has a vibration space, and the vibration impact conductive member is movably disposed in the vibration space.

In one embodiment, the impact point moving part is a vibrating spring, one end of the vibrating spring is connected with the vibrating impact conductive part, and the other end of the vibrating spring is connected with the vibrating trigger part.

In one embodiment, the vibration trigger component is provided with a displacement clamping hole, the impact point moving component is a vibration spring pin, the vibration spring pin and the vibration impact conductive component are arranged in the displacement clamping hole in a penetrating mode, and the vibration impact conductive component is moved to a position corresponding to the vibration trigger conductive area.

An electronic atomizer comprising the vibration switch triggering device according to any one of the above embodiments.

Compared with the prior art, the utility model discloses at least, following advantage has:

when the unlocking is carried out, the collision point moving piece of the vibration switch trigger device is rotated firstly, so that the collision point moving piece drives the vibration collision conductive piece to move, the vibration collision conductive piece is made to move to a position opposite to the vibration trigger conduction region, the vibration collision conductive piece is convenient to be right opposite to the vibration trigger conduction region, then the vibration collision vibration switch trigger device is swung, the vibration collision conductive piece is made to vibrate, the vibration trigger conduction region is made to collide the appointed position by the vibration collision conductive piece, an electric signal generated by the vibration collision between the vibration collision conductive piece and the vibration trigger conduction region is transmitted to the vibration detector, the unlocking is carried out according to the vibration collision condition, the random unlocking is avoided, the locking and cracking difficulty is effectively improved, and the use safety of the vibration switch trigger device is effectively improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic diagram of a vibration switch triggering device in one embodiment;

FIG. 2 isbase:Sub>A cross-sectional view of the vibration switch activation device of FIG. 1 taken along the direction A-A;

FIG. 3 is a schematic view of another embodiment of a vibration switch triggering device;

FIG. 4 is a cross-sectional view of the vibration switch triggering device shown in FIG. 3 taken along the direction B-B;

FIG. 5 is a schematic diagram of an electronic atomizer in accordance with one embodiment;

fig. 6 is a cross-sectional view of the electronic atomizer shown in fig. 4 taken along the direction C-C.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are illustrated in the accompanying drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

The utility model relates to a vibration switch trigger device. In one embodiment, the vibration switch triggering device comprises a vibration triggering piece and a vibration assembly. The vibration trigger part is provided with a vibration trigger conductive area which is used for being connected with a first detection end of the vibration detector. The vibration assembly comprises a vibration impact conductive piece and a collision point moving piece. The vibration impact conductive piece is connected with the impact point moving piece, the vibration impact conductive piece is used for being in impact contact with the vibration trigger conductive area when in vibration unlocking, and the vibration impact conductive piece is also used for being connected with a second detection end of the vibration detector. The collision point moving piece is connected with the vibration trigger piece and used for moving the vibration collision conductive piece to be corresponding to the vibration trigger conductive area when the vibration unlocking is carried out. When the unlocking is carried out, the collision point moving piece of the vibration switch trigger device is rotated firstly, so that the collision point moving piece drives the vibration collision conductive piece to move, the vibration collision conductive piece is made to move to a position opposite to the vibration trigger conduction region, the vibration collision conductive piece is convenient to be right opposite to the vibration trigger conduction region, then the vibration collision vibration switch trigger device is swung, the vibration collision conductive piece is made to vibrate, the vibration trigger conduction region is made to collide the appointed position by the vibration collision conductive piece, an electric signal generated by the vibration collision between the vibration collision conductive piece and the vibration trigger conduction region is transmitted to the vibration detector, the unlocking is carried out according to the vibration collision condition, the random unlocking is avoided, the locking and cracking difficulty is effectively improved, and the use safety of the vibration switch trigger device is effectively improved.

Please refer to fig. 1, which is a schematic structural diagram of a vibration switch triggering device according to an embodiment of the present invention.

The vibrating switch trigger device 10 of an embodiment includes a vibrating trigger 100 and a vibrating assembly 200. The vibration-inducing component 100 has a vibration-inducing conductive region 102, and the vibration-inducing conductive region 102 is configured to be connected to a first detection terminal of a vibration detector. Referring to fig. 2, the vibrating element 200 includes a vibrating impact conductor 210 and a moving impact point element 220. The vibration impact conductor 210 is connected to the hit point moving member 220, the vibration impact conductor 210 is configured to be in impact contact with the vibration trigger conductive area 102 when the vibration is unlocked, and the vibration impact conductor 210 is further configured to be connected to a second detection end of the vibration detector. The striker moving member 220 is connected to the vibration trigger member 100, and the striker moving member 220 is configured to move the vibration impact conductive member 210 to correspond to the vibration trigger conductive area 102 when the vibration is unlocked.

In this embodiment, during unlocking, the hitting point moving member 220 of the vibration switch triggering device is first rotated, so that the hitting point moving member 220 drives the vibration hitting conductive member 210 to move, so that the vibration hitting conductive member 210 moves to a position opposite to the vibration triggering conductive region 102, and the vibration hitting conductive member 210 is opposite to the vibration triggering conductive region 102, and then the vibration hitting conductive member 210 vibrates in the vibration switch triggering device, so that the vibration hitting conductive member 210 hits the vibration triggering conductive region 102 at a specified position, and an electrical signal generated by vibration hitting between the vibration hitting conductive member 210 and the vibration triggering conductive region 102 is transmitted to the vibration detector, so that unlocking can be performed according to the vibration hitting condition, random unlocking can be avoided, the difficulty in locking and cracking can be effectively improved, and the use safety of the vibration switch triggering device can be effectively improved. Wherein a vibration switch is formed between the vibration impact conductive member 210 and the vibration trigger conductive region 102 at the time of impact contact, that is, the electrical conduction between the vibration impact conductive member 210 and the vibration trigger conductive region 102 is used as a detection amount of the vibration switch, so that the vibration detector can form a desired unlock vibration switch code according to the electrical conduction detected by the detection end, for example, the number of electrical conduction times and the electrical conduction time interval between the vibration impact conductive member 210 and the vibration trigger conductive region 102 are used as unlock vibration switch codes.

In one embodiment, referring to fig. 2, the vibration trigger component 100 includes a receiving portion 110 and a vibration trigger conductive portion 120 connected to each other, the receiving portion 110 is connected to the bumping point moving component 220, the vibration trigger conductive portion 120 is configured to be in vibration contact with the vibration impact conductive component 210, and the vibration trigger conductive portion 120 is further configured to be electrically connected to a vibration trigger input end of the vibration detector. In this embodiment, the receiving portion 110 serves as an installation component of the ram moving member 220, that is, the ram moving member 220 is installed by using the receiving portion 110 as a base, so that the ram moving member 220 is conveniently installed. The vibration-triggered conductive part 120 is connected to the receiving part 110, and specifically, the vibration-triggered conductive part 120 is disposed at a predetermined position according to actual conditions. The vibration triggering conductive part 120 has a conductive performance, the impact point moving part 220 moves the vibration impact conductive part 210 to the vibration triggering conductive part 120 at a specified position, so that when the vibration switch triggering device is vibrated and unlocked, the vibration impact conductive part 210 is in contact with the vibration triggering conductive part 120 to realize the electrical conduction between the vibration impact conductive part 210 and the vibration triggering conductive part 120, and thus the impact frequency between the vibration impact conductive part 210 and the vibration triggering conductive part 120 is collected by the vibration detector, that is, the vibration impact frequency is calculated by the electrical conduction frequency between the vibration impact conductive part 210 and the vibration triggering conductive part 120, so that the vibration detector determines whether to unlock according to the vibration impact frequency.

Further, the number of the vibration triggering conductive parts 120 is multiple, the multiple vibration triggering conductive parts 120 are sequentially distributed along the moving direction of the hitting point moving member 220, and each vibration triggering conductive part 120 is used for being electrically connected with one triggering input end of the vibration detector. In this embodiment, the plurality of vibration trigger conductive parts 120 are disposed at intervals, and each of the vibration trigger conductive parts 120 is located at a different position, that is, the position of each vibration trigger conductive part 120 on the vibration switch trigger device is different, that is, the relative position between each vibration trigger conductive part 120 and the vibration impact conductive part 210 is different, so that a required vibration unlocking code is formed according to the impact condition between the vibration impact conductive part 210 and each vibration trigger conductive part 120. Moreover, the positions of the vibration trigger conductive parts 120 in the vibration switch trigger device are different, so that multiple combinations of the formed vibration unlocking codes are facilitated, that is, the vibration impact conductive parts 210 and the impact unlocking codes of different vibration trigger conductive parts 120 are combined to improve the unlocking difficulty of the vibration switch trigger device, so that the use safety of the vibration switch trigger device is further improved, and the situation that other people use the vibration switch trigger device randomly is further avoided.

Further, referring to fig. 2, the vibration trigger 100 further includes a plurality of vibration trigger insulating portions 130, and one vibration trigger insulating portion 130 is disposed between any two adjacent vibration trigger conductive portions 120. In this embodiment, the vibration trigger conductive part 120 is configured to be electrically conducted with the vibrating impacting conductive member 210, so as to convert the impacting state of the vibrating impacting conductive member 210 into an electrically conducting state and transmit the electrically conducting state to the vibration detector. Specifically, the vibration trigger conductive parts 120 and the vibration impact conductive parts 210 are made of conductive metals, so as to facilitate distinguishing the impact conditions of the vibration impact conductive parts 210, even if more accurate unlocking codes are formed, the vibration trigger insulating parts 130 are placed between two adjacent vibration trigger conductive parts 120, so that the vibration trigger conductive parts 120 are insulated from each other, so that the different impact conditions between the vibration trigger conductive parts 120 and the vibration impact conductive parts 210 can be collected respectively, thereby avoiding the problem that the vibration unlocking codes are too complicated due to the fact that the vibration trigger conductive parts 120 are connected in series with each other, and facilitating the decoding of the vibration unlocking codes by the vibration detector.

Still further, the resistance values of any two adjacent vibration trigger conductive parts 120 are not equal. In this embodiment, the vibration impact conductive member 210 is connected to a voltage output terminal of the vibration detector, so as to provide a reference voltage for the vibration impact conductive member 210, so as to generate a corresponding conduction voltage when the vibration impact conductive member 210 impacts different vibration trigger conductive portions 120. The resistance values of two adjacent vibration trigger conductive parts 120 are different, so that the impact of the vibration impact conductive part 210 is different from the conduction resistance formed between the vibration trigger conductive parts 120, and the conduction currents collected by the vibration trigger input ends of the vibration detector are different, so that the vibration detector determines the impact position of the vibration impact conductive part 210 according to the collected conduction currents, and the impact conditions generated on each vibration trigger conductive part 120 are collected respectively. In another embodiment, the resistance of each of the vibration triggering conductive parts 120 is gradually increased along the moving direction of the moving member 220. In this way, under the condition that the reference voltage is the same, the conduction current collected by the vibration detector is gradually reduced along the moving direction of the moving member 220, and the impact position where the vibration impacts the conductive member 210 is determined according to the magnitude of the conduction current. The number of times of the impact between the vibrating impact conductive member 210 and the vibrating trigger conductive member 120 may be determined according to the conduction time of the conduction current.

In one embodiment, referring to fig. 2, the vibration trigger 100 has a vibration space 104, and the vibration impact conductive member 210 is movably disposed in the vibration space 104. In this embodiment, the vibrating striking conductive element 210 moves in the vibrating space 104, and the vibrating space 104 is used as a moving space of the vibrating striking conductive element 210, that is, the vibrating space 104 is used as a telescopic displacement space of the vibrating striking conductive element 210, that is, the vibrating space 104 is used as a position adjusting space of the vibrating striking conductive element 210. The vibrating impacting conductive member 210 is driven by the impact point moving member 220 to move, so that the vibrating impacting conductive member 210 is adjusted in position in the vibrating space 104, so as to adjust the vibrating impacting conductive member 210 to be in impact contact with the vibration triggering conductive area 102 at a specified position. Thus, after the vibrating impacting conductive member 210 is moved to a designated position, the vibrating impacting conductive member 210 may rapidly and highly frequently impact the vibration trigger conductive area 102 during vibration to rapidly form a desired impact unlock code. In another embodiment, the vibration trigger is a housing structure, and the interior of the vibration trigger is a housing interior cavity.

In one embodiment, referring to fig. 2, the striking point moving member 220 is a vibrating spring, one end of the vibrating spring is connected to the vibrating striking conductive member 210, and the other end of the vibrating spring is connected to the vibrating triggering member 100. In this embodiment, the impact point moving member 220 is a vibration spring, and the position of the vibration impact conductive member 210 is changed by the impact point moving member 220 through the deformation amount of the spring, specifically, when the gravity direction of the vibration impact conductive member 210 and the expansion direction of the vibration spring are changed, the vibration spring pushes the vibration impact conductive member 210 to a specified position, so that the vibration impact conductive member 210 is convenient to impact with the corresponding vibration trigger conductive area 102, and thus the vibration switch trigger device generates a corresponding vibration unlocking code through vibration.

In another embodiment, when the vibration trigger conductive area 102 is close to the vibration spring, the vibration switch trigger device is placed vertically and vibrates, and the vibration spring is pressed by the gravity of the vibration impact conductive element 210, so that the vibration spring contracts, and the vibration impact conductive element 210 compresses the vibration spring, so that the vibration impact conductive element 210 is close to the vibration trigger conductive area 102; when the vibration trigger conductive area 102 is far away from the vibration spring, the vibration switch trigger device is placed vertically in the reverse direction and vibrates, and the vibration spring is stretched by the gravity of the vibration impact conductive piece 210, so that the vibration spring is stretched, and the vibration impact conductive piece 210 pulls the vibration spring, and the vibration impact conductive piece 210 is close to the vibration trigger conductive area 102; when the vibration striking conductive component 102 is located in the middle of the vibration switch triggering device, the vibration switch triggering device is horizontally placed and vibrates, the gravity of the vibration striking conductive component 210 is perpendicular to the elastic force of the vibration spring, and the vibration spring is not influenced by each other any more, so that the vibration spring is in a natural extension state, the vibration striking conductive component 210 is located in the middle of the vibration switch triggering device, and the vibration striking conductive component 210 is close to the vibration striking conductive component 102.

In one embodiment, the vibration trigger component is provided with a displacement clamping hole, the impact point moving component is a vibration spring pin, the vibration spring pin and the vibration impact conductive component are arranged in the displacement clamping hole in a penetrating mode, and the vibration impact conductive component is moved to a position corresponding to the vibration trigger conductive area. In this embodiment, the moving member of the hit point is disposed in the displacement clamping hole, the moving member of the hit point is a vibrating pogo pin, and the vibration of the vibrating conductive member striking the vibrating pogo pin is facilitated by the elasticity of the vibrating pogo pin. Through removing the vibration bullet needle, be convenient for adjust vibration striking electrically conductive stretch out and draw back in the position on the vibration trigger spare, thereby be convenient for with vibration striking electrically conductive piece adjustment is with vibration trigger conduction region corresponds.

It can be understood that, in the use process of the vibration switch trigger device, sometimes the unlocking suspension condition occurs, at this time, the vibration switch trigger device is idle, but at this time, the vibration switch trigger device is still in a real-time detection state, that is, the vibration switch trigger device is in a working state. However, when the vibration switch triggering device is in an operating state and is not subjected to vibration unlocking, for example, the vibration switch triggering device is limited to be flat, and the impact point moving member 220 is weakened in elasticity and the vibration impacts the conductive member 210 in gravity, the vibration impact conductive member 210 will be in contact with the vibration trigger conductive area 102 for a long time, which easily causes the continuous consumption of the electric energy of the battery for supplying power to the vibration switch triggering device, and finally affects the service life of the electronic atomizer.

In order to facilitate timely detection of the pause-limited unlocking state of the vibration switch trigger device, please refer to fig. 3 and 4, the vibration switch trigger device 10 further includes a temperature-sensitive detection assembly 300, the temperature-sensitive detection assembly 300 includes a temperature-sensitive element 310 and a sliding limiting member 320, the sliding limiting member 320 includes two sliding limiting rings 322 disposed in parallel and at an interval, the vibration trigger element 100 is disposed in the two sliding limiting rings 322, a sliding limiting space 302 is formed between the two sliding limiting rings 322, the temperature-sensitive element 310 is disposed between the vibration trigger element 100 and the two sliding limiting rings 322, a part of the temperature-sensitive element 310 is slidably disposed in the sliding limiting space 302, the temperature-sensitive element 310 is slidably disposed on the vibration trigger element 100, the temperature-sensitive element 310 is configured to sense the temperature of the vibration trigger conductive region 102, and the temperature-sensitive element 310 is further connected to a third detection end of the vibration detector, so as to transmit the temperature of the vibration trigger conductive region 102 to the vibration detector.

In this embodiment, the temperature sensing element 310 is slidably disposed on the surface of the vibration trigger 100, and the temperature sensing element 310 performs temperature sensing on the surface of the vibration trigger 100, so as to collect the surface temperature of the vibration trigger conductive area 102. When the vibration switch triggering device is in the pause limited unlocking state, the vibration impact conductive piece 210 is in contact with the vibration trigger conductive area 102 for a long time, so that the vibration trigger conductive area 102 continuously consumes electric energy, the temperature of the surface of the vibration trigger conductive area 102 continuously rises, and the temperature sensing piece 310 is convenient to collect the temperature change of the surface of the vibration trigger conductive area 102, so that whether the vibration impact conductive piece 210 is in contact with the vibration trigger conductive area 102 for a long time or not is convenient to determine, and further, the pause limited unlocking state of the vibration switch triggering device is convenient to determine, namely, whether the vibration switch triggering device excessively consumes the electric energy of the battery at the moment is determined. Thus, the vibration detector analyzes the temperature collected by the temperature sensing element 310, so that the suspension limiting unlocking state of the vibration switch trigger device can be detected in time, the power output of the battery to the vibration switch trigger device can be closed in time, and the power excessive consumption of the battery can be reduced. In another embodiment, in order to ensure that the temperature-sensing detecting assembly 300 slides stably on the vibration trigger 100, the number of the temperature-sensing elements 310 is multiple, and the temperature-sensing elements 310 are uniformly distributed in the sliding limiting space 302. In another embodiment, the temperature sensing element is a ball structure, so that the temperature sensing element slides more smoothly on the vibration trigger.

Further, when there are a plurality of vibration trigger conductive areas 102, in order to reduce the number of the temperature sensing elements 300, that is, to detect the temperature of each vibration trigger conductive area 102 through one temperature sensing element 300, referring to fig. 3, the temperature sensing element 300 further includes a plurality of sliding posts 330 connected to the sliding limiting ring 322, each sliding post 330 is located between the vibration trigger 100 and the sliding limiting ring 322, the vibration trigger 100 is provided with a plurality of sliding slots 106, and each sliding post 330 is slidably disposed in one sliding slot 106. In this embodiment, the sliding column 330 is used as a component for moving the sliding limiting ring 322 on the vibration trigger 100, and the sliding column 330 is convenient for the sliding column 330 to move on the vibration trigger 100 by means of the sliding slot 106, that is, the sliding slot 106 is used as a guide slot of the sliding column 330, so that the sliding limiting ring 322 moves relative to the vibration trigger 100, and the temperature-sensitive component 310 moves together with the vibration trigger 100. In this way, even if the vibration switch triggering device is limited to a tilted state, the temperature sensing element 310 may be tilted together, so that the temperature sensing element 310 moves to the vibration trigger conductive area 102 where the vibration impact conductive element 210 is tilted to contact, thereby facilitating temperature detection of the vibration trigger conductive area 102 where the vibration impact conductive element 210 contacts. In another embodiment, the sliding column 330 further separates the temperature-sensitive elements 310, so as to prevent the temperature-sensitive elements 310 from being too concentrated to cause the sliding stop collar 322 to tilt.

Further, please refer to fig. 3 and fig. 4 together, the vibration switch triggering device 10 further includes a limiting component 400, the limiting component 400 includes a limiting rod 410 and a push rod 420, the end of the vibration triggering component 100 is provided with a first through hole 108 and a second through hole 101 which are communicated with each other, the limiting rod 410 is disposed in the first through hole 108, the limiting rod 410 is used for corresponding to the sliding slot 106 to block the sliding column 330, the push rod 420 is disposed in the second through hole 101, the push rod 420 is slidably abutted to the limiting rod 410, and the push rod 420 is used for pushing the limiting rod 410 to correspond to the sliding slot 106. In this embodiment, the push rod 420 is used for pushing the limiting rod 410, so that a portion of the limiting rod 410 protrudes out of the first through hole 108, so that a portion of the limiting rod 410 corresponds to the sliding slot 106, and the sliding column 330 is blocked from sliding out of the sliding slot 106, thereby ensuring that the sliding column 330 slides stably in the sliding slot 106. When the temperature-sensing detection assembly 300 needs to be replaced or maintained, the push rod 420 is only required to be taken out of the second through hole 101, and the limiting rod 410 can be pushed back into the first through hole 108, so that the limiting rod 410 does not block the sliding column 330 any more, and the temperature-sensing detection assembly 300 can be conveniently taken down from the vibration trigger 100. In another embodiment, two ends of the vibration trigger 100 are respectively provided with one limiting component 400, so as to further ensure the sliding stability of the temperature-sensing detection component 300 on the vibration trigger 100. In yet another embodiment, the push rod member 420 has a push rod inclined surface, the push rod inclined surface is inclined towards a direction away from the limiting rod 410, and the push rod inclined surface is configured to slidably abut against the limiting rod 410 so as to rapidly push the limiting rod 410 out of the first through hole 108.

In one embodiment, the present application further provides an electronic atomizer, please refer to fig. 5 and fig. 6 together, in which the electronic atomizer 20 includes the vibration switch triggering device 10 according to any one of the embodiments. In this embodiment, the vibration switch triggering device comprises a vibration triggering piece and a vibration component. The vibration trigger part is provided with a vibration trigger conductive area which is used for being connected with a first detection end of the vibration detector. The vibration component comprises a vibration impact conductive piece and a collision point moving piece. The vibration impact conductive piece is connected with the impact point moving piece, the vibration impact conductive piece is used for being in impact contact with the vibration trigger conductive area when in vibration unlocking, and the vibration impact conductive piece is also used for being connected with a second detection end of the vibration detector. The collision point moving piece is connected with the vibration trigger piece and used for moving the vibration collision conductive piece to be corresponding to the vibration trigger conductive area when the vibration unlocking is carried out. When the unlocking is carried out, the collision point moving piece of the vibration switch trigger device is rotated firstly, so that the collision point moving piece drives the vibration collision conductive piece to move, the vibration collision conductive piece is made to move to a position opposite to the vibration trigger conduction region, the vibration collision conductive piece is convenient to be right opposite to the vibration trigger conduction region, then the vibration collision vibration switch trigger device is swung, the vibration collision conductive piece is made to vibrate, the vibration trigger conduction region is made to collide the appointed position by the vibration collision conductive piece, an electric signal generated by the vibration collision between the vibration collision conductive piece and the vibration trigger conduction region is transmitted to the vibration detector, the unlocking is carried out according to the vibration collision condition, the random unlocking is avoided, the locking and cracking difficulty is effectively improved, and the use safety of the vibration switch trigger device is effectively improved.

In another embodiment, the vibration switch triggering device is perpendicular to the whole electronic atomizer, that is, the distribution direction of the vibration triggering conductive parts is perpendicular to the battery rod body of the electronic atomizer.

The above-mentioned embodiments only represent several embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A vibration switch triggering device, comprising:

the vibration trigger part is provided with a vibration trigger conductive area which is used for being connected with a first detection end of the vibration detector;

the vibration assembly comprises a vibration impact conductive piece and a collision point moving piece, the vibration impact conductive piece is connected with the collision point moving piece, the vibration impact conductive piece is used for being in impact contact with the vibration trigger conduction region when in vibration unlocking, the vibration impact conductive piece is also used for being connected with a second detection end of the vibration detector, the collision point moving piece is connected with the vibration trigger piece, and the collision point moving piece is used for moving the vibration impact conductive piece to be corresponding to the vibration trigger conduction region when in vibration unlocking.

2. A vibration switch triggering device as claimed in claim 1, wherein said vibration triggering member comprises a receiving portion and a vibration triggering conductive portion connected with each other, said receiving portion is connected with said striking point moving member, said vibration triggering conductive portion is adapted to be in vibration abutment with said vibration striking conductive member, and said vibration triggering conductive portion is further adapted to be electrically connected with a vibration triggering input terminal of said vibration detector.

3. A vibration switch triggering device as claimed in claim 2, wherein said vibration triggering conductive portion is plural, and plural vibration triggering conductive portions are sequentially distributed along the moving direction of said movable member at the collision point, and each of said vibration triggering conductive portions is configured to be electrically connected to a triggering input end of said vibration detector.

4. A vibration-activated switch actuating apparatus as claimed in claim 3, wherein said vibration-activated member further includes a plurality of vibration-activated insulating portions, one of said vibration-activated insulating portions being disposed between any adjacent two of said vibration-activated conductive portions.

5. A vibro-switch trigger device according to claim 3 and wherein any two adjacent vibro-trigger conductive parts have unequal resistance values.

6. A vibration switch triggering device as claimed in claim 5, wherein the resistance of each of said vibration triggering conductive portions is gradually increased in a moving direction of said moving member at the hitting point.

7. A vibration switch triggering device as claimed in claim 1, wherein the vibration triggering member has a vibration space in which the vibration impact conductive member is movably disposed.

8. A vibration switch triggering device as in claim 1, wherein said impact point moving member is a vibration spring, one end of said vibration spring is connected to said vibration impact conducting member, and the other end of said vibration spring is connected to said vibration triggering member.

9. The vibration switch triggering device according to claim 1, wherein the vibration triggering member is provided with a displacement hole, the hitting point moving member is a vibration pogo pin, the vibration pogo pin and the vibration striking conductive member hit the conductive member, and the vibration pogo pin is inserted into the displacement hole to move the vibration striking conductive member to a position corresponding to the vibration triggering conductive region.

10. An electronic atomizer, comprising a vibration switch triggering device according to any one of claims 1 to 9.

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