CN115059896B - Simulated flame device - Google Patents

Abstract

The invention provides a simulated flame device, which comprises a shell, a fog generating module, a light-emitting mechanism and an airflow regulating mechanism, wherein the shell is provided with a plurality of luminous holes; the top of the shell is provided with a flame spraying port, and the inner cavity of the shell is used as a water storage cavity and a mist accumulation cavity; the air flow regulating mechanism is arranged in the inner cavity; the mist generating module is arranged in the inner cavity and communicated with the water storage cavity, the mist generating module stretches out of the water surface of the water storage cavity, and mist generated by the mist generating module is regulated by the airflow regulating mechanism and then sprayed out of the flame spraying port; the light-emitting mechanism is arranged on the airflow regulating mechanism, and irradiates light beams on mist sprayed by the flame spraying port, and the light beams are refracted by the mist to form dynamic flame. The simulated flame device has a simple and concise internal structure, is convenient to clean, can improve the use convenience, and can reduce the production cost.

Description

Simulated flame device

Technical Field

The invention relates to the technical field of simulated flames, in particular to a simulated flame device.

Background

Candles are an article of daily use, traditional candles are used for illumination and are realized by burning wax oil, and the burning can lead the candles to be gradually shortened to be used up; with the development of society, the function of the candle is not limited to illumination, and the candle also plays roles of decoration and atmosphere increasing. However, the burning type candle is not only cumbersome to operate, but also has a great potential safety hazard. Some simulated candles are now used to simulate real candles, avoiding safety hazards, such as by means of electronic lighting, to illuminate a flame-like object to simulate a flame. But the sense of realism is not high and needs to be improved.

In the present stage, some simulated flame devices with smoke effect also appear, and the simulated flame devices irradiate the mist generated after the liquid is atomized through a light-emitting mechanism to form simulated flames. However, the existing simulated flame device is additionally provided with a mist accumulation cavity, and in addition, an additional space is required to be provided with a mist outlet mechanism communicated with the mist accumulation cavity, so that the internal structure of the simulated flame device is complex, the use is inconvenient, and the application range and the application occasion of the simulated flame device are greatly limited. Therefore, how to simplify the internal structure of the simulated flame device is an important research direction for the simulated flame technology.

Disclosure of Invention

The invention aims to overcome the defects and shortcomings in the prior art and provide the simulated flame device, which has a simple and concise internal structure, is convenient to clean, can improve the use convenience and can reduce the production cost.

In order to achieve the above purpose, the invention is realized by the following technical scheme: a simulated flame device, characterized by: comprises a shell, a fog generating module, a light-emitting mechanism and an airflow regulating mechanism; the top of the shell is provided with a flame spraying port, and the inner cavity of the shell is used as a water storage cavity and a mist accumulation cavity; the air flow regulating mechanism is arranged in the inner cavity; the mist generating module is arranged in the inner cavity and is communicated with the water storage cavity, the mist generating module stretches out of the water surface of the water storage cavity, and mist generated by the mist generating module is regulated by the airflow regulating mechanism and then is sprayed out of the flame spraying port; the light-emitting mechanism irradiates light beams on mist sprayed by the flame spraying opening, and the light beams are refracted by the mist to form dynamic flame.

In the scheme, the inner cavity of the shell is used as the water storage cavity and the mist accumulation cavity simultaneously, so that a physical separation structure is reduced, the internal structure of the simulated flame device can be greatly simplified, namely, the space above the water surface of the water storage cavity can be used as the mist accumulation cavity, the working power can be reduced, and the interior of the simulated flame device is concise, so that the interior of the simulated flame device is convenient to clean, the use convenience can be improved, and the production cost can be reduced.

The light-emitting mechanism is arranged on the airflow adjusting mechanism. The luminous mechanism is directly arranged on the airflow regulating mechanism, an additional supporting piece is not needed for installing the luminous mechanism, the internal structure of the simulated flame device is further simplified, the water storage space of the water storage cavity is large, and therefore the water storage capacity is increased.

The air flow regulating mechanism is a support bracket, and the support bracket comprises a support seat and a support piece for supporting the light-emitting mechanism; the supporting seat is arranged in the inner cavity and is connected with the bearing piece; the support seat is of a hollow structure and is used as an air duct, and air flow flowing out of the air duct is blown out through the bearing piece;

the bearing piece comprises a pipeline and a mounting piece for bearing the light-emitting mechanism; the pipeline is communicated with the air duct and is provided with an air outlet, and the mounting piece is connected with the pipeline and is provided with a wind shield; the wind shield is arranged opposite to the air outlet. The wind shield can block the air flow flowing out from the air outlet so as to change the direction of the air flow and blow out or adjust the air flow.

The support bracket of the invention is used as a bracket body for installing the light-emitting mechanism and also used as an air duct, and can greatly simplify the internal structure of the simulated three-dimensional flame device. In addition, the support piece can adjust the air flow flowing out of the air duct, so that the air flow flowing out of the air duct is adjusted and blown out, the blown air flow can squeeze mist generated by the mist generating module to the spraying port to be sprayed out, the light emitting mechanism irradiates light beams on the mist sprayed out of the spraying port, and light rays are refracted by the mist to form dynamic flame.

The mist generating module comprises a base, a water absorbing rod and a microporous atomization sheet; the base is arranged in the inner cavity and provided with a water absorption groove, and the water absorption rod is arranged in the base and is communicated with the water storage cavity through the water absorption groove; the micropore atomization sheet is arranged in the base and connected with the water absorption rod, and is communicated with the inner cavity; the water absorbing rod arranged in the base can be communicated with the water storage cavity through the water absorbing groove, the design is simple and ingenious, and the internal structure of the simulated flame device can be further simplified.

Or the mist generating module comprises a substrate, a water absorbing rod and a microporous atomization sheet; the micropore atomization sheet is arranged on the substrate and is communicated with the inner cavity; the water absorbing rod is connected with the microporous atomization sheet and is suspended in the inner cavity. This hanging arrangement also saves installation space.

The shell, the inner cavity, the base and the airflow adjusting mechanism are of an integrated structure;

or the shell, the inner cavity, the base plate and the air flow regulating mechanism are of an integrated structure. The design can improve the overall structural strength and save the production cost.

The simulated flame device also comprises a surface cover which is covered on the shell, and the flame spraying port is arranged on the surface cover; the mist generating module is arranged in a staggered manner with the flame spraying opening.

The face lid is provided with tapering or radian, spouts the flame port and sets up in the lowest position of face lid, spouts the flame port and regard as the operating element that draws the face lid.

In the working process of the simulated flame device, the mist of the spray opening is covered on the surface to easily form water drops, the water drops formed by the mist can be effectively prevented from directly dripping to the mist generating module by the staggered arrangement of the mist generating module and the spray opening, the damage to the mist generating module can be reduced, and the service life of the mist generating module is greatly prolonged. In addition, the surface cover is provided with taper or radian, so that water drops formed by mist can be further located at the lowest position. In the use process, a user can add water, pour water or clean the inside by operating the extraction face cover, so that the use is convenient.

The simulated flame device also comprises a bottom cover connected with the shell; the bottom cover is provided with an air inlet, the bottom of the air flow regulating mechanism is provided with an air supply device, and air flow entering from the air inlet enters the air flow regulating mechanism through the air supply device.

The simulated flame device also comprises a battery, a main control board and a liquid level sensor; the battery is respectively connected with the fog generating module, the light emitting mechanism and the liquid level sensor through the main control board; a containing cavity is arranged between the bottom cover and the inner cavity, and the battery and the main control board are arranged in the containing cavity; the liquid level sensor is arranged between the accommodating cavity and the inner cavity and extends into the inner cavity. The design of installing the electric device in the accommodating cavity can enable the electric device to be separated from the water storage cavity and the mist accumulation cavity, so that the use safety is improved. The liquid level sensor can detect the liquid position in the inner cavity, and can warn if the liquid level is too low.

The bottom of the bottom cover is provided with a groove; the groove is provided with an external plug wire slot, a step structure is arranged in the groove, and an interface is arranged on one side of the step structure, opposite to the plug wire slot. The interface can be a charging structure or a power supply interface, and the power line passes through the plug wire slot and can be directly electrically connected with the interface.

Compared with the prior art, the invention has the following advantages and beneficial effects: the simulated flame device has a simple and concise internal structure, is convenient to clean, can improve the use convenience, and can reduce the production cost.

Drawings

FIG. 1 is a schematic diagram of a simulated flame apparatus of the present invention;

FIG. 2 is a schematic diagram of a simulated flame device of the present invention;

FIG. 3 is a schematic illustration of the interior of the simulated flame apparatus of the present invention;

FIG. 4 is a second schematic view of the interior of the simulated flame device of the present invention;

FIG. 5 is a third schematic view of the interior of the simulated flame device of the present invention;

FIG. 6 is a schematic view of a support in a simulated flame device of the present invention;

FIG. 7 is a schematic view of a support member according to a second embodiment;

FIG. 8 is an internal schematic view of a simulated flame device in accordance with a third embodiment;

FIG. 9 is a second schematic view of the interior of the simulated flame device of the third embodiment;

FIG. 10 is an internal schematic view of a simulated flame device in embodiment five;

wherein 1 is a shell, 2 is a luminous mechanism, 3 is a flame spraying port, 4 is an inner cavity, 4.1 is a water storage cavity, 4.2 is a mist accumulation cavity, 5 is a supporting seat, 6 is an air duct, 7 is a pipeline, 8 is an air outlet, 9 is a platform, 10 is a sleeve, 11 is a wind shield, 12 is a base, 12.1 is a seat body, 12.2 is a cover body, 13 is a water absorbing rod, 14 is a micropore atomization sheet, 15 is a water absorbing groove, 16 is a surface cover, 17 is a bottom cover, 18 is an air inlet, 19 is a fan, 20 is a battery, 21 is a main control board, 22 is a liquid level sensor, 23 is a containing cavity, 24 is a groove, 25 is a slot, 26 is a step structure, 27 is an interface, 28 is a base plate, 29 is a mist outlet sleeve, 30 is an airflow adjusting mechanism, and 31 is a mist outlet generating module.

Detailed Description

The invention is described in further detail below with reference to the drawings and the detailed description.

Example 1

As shown in fig. 1 to 6, the simulated flame device of the invention comprises a shell 1, a mist generating module, a light emitting mechanism 2 and an airflow adjusting mechanism, wherein a flame spraying opening 3 is arranged at the top of the shell 1, an inner cavity 4 of the shell 1 is used as a water storage cavity 4.1 and a mist accumulating cavity 4.2, the airflow adjusting mechanism is arranged in the inner cavity 4, the mist generating module is arranged in the inner cavity 4 and is communicated with the water storage cavity 4.1, the mist generating module extends out of the water surface of the water storage cavity 4.1, and mist generated by the mist generating module is sprayed out from the flame spraying opening 3 after being adjusted by the airflow adjusting mechanism. The light-emitting mechanism 2 is arranged on the airflow adjusting mechanism, and irradiates light beams on mist sprayed by the flame spraying ports 3, and the light beams are refracted by the mist to form dynamic flames.

The air flow regulating mechanism is a support bracket, and the support bracket comprises a support seat 5 and a bearing piece for bearing the light-emitting mechanism 2, wherein the support seat 5 is arranged in the inner cavity 4 and is connected with the bearing piece, the support seat 5 is of a hollow structure and is used as an air duct 6, and air flow flowing out of the air duct 6 is blown downwards through the bearing piece.

Specifically speaking, the bearing piece includes pipeline 7 and the installed part that is used for bearing luminous mechanism 2, pipeline 7 and wind channel 6 intercommunication are provided with air outlet 8, the installed part includes platform 9 and the sleeve 10 of being connected with platform 9, platform 9 is connected with pipeline 7 and is provided with windshield 11, luminous mechanism 2 sets up inside sleeve 10, this sleeve 10 can shelter from luminous mechanism 2's light for luminous mechanism 2's light beam concentrates on spouting the fog of flame opening 3 blowout. In this embodiment, the number of the wind shielding sheets 11 is equal to the number of the air outlets 8, and the wind shielding sheets 11 are disposed opposite to the air outlets 4. In addition, the wind shielding plate 11 is arranged along the edge of the platform 9, and the body diameter of the mounting piece is larger than the pipe diameter of the pipeline 7, so that a flowing space for air flow is formed between the wind shielding plate 11 and the air outlet 8.

The mist generating module of this embodiment includes a base 12, a water absorbing rod 13 and a microporous atomization sheet 14, wherein the base 12 includes a base 12.1 and a cover 12.2, the base 12.1 is disposed in the inner cavity 4 and is provided with a water absorbing groove 15, the water absorbing rod 13 is disposed in the base 12.1 and is communicated with the water storage cavity 4.1 through the water absorbing groove 15, and the cover 12.2 covers the microporous atomization sheet 14 in the base 12.1 and is connected with the water absorbing rod 13, and the microporous atomization sheet 14 is communicated with the inner cavity 4. The water absorbing rod 13 arranged in the base 12 can be communicated with the water storage cavity 4.1 through the water absorbing groove 15, so that the design is simple and ingenious, and the internal structure of the simulated flame device can be further simplified. In order to improve the structural strength, the shell 1, the inner cavity 4, the base 12 and the supporting seat 5 of the air flow regulating mechanism are integrally formed.

The simulated flame device also comprises a surface cover 16 which is arranged on the shell 1 in a covering way, the flame spraying opening 3 is arranged on the surface cover 16, and the mist generating module and the flame spraying opening 3 are arranged in a staggered way. In addition, the surface cover 16 is provided with taper or radian, the flame spraying port 3 is arranged at the lowest position of the surface cover 16, and the flame spraying port 3 is used as an operating member for extracting the surface cover 16. In the working process of the simulated flame device, the mist of the spraying flame port 3 on the face cover 16 easily forms water drops, the phenomenon that the water drops formed by the mist are directly dropped to the mist generating module can be effectively avoided due to the fact that the mist generating module and the spraying flame port 3 are arranged in a staggered mode, damage to the mist generating module can be reduced, and the service life of the mist generating module is greatly prolonged. In addition, the surface cover 16 is provided with taper or radian, so that the water drops formed by mist can be further located at the lowest position. In use, a user can add water, pour water or clean the interior by manipulating the extraction face cover 16, thereby facilitating use.

The simulated flame device also comprises a bottom cover 17 connected with the shell 1, wherein the bottom cover 17 is provided with an air inlet 18, the bottom of the supporting seat 5 of the air flow regulating mechanism is provided with a fan 19 communicated with the air inlet 18, and air flow entering from the air inlet 18 enters the air duct 6 through the fan 19.

The simulated flame device also comprises a battery 20, a main control board 21 and a liquid level sensor 22, wherein the battery 20 is respectively connected with the mist generating module, the light emitting mechanism 2 and the liquid level sensor 22 through the main control board 21, a containing cavity 23 is arranged between the bottom cover 17 and the inner cavity 4, the battery 20 and the main control board 21 are both arranged in the containing cavity 23, and the liquid level sensor 22 is arranged between the containing cavity 23 and the inner cavity 4 and stretches into the inner cavity 4. The design of mounting the electrical device in the receiving chamber 23 allows the electrical device to be separated from the water storage chamber 4.1 and the mist accumulation chamber 4.2 to improve the safety of use. The simulated flame device can be provided with an indicator lamp or a buzzer, when the liquid level sensor 22 can detect the position of the liquid in the inner cavity 4, the simulated flame device can warn through the indicator lamp or the buzzer if the liquid level is too low. In order to prevent the simulated flame device from affecting normal use in the charging process, a groove 24 is formed in the bottom of the bottom cover 17, a slot 25 is formed in the groove 24 and is communicated with the outside, a step structure 26 is formed in the groove 24, an interface 27 for charging is formed on one side of the step structure 26 opposite to the slot 25, and the interface 27 is connected with the battery 20. When charging, the power line passes through the wiring groove 25 and can be directly and electrically connected with the interface 27, and the design can enable the simulated flame device to be charged without affecting the flat-laying stability of the simulated flame device.

The working process of the simulated flame device comprises the following steps: the micropore atomizing sheet 4 in the mist generating module generates mist on the water surface of the water storage cavity 4.1, the air flow entering the accommodating cavity 23 from the air inlet 18 arranged on the bottom cover 17 is sent into the air duct 6 through the fan 19, the wind shielding sheet 11 of the bearing piece can adjust the air flow flowing out of the air duct 6, the air flow flowing out of the air duct 6 is blown downwards, the mist generated by the mist generating module can be extruded to the flame spraying opening 3 to be sprayed out by the air flow blown downwards, the light emitting mechanism 2 irradiates the light beam on the mist sprayed out by the flame spraying opening 3, and the light is refracted by the mist to form dynamic flame.

The principle of operation of the microporous atomizer plate 14 in this embodiment is as follows: because the frequency and the working voltage of the microporous atomizing sheet 14 are relatively small, the microporous atomizing sheet does not need to be put into water for working, the microporous atomizing sheet is sprayed out through the micropores in the middle, the water is sucked up through the water suction rod 13 by electrifying the circuit of the microporous atomizing sheet, and the mist is formed through the microporous atomizing sheet 14. The microporous atomizer sheet 14 of the present invention is a prior art, commercially available mature product.

The fog generating modules of the simulation flame device are all arranged in water, and the atomization sheet can generate oscillation energy through the driving voltage applied to the atomization sheet. The oscillation energy propagates in water along the direction perpendicular to the surface of the atomizing sheet, under the condition of proper water depth, the water surface on the energy propagation axis is concentrated to rise to one water column, and a large amount of tiny tension waves are concentrated at the front end of the water column, so that the surface tension of the rising water surface is greatly reduced, the water surface is divided into a plurality of tiny areas by the wavelength of the surface tension waves, and each area is formed as independent particles as if not bonded with each other, and the effect of forming fog in the air is diffused. However, the existing mist generating module is arranged in water to generate mist, a high-power supply is required to drive the structure, and the working voltage is high, so that the existing simulated flame device can only be connected with the mains supply by adopting a power line, and cannot adopt a battery, so that the device cannot be used at will, and the application range is limited.

The invention adopts the structure that the mist generating module extends out of the water surface of the water storage cavity 4.1, the circuit of the microporous atomizing sheet 14 is electrified to suck water through the water absorbing rod 13, and the atomizing sheet is not required to generate oscillation energy due to the structure of the microporous atomizing sheet 14, and the frequency and the working voltage of the atomizing sheet are relatively small, so that the power supply device of the simulated flame device can adopt a battery, is convenient to use, can be moved and used at will, and expands the application range of the device.

Example two

The present embodiment differs from the first embodiment only in that: as shown in fig. 7, the wind shielding plate 11 is disposed along the edge of the platform 9, and the wind shielding plate 11 is integrally formed and surrounds the outside of the air outlet 8.

Other structures of this embodiment are identical to those of the embodiment.

Example III

The present embodiment differs from the first embodiment only in that: as shown in fig. 8 and 9, the mist generating module is suspended inside the cavity. The mist generating module comprises a substrate 28, a water absorbing rod 13, a microporous atomizing sheet 14 and a mist generating sleeve 29, wherein the microporous atomizing sheet 14 is arranged on the substrate 28 and is communicated with an inner cavity 4, the water absorbing rod 13 is connected with the microporous atomizing sheet 14 and is suspended in the inner cavity 4, the mist generating sleeve 29 is sleeved with the water absorbing rod 13 and fixes the microporous atomizing sheet 14 on the substrate 28, a water absorbing groove (not shown) is formed in the side part of the mist generating sleeve 29, and water absorbing holes (not shown) are formed in the bottom of the mist generating sleeve 29, so that the water absorbing rod 13 can absorb water through the water absorbing groove and/or the water absorbing holes.

Other structures of this embodiment are identical to those of the embodiment.

Example IV

The present embodiment differs from the third embodiment only in that: the mist generating module of the embodiment comprises a mist generating cover, the mist generating cover penetrates through the water absorbing rod to fix the microporous atomization sheet on the substrate, and the water absorbing rod is directly contacted with water in the cavity to realize water absorption.

Other structures of this embodiment are the same as those of the third embodiment.

Example five

The present embodiment differs from the first embodiment only in that: as shown in fig. 10, the light emitting mechanism 2 of the present embodiment is not provided on the airflow adjusting mechanism 30. The simulated flame device of the embodiment comprises a shell 1, a mist generating module, a light emitting mechanism 2 and an airflow adjusting mechanism 30, wherein a flame spraying opening 3 is formed in the top of the shell 1, an inner cavity 4 of the shell 1 is used as a water storage cavity 4.1 and a mist accumulating cavity 4.2, the airflow adjusting mechanism 30 is arranged in the inner cavity 4, the mist generating module is arranged in the inner cavity 4 and is communicated with the water storage cavity 4.1, the mist generating module extends out of the water surface of the water storage cavity 4.1, and mist generated by the mist generating module is sprayed out of the flame spraying opening 3 after being adjusted by the airflow adjusting mechanism. The light emitting mechanism 2 irradiates the light beam on the mist sprayed from the flame spraying port 3, and the light beam is refracted by the mist to form dynamic flame.

Other structures of this embodiment are identical to those of the embodiment.

Example six

The present embodiment differs from the first embodiment only in that: the wind shield in the embodiment relatively shields the lower part of the air outlet, so that the air flow flowing out of the air duct is blown upwards; or when the wind shield is relatively shielded above the middle part or below the middle part of the air outlet, the air flow flowing out of the air duct is blown out horizontally. The direction of the air flow out of the air duct is adjusted according to the position of the mist generating mechanism, the position of the air duct and the like.

Other structures of this embodiment are identical to those of the embodiment.

The above examples are preferred embodiments of the present invention, but the embodiments of the present invention are not limited to the above examples, and any other changes, modifications, substitutions, combinations, and simplifications that do not depart from the spirit and principle of the present invention should be made in the equivalent manner, and the embodiments are included in the protection scope of the present invention.

Claims (7)

1. A simulated flame device, characterized by: comprises a shell, a fog generating module, a light-emitting mechanism and an airflow regulating mechanism; the top of the shell is provided with a flame spraying port, and the inner cavity of the shell is used as a water storage cavity and a mist accumulation cavity; the air flow regulating mechanism is arranged in the inner cavity; the mist generating module is arranged in the inner cavity and is communicated with the water storage cavity, the mist generating module stretches out of the water surface of the water storage cavity, and mist generated by the mist generating module is regulated by the airflow regulating mechanism and then is sprayed out of the flame spraying port; the luminous mechanism irradiates light beams on mist sprayed by the flame spraying port, and the light beams are refracted by the mist to form dynamic flame;

the light-emitting mechanism is arranged on the airflow adjusting mechanism;

the air flow regulating mechanism is a support bracket, and the support bracket comprises a support seat and a support piece for supporting the light-emitting mechanism; the supporting seat is arranged in the inner cavity and is connected with the bearing piece; the support seat is of a hollow structure and is used as an air duct, and air flow flowing out of the air duct is blown out through the bearing piece;

the bearing piece comprises a pipeline and a mounting piece for bearing the light-emitting mechanism; the pipeline is communicated with the air duct and is provided with an air outlet, and the mounting piece is connected with the pipeline and is provided with a wind shield; the wind shield is arranged opposite to the air outlet;

the mist generating module comprises a base, a water absorbing rod and a microporous atomization sheet; the base is arranged in the inner cavity and provided with a water absorption groove, and the water absorption rod is arranged in the base and is communicated with the water storage cavity through the water absorption groove; the micropore atomization sheet is arranged in the base and connected with the water absorption rod, and is communicated with the inner cavity;

or the mist generating module comprises a substrate, a water absorbing rod and a microporous atomization sheet; the micropore atomization sheet is arranged on the substrate and is communicated with the inner cavity; the water absorbing rod is connected with the microporous atomization sheet and is suspended in the inner cavity.

2. A simulated flame device as claimed in claim 1, wherein: the shell, the inner cavity, the base and the airflow adjusting mechanism are of an integrated structure;

or the shell, the inner cavity, the base plate and the air flow regulating mechanism are of an integrated structure.

3. A simulated flame device as claimed in claim 1, wherein: the simulated flame device also comprises a surface cover which is covered on the shell, and the flame spraying port is arranged on the surface cover; the mist generating module is arranged in a staggered manner with the flame spraying opening.

4. A simulated flame device as claimed in claim 3 wherein: the face lid is provided with tapering or radian, spouts the flame port and sets up in the lowest position of face lid, spouts the flame port and regard as the operating element that draws the face lid.

5. A simulated flame device as claimed in claim 1, wherein: the simulated flame device also comprises a bottom cover connected with the shell; the bottom cover is provided with an air inlet, the bottom of the air flow regulating mechanism is provided with an air supply device, and air flow entering from the air inlet enters the air flow regulating mechanism through the air supply device.

6. A simulated flame device as claimed in claim 5, wherein: the simulated flame device also comprises a battery, a main control board and a liquid level sensor; the battery is respectively connected with the fog generating module, the light emitting mechanism and the liquid level sensor through the main control board; a containing cavity is arranged between the bottom cover and the inner cavity, and the battery and the main control board are arranged in the containing cavity; the liquid level sensor is arranged between the accommodating cavity and the inner cavity and extends into the inner cavity.

7. A simulated flame device as claimed in claim 5, wherein: the bottom of the bottom cover is provided with a groove; the groove is provided with an external plug wire slot, a step structure is arranged in the groove, and an interface is arranged on one side of the step structure, opposite to the plug wire slot.