CN210688082U - Improved simulated three-dimensional flame device - Google Patents

Abstract

The utility model provides an improved simulated three-dimensional flame device, which comprises a base, a fog generating mechanism arranged in the base, an outer cover connected with the base and a luminous mechanism; the inner cavity of the outer cover is a mist accumulation cavity, a mist outlet of the mist generating mechanism is communicated with the mist accumulation cavity, or a component for generating mist by the mist generating mechanism is arranged in the mist accumulation cavity; the top of the outer cover is provided with a flame spraying port, the light-emitting mechanism is arranged in the outer cover, the illumination direction of the light-emitting mechanism is opposite to the flame spraying port, light beams of the light-emitting mechanism are irradiated on fog sprayed from the flame spraying port, and light rays are refracted by the fog to form dynamic flame. The utility model discloses three-dimensional flame device of emulation shines on irregular spun fog through the light beam of light source, and light receives the fog refraction and produces dynamic flame to can image and present the effect that flame swayed among the combustion process lifelikely.

Description

Improved simulated three-dimensional flame device

Technical Field

The utility model relates to a simulated flame technical field, more specifically say, relate to a three-dimensional flame device of improved generation emulation.

Background

The candle or flame device is a decorative daily living article, and the traditional candle or flame device is mainly used for illumination and is realized by burning wax oil. However, burning causes the wick of the candle or flame device to become progressively shorter and thus exhausted. Simultaneously along with social development, the function of candle or flame device is not being confine to the illumination yet, has still played the effect of decorating and increasing the atmosphere, and at the birthday party, friend party's meal, when the lover appointment, some candles or with the flame device are clicked, its sudden and sudden candle light can add romantic atmosphere. However, after the traditional candle or flame device is ignited, smoke is generated, the environment is polluted, and open fire also has potential safety hazard. As a result, conventional candles or flame devices are increasingly being replaced by simulated candles or simulated flame devices. The artificial candle or artificial flame device can simulate the lighting effect of the candle by the light generated by the light source, and is widely used in places such as bars, coffee shops, dance halls and the like.

At present, a simulated candle or a simulated flame device usually utilizes a mode of projecting light to a flame sheet to simulate flame, the mode enables the viewing angle to be limited, and a flame sheet carrier with diffuse reflection can exist at the top of the electronic candle or the flame device, so that the simulation effect is not real, and the simulation degree is not high and the image is not vivid.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the shortcoming and not enough among the prior art, provide a three-dimensional flame device of improved generation emulation, this three-dimensional flame device of emulation shines on irregular spun fog through the light beam of light source, and light receives the three-dimensional flame of emulation that the fog refraction produced the developments to can image and present the effect that flame swayed among the combustion process lifelikely. Another object of the present invention is to provide a simulated three-dimensional flame device capable of solving the problem that the three-dimensional simulated flame is difficult to form due to the circulation generated by the jetted mist at the low position, thereby further improving the simulation degree.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: an improved generation emulation three-dimensional flame device which characterized in that: comprises a base, a fog generating mechanism arranged in the base, an outer cover connected with the base and a light-emitting mechanism; the inner cavity of the outer cover is a mist accumulation cavity, a mist outlet of the mist generating mechanism is communicated with the mist accumulation cavity, or a component for generating mist by the mist generating mechanism is arranged in the mist accumulation cavity; the top of the outer cover is provided with a flame spraying port, the light-emitting mechanism is arranged in the outer cover, and light beams of the light-emitting mechanism are irradiated out of the flame spraying port, so that the light beams of the light-emitting mechanism are irradiated on mist sprayed out of the flame spraying port, and light rays are refracted by the mist to form dynamic flame;

also includes a housing; the shell covers the outer cover; the top end opening of the shell is opposite to the flame spraying port, and an accommodating space communicated with the top end opening of the shell is arranged between the shell and the outer cover.

In the above technical scheme, the utility model discloses the fog that the fog produced the mechanism is gathered in long-pending fog intracavity to gush out from the flame jet at dustcoat top is irregular, and at this moment, luminous mechanism's light beam shines on the fog from flame jet spun, and light receives the fog refraction and forms dynamic emulation three-dimensional flame. The flame formed by the mode ensures that the viewing angle is not limited, and the simulation effect is real, vivid and lifelike, thereby vividly and vividly presenting the flame swaying effect in the combustion process.

The utility model also comprises a fog feeding anti-circulation mechanism which is used for rapidly raising the fog in the fog accumulation cavity to the flame spraying port and preventing the fog sprayed from the flame spraying port from generating circulation at a low position; the fog feeding circulation preventing mechanism is arranged in the accommodating space between the shell and the outer cover, and an air outlet of the fog feeding circulation preventing mechanism is communicated with the fog accumulating cavity and the accommodating space. The low position is 1-8cm away from the flame spraying opening.

The utility model discloses a send fog to prevent circulation mechanism has two effects:

the method has the following effects: when the fog-feeding circulation-preventing mechanism works, a part of wind is fed into the fog-accumulating cavity, fog is irregularly sprayed out of the flame-spraying port under the action of wind blowing, and the effect of flame swaying in the combustion process is presented under the illumination of the light-emitting mechanism. And the air output can be adjusted to adjust the rising speed of the fog or the component rising to the flame spraying opening, thereby playing the role of adjusting the size of the simulated three-dimensional flame.

The second action is as follows: the air outlet, the accommodating space and the top end opening of the shell of the fog-feeding anti-circulation mechanism are all in a communicated state, the fog-feeding anti-circulation mechanism feeds air into the accommodating space, and the air flow is blown out from the top end opening of the shell and then enters the accommodating space from the air inlet to form circulation, so that the blown air flow drives the fog sprayed from the flame spraying port to face upwards, the air flow flowing out from the top end opening of the shell surrounds the sprayed fog, the problem that the sprayed fog is easy to generate circulation at a low position (namely, a position 1-8cm away from the flame spraying port) to cause that simulated three-dimensional flame is difficult to form can be solved, and the flame simulation degree is high and the flame is more vivid.

Specifically, the fog feeding circulation preventing mechanism has two structural schemes:

the first structure scheme is as follows: the fog feeding circulation-preventing mechanism comprises a fan, an air inlet, an inner cavity air outlet communicated with the fog accumulation cavity and an air channel communicated with the accommodating space; the fan is arranged in the accommodating space between the shell and the outer cover, and the air outlet of the fan is respectively communicated with the air outlet of the inner cavity and the air duct; the air inlet is close to the fan and is formed in the shell wall.

The second structure scheme is as follows: the fog feeding circulation preventing mechanism comprises a fog feeding assembly and a circulation preventing assembly; the mist sending assembly comprises a first fan, an air inlet and an inner cavity air outlet communicated with the mist accumulation cavity; the first fan is arranged in the accommodating space, and an air outlet of the first fan is communicated with an air outlet of the inner cavity; the air inlet is close to the fan and is formed in the wall of the shell;

the circulation preventing assembly comprises a second fan arranged in the accommodating space; and the air outlet of the second fan faces upwards.

The fog generating mechanism comprises an atomizing sheet arranged in the fog accumulating cavity, a water absorbing rod and a water storage tank arranged at the bottom of the base; one end of the water absorption rod extends into the water storage tank, and the other end of the water absorption rod is connected with the atomizing sheet.

The light-emitting mechanism is a light source arranged at the side part of the flame spraying port, and when the device works, light beams of the side light source irradiate on mist sprayed from the flame spraying port.

The light source is more than two multicolor light sources and emits light in a color changing mode, and when the device works, the light sources emit color changing light beams to irradiate fog sprayed from the flame spraying port.

The light source is more than two light sources which emit light in a light and shade alternating mode, and when the device works, light beams with light and shade alternating are emitted by the light sources and irradiated on fog sprayed from the flame spraying port.

The utility model also comprises an electric control board provided with a power supply; the electric control board is respectively connected with the light-emitting mechanism and the mist generating mechanism.

The utility model also comprises a power socket and a key switch; the power socket and the key switch are respectively connected with the electric control board.

The utility model is characterized in that:

1. the utility model discloses fog produces the mode that the mechanism adopted the atomizing piece to pass through water absorption stick and storage water tank connection, not only can reach the effect that forms the fog, can simplify the device's inner structure and volume moreover.

2. The utility model discloses set up respectively with long-pending fog chamber and accommodation space intercommunication send fog to prevent circulation mechanism, can form the double air current: the fog is irregularly sprayed out of the flame spraying port by the airflow formed in the fog accumulating cavity, and the flame swaying effect in the combustion process is shown under the illumination of the light emitting mechanism; the airflow formed in the accommodating space is blown out from the top opening of the shell to surround the sprayed mist, so that the sprayed mist flame is not easily interfered and influenced by external airflow, the stability of the sprayed mist is improved, and the problem that the simulated three-dimensional flame is difficult to form due to the fact that the sprayed mist easily generates circulation at a low position (namely, a position 1-8cm away from a flame spraying port) can be effectively solved, so that the flame simulation degree is high, and the flame simulation is more vivid.

3. The utility model discloses set up the light source in flame jet lateral part to the outstanding flame jet fog of mode that directly shines forms the effect of flame. In addition, the light source is a multicolor light source and emits light in a color changing mode, so that the simulation degree and the three-dimensional degree of flame can be improved, and the image is more vivid. Or the light source emits light in an alternating light and shade mode, so that the light and shade projected on the fog are changed in an alternating light and shade mode, and the effect of shaking the flame is achieved.

Compared with the prior art, the utility model has the advantages of as follows and beneficial effect:

1. the utility model discloses three-dimensional flame device of emulation shines on irregular spun fog through the light beam of light source, and light receives the fog refraction and produces the three-dimensional flame of dynamic emulation to can vividly and vividly present the effect that flame swayed among the combustion process.

2. The utility model discloses three-dimensional flame device of emulation can solve spun fog and produce the circulation easily at the low level and lead to the three-dimensional flame of emulation to be difficult to the problem that takes shape to further improve the fidelity.

Drawings

FIG. 1 is a schematic view of a simulated three-dimensional flame device according to a first embodiment;

FIG. 2 is a schematic view of a simulated three-dimensional flame device according to a second embodiment;

wherein, 1 is a base, 2 is an outer cover, 3 is a mist accumulation cavity, 5 is a flame spraying port, 6 is flame, 7 is a water storage tank, 10 is an electric control board, 15 is an air duct, 16 is an air inlet, 17 is a light source, 19 is a microporous atomizing sheet, 20 is a water absorption rod, 22 is a shell, 23 is an opening at the top end, 24 is a containing space, 25 is a fan, 26 is an inner cavity air outlet, 27 is a power socket, 28 is a key switch, 29 is a first fan, and 30 is a second fan.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Example one

As shown in fig. 1, the improved simulated three-dimensional flame device of the present embodiment includes a base 1, a mist generating mechanism disposed in the base 1, an outer cover 2 connected to the base 1, and a light emitting mechanism, wherein an inner cavity of the outer cover 2 is a mist accumulating cavity 3, a component of the mist generating mechanism for generating mist is disposed in the mist accumulating cavity 3, a flame opening 5 is disposed on a top of the outer cover 2, the light emitting mechanism is a light source 17 disposed in the outer cover 2 and located on two sides of the flame opening 5, an illumination direction of the light source 17 is opposite to the flame opening 5, when the device is in operation, light beams of the light sources 17 on two sides are irradiated from the flame opening 5, so that the light beams of the light emitting mechanism are irradiated on the mist sprayed from the flame opening 5, and the light beams are refracted by the mist to form a dynamic flame 6.

The fog generating mechanism of this embodiment includes micropore atomizing piece 19, the stick 20 that absorbs water and the storage water tank 7 of setting in base 1 bottom that sets up in long-pending fog chamber 3, and wherein, the stick 20 one end that absorbs water stretches into storage water tank 7, and the other end is connected with micropore atomizing piece 19.

The utility model discloses still include shell 22, this shell 22 cladding dustcoat 2 and be connected with base 1, the open-top 23 of shell 22 is relative with flame projecting port 5, and be provided with between shell 22 and the dustcoat 2 with the accommodation space 24 of shell open-top 23 intercommunication. The utility model discloses still including being used for making long-pending fog chamber 3's fog rise fast to spout flame vent 5 and prevent to spout flame vent 5 spun fog at the low level and produce the circulation send fog to prevent the circulation mechanism, should send fog to prevent that circulation mechanism sets up the accommodation space 24 between shell 22 and dustcoat 2, send the air outlet and long-pending fog chamber 3 and the accommodation space 24 intercommunication of fog anti-circulation mechanism, wherein, the low level indicates apart from spouting flame vent 1-8cm department.

Specifically, the mist feeding circulation preventing mechanism comprises a fan 25, an air inlet 16, an inner cavity air outlet 26 communicated with the mist collecting cavity 3 and an air duct 15 communicated with the accommodating space 24, the fan 25 is arranged in the accommodating space 24 between the shell 22 and the outer cover 2, the air outlet is respectively communicated with the inner cavity air outlet 26 and the air duct 15, and the air inlet 16 is close to the fan 25 and is arranged on the wall of the shell 22.

The utility model discloses still including the automatically controlled board 10 that is provided with the power, this automatically controlled board 10 sets up in accommodation space 24 and is connected with luminous mechanism and fog production mechanism respectively. The present embodiment further includes a power socket 27 and a key switch 28, wherein the power socket 27 and the key switch 28 are both disposed in the housing 22 and are respectively connected to the electronic control board.

The utility model discloses the fog that fog production mechanism produced is gathered in long-pending fog chamber 3 to spout the 5 irregular blowout of flame vent from the 2 tops of dustcoat through fan 25 effect, at this moment, luminous mechanism's light beam shines on the fog from flame vent 5 spun, and light receives fog refraction and forms dynamic emulation three-dimensional flame 6. The simulated three-dimensional flame 6 formed in the mode ensures that the viewing angle is not limited, and the simulation effect is real, vivid and lifelike, so that the swaying effect of the flame 6 in the combustion process can be vividly and vividly presented.

In addition, the fan 25 sends a part of air into the accommodating space 24, blows out air flow from the top end opening 23 of the shell 22, and then enters the accommodating space 24 from the air inlet 16 to form circulation, so that the blown air flow drives the mist sprayed from the flame spraying port 5 to face upwards, the air flow flowing out from the top end opening 23 of the shell 22 surrounds the sprayed mist, the problem that the sprayed mist easily generates circulation at a low position (namely, a position 1-8cm away from the flame spraying port) to cause that simulated three-dimensional flame is difficult to form can be solved, and the flame simulation degree is high and vivid.

The working principle of the microporous atomizing sheet 19 in this embodiment is such that: the frequency and the working voltage of the micropore atomization sheet 19 are both relatively small, so that the micropore atomization sheet does not need to be placed in water for working, the atomization work is carried out through the middle micropore ejection, the water absorption rod 20 is fixed in the water storage tank 7, the middle aperture of the micropore atomization sheet 19 is fixed on the water absorption rod 20, water is absorbed through the water absorption rod 20 through the electrification of the micropore atomization sheet circuit of the electric control board 10, and the effect of fog is formed through the micropore atomization sheet 19.

The utility model discloses well micropore atomizing piece 19, automatically controlled board 10, supply socket 27 and key switch 28 are prior art, are the ripe product that can purchase on the current market.

Example two

The present embodiment is different from the first embodiment only in that: as shown in fig. 2, the mist feeding circulation-preventing mechanism includes a mist feeding assembly and a circulation-preventing assembly, wherein the mist feeding assembly includes a first fan 29, an air inlet 16, and an inner cavity air outlet 26 communicated with the mist collecting cavity 3, the first fan 29 is disposed in the accommodating space 24, the air outlet thereof is communicated with the inner cavity air outlet 26, and the air inlet 16 is close to the first fan 29 and opened on the wall of the housing 22. The circulation-preventing component comprises a second fan 30 arranged in the accommodating space 24, and an air outlet of the second fan 30 faces upwards.

The mist generated by the mist generating mechanism of the embodiment is accumulated in the mist accumulation cavity 3 and irregularly sprayed out from the flame spraying port 5 at the top of the outer cover 2 through the action of the first fan 29, at the moment, the light beam of the light emitting mechanism irradiates on the mist sprayed out from the flame spraying port 5, and the light is refracted by the mist to form dynamic simulated three-dimensional flame 6. The second fan 30 sends air into the accommodating space 24, blows air flow out of the top opening 23 of the shell 22, and then enters the accommodating space 24 from the air inlet 16 to form circulation, so that the blown air flow drives the mist sprayed out of the flame spraying port 5 to face upwards, the air flow flowing out of the top opening 23 of the shell 22 surrounds the sprayed mist, the problem that the sprayed mist easily generates circulation at a low position (namely 1-8cm away from the flame spraying port) to cause that simulated three-dimensional flame is difficult to form can be solved, and the flame simulation degree is high and is more vivid.

Other structures of the present embodiment are consistent with the present embodiment.

EXAMPLE III

The present embodiment is different from the first embodiment only in that: the light-emitting mechanism is three or more than three light sources arranged on the side part of the flame spraying port, the light sources are multicolor light sources and emit light in a color-changing mode, and when the device works, the light sources emit color-changing light beams to irradiate fog sprayed from the flame spraying port, so that the simulation degree and the three-dimensional degree of flame can be greatly improved, and the device is more vivid and lifelike.

Other structures of the present embodiment are consistent with the present embodiment.

Example four

The present embodiment is different from the first embodiment only in that: the light-emitting mechanism is three or more than three light sources arranged on the side part of the flame port, the light sources emit light in a light and shade alternating mode, and when the device works, light and shade alternating light beams emitted by the light sources are irradiated on fog sprayed by the flame port, so that light and shade on the fog are changed in a light and shade alternating mode, the effect of flame shaking is formed, the simulation degree and the three-dimensional degree of the flame can be greatly improved, and the device is more vivid.

Other structures of the present embodiment are consistent with the present embodiment.

EXAMPLE five

The present embodiment is different from the first embodiment only in that: the inner cavity of the outer cover is a mist accumulation cavity, a mist outlet of the mist generation mechanism is communicated with the mist accumulation cavity, mist in the mist accumulation cavity is irregularly sprayed out of the flame spraying port during working, and the effect of flame swaying in the combustion process is achieved under the illumination of the light source.

Other structures of the present embodiment are consistent with the present embodiment.

EXAMPLE six

The improved simulated three-dimensional flame device comprises a base, a mist generation mechanism arranged in the base, an outer cover connected with the base and a light-emitting mechanism, wherein the inner cavity of the outer cover is a mist accumulation cavity, a mist outlet of the mist generation mechanism is communicated with the mist accumulation cavity, or a component for generating mist by the mist generation mechanism is arranged in the mist accumulation cavity, a flame spraying port is arranged at the top of the outer cover, the light-emitting mechanism is arranged in the outer cover and irradiates out from the flame spraying port by light beams, the light beams of the light-emitting mechanism irradiate on the mist sprayed out from the flame spraying port, and the light beams are refracted by the mist to form dynamic flame.

The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited to the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be equivalent replacement modes, and all are included in the scope of the present invention.

Claims (10)

1. An improved generation emulation three-dimensional flame device which characterized in that: comprises a base, a fog generating mechanism arranged in the base, an outer cover connected with the base and a light-emitting mechanism; the inner cavity of the outer cover is a mist accumulation cavity, a mist outlet of the mist generating mechanism is communicated with the mist accumulation cavity, or a component for generating mist by the mist generating mechanism is arranged in the mist accumulation cavity; the top of the outer cover is provided with a flame spraying port, the light-emitting mechanism is arranged in the outer cover, and light beams of the light-emitting mechanism are irradiated out of the flame spraying port, so that the light beams of the light-emitting mechanism are irradiated on mist sprayed out of the flame spraying port, and light rays are refracted by the mist to form dynamic flame;

also includes a housing; the shell covers the outer cover; the top end opening of the shell is opposite to the flame spraying port, and an accommodating space communicated with the top end opening of the shell is arranged between the shell and the outer cover.

2. The improved simulated three-dimensional flame device of claim 1, wherein: the fog circulation preventing mechanism is used for enabling the fog in the fog accumulating cavity to quickly rise to the flame spraying port and preventing the fog sprayed from the flame spraying port from generating circulation at a low position; the fog feeding circulation preventing mechanism is arranged in the accommodating space between the shell and the outer cover, and an air outlet of the fog feeding circulation preventing mechanism is communicated with the fog accumulating cavity and the accommodating space.

3. The improved simulated three-dimensional flame device of claim 2, wherein: the fog feeding circulation-preventing mechanism comprises a fan, an air inlet, an inner cavity air outlet communicated with the fog accumulation cavity and an air channel communicated with the accommodating space; the fan is arranged in the accommodating space between the shell and the outer cover, and the air outlet of the fan is respectively communicated with the air outlet of the inner cavity and the air duct; the air inlet is close to the fan and is formed in the shell wall.

4. The improved simulated three-dimensional flame device of claim 2, wherein: the fog feeding circulation preventing mechanism comprises a fog feeding assembly and a circulation preventing assembly; the mist sending assembly comprises a first fan, an air inlet and an inner cavity air outlet communicated with the mist accumulation cavity; the first fan is arranged in the accommodating space, and an air outlet of the first fan is communicated with an air outlet of the inner cavity; the air inlet is close to the fan and is formed in the wall of the shell;

the circulation preventing assembly comprises a second fan arranged in the accommodating space; and the air outlet of the second fan faces upwards.

5. The improved simulated three-dimensional flame device of claim 1, wherein: the fog generating mechanism comprises an atomizing sheet arranged in the fog accumulating cavity, a water absorbing rod and a water storage tank arranged at the bottom of the base; one end of the water absorption rod extends into the water storage tank, and the other end of the water absorption rod is connected with the atomizing sheet.

6. The improved simulated three-dimensional flame device of claim 1, wherein: the light-emitting mechanism is a light source arranged at the side part of the flame spraying port, and when the device works, light beams of the side light source irradiate on mist sprayed from the flame spraying port.

7. The improved simulated three-dimensional flame device of claim 6, wherein: the light source is more than two multicolor light sources and emits light in a color changing mode, and when the device works, the light sources emit color changing light beams to irradiate fog sprayed from the flame spraying port.

8. The improved simulated three-dimensional flame device of claim 6, wherein: the light source is more than two light sources which emit light in a light and shade alternating mode, and when the device works, light beams with light and shade alternating are emitted by the light sources and irradiated on fog sprayed from the flame spraying port.

9. The improved simulated three-dimensional flame device of claim 1, wherein: the electric control board is provided with a power supply; the electric control board is respectively connected with the light-emitting mechanism and the mist generating mechanism.

10. The improved simulated three-dimensional flame device of claim 9, wherein: the device also comprises a power socket and a key switch; the power socket and the key switch are respectively connected with the electric control board.

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