CN220169541U - Steam atomization 3D flame simulation electric fireplace - Google Patents

Abstract

The utility model provides a steam atomization 3D flame simulation electric fireplace, which comprises a machine shell, wherein a simulated fuel bed is arranged in the machine shell, and the steam simulation electric fireplace is characterized in that a steam discharging device is arranged below the simulated fuel bed in the machine shell and is used for discharging steam upwards to form a steam discharging area above the steam discharging device, a first light source used for irradiating the steam discharging area is arranged in the machine shell, and the steam discharging device comprises a water storage tank used for storing liquid and a heating mechanism used for heating the liquid to form steam. In the utility model, the electric fireplace adopts a mode of directly heating liquid to generate steam to form an atomization effect so as to form a 3D flame effect in a matching way, and compared with the ultrasonic atomization technology, the electric fireplace has low cost and effectively improves the market competitiveness of products.

Description

Steam atomization 3D flame simulation electric fireplace

[ field of technology ]

The utility model relates to the technical field of electric fireplaces, in particular to a steam atomization 3D flame simulation electric fireplace.

[ background Art ]

An atomization device is adopted in the existing electric fireplace, liquid is converted into mist and is sent to the upper portion of a simulated fuel bed, then the liquid is irradiated through a light source, and a purpose-made flame shape forming structure is matched, so that a vivid 3D flame effect can be achieved in a shell of the electric fireplace. Some existing electric fireplaces use ultrasonic atomization devices to atomize liquid, but the cost of the electric fireplace is high due to the adoption of the ultrasonic atomization devices.

[ utility model ]

In order to reduce the cost of the electric fireplace, the utility model provides a steam atomization 3D flame simulation electric fireplace.

The utility model is realized by the following technical scheme:

the utility model provides a steam atomizing 3D flame emulation electricity fireplace, includes the casing, be equipped with the simulated fuel bed in the casing, its characterized in that, be equipped with steam discharging device in the casing in the simulated fuel bed below, steam discharging device is used for upwards discharging steam in order to form the steam discharge area above the steam discharging device, be equipped with in the casing and be used for shining the first light source in the steam discharge area, steam discharging device includes the storage water tank that is used for storing liquid and is used for heating the liquid and forms vapor heating mechanism.

The steam atomization 3D flame simulation electric fireplace is characterized in that the water storage cavity is arranged in the water storage tank, the heating mechanism comprises a heating chamber, a heating component for heating the heating chamber and a partition board for separating the heating chamber and the water storage cavity, and a communicating part for communicating the water storage cavity with the heating chamber is arranged on the partition board.

The steam atomization 3D flame simulation electric fireplace is characterized in that the partition plate comprises a first enclosing plate and a second enclosing plate, the first enclosing plate is arranged outside the heating chamber, a water inlet channel is formed between the first enclosing plate and the second enclosing plate, and the communicating part comprises a first communicating hole and a second communicating hole, the first communicating hole is arranged on the first enclosing plate and used for communicating the heating chamber with the water inlet channel, and the second communicating hole is arranged on the second enclosing plate and used for communicating the water storage cavity with the water inlet channel.

The steam atomization 3D flame simulation electric fireplace is characterized in that the first communication hole is formed in one side of the first coaming, and the second communication hole is formed in one side, far away from the first communication hole, of the second coaming.

The steam atomization 3D flame simulating electric fireplace is characterized in that the steam discharging device comprises a steam discharging part for discharging steam upwards, and the steam discharging part is arranged in an extending mode along the length direction of the simulated fuel bed.

The steam atomization 3D flame simulation electric fireplace is characterized in that the steam discharge device comprises a steam guide mechanism used for communicating the heating chamber and the steam discharge part.

The steam atomization 3D flame simulation electric fireplace is characterized in that the steam guide mechanism comprises a guide substrate, and the guide substrate is provided with a sleeved side plate, a steam through hole and a guide side plate, the sleeved side plate is sleeved on the outer side of the first coaming, the steam through hole is used for communicating the heating chamber and the steam discharge part, and the guide side plate is used for guiding steam to the steam discharge part.

The steam atomization 3D flame simulation electric fireplace is characterized in that the shell is provided with the drawer frame detachably connected with the shell, and the steam discharge device and the first light source are arranged on the drawer frame.

The steam atomization 3D flame simulation electric fireplace is characterized in that the steam discharging device further comprises a water supplementing device communicated with the water storage cavity.

The steam atomization 3D flame simulation electric fireplace is characterized in that a second light source is further arranged in the shell, the second light source is arranged below the simulated fuel bed and used for radiating upwards on the simulated fuel bed, and a hot air outlet device is arranged on the upper portion of the shell.

Compared with the prior art, the utility model has the following advantages:

1. in the utility model, the electric fireplace adopts a mode of directly heating liquid to generate steam to form an atomization effect so as to form a 3D flame effect in a matching way, and compared with the ultrasonic atomization technology, the electric fireplace has low cost and effectively improves the market competitiveness of products.

2. In the utility model, the heating chamber and the water storage cavity are separated by the partition plate, and the heating chamber and the water storage cavity are communicated only through the communicating part on the partition plate, so that the heat of the liquid in the heating chamber can be effectively reduced to be transferred into the liquid in the water storage cavity when the heating mechanism heats the liquid in the heating chamber, and the liquid in the heating chamber can be quickly heated and boiled to form steam. Therefore, the scheme of the utility model can adopt a heating steam technology to replace an ultrasonic atomization technology to reduce the cost of the electric fireplace, and can also quickly generate steam so that the electric fireplace can be used for forming a 3D flame effect.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are required to be used in the description of the embodiments will be briefly described below.

FIG. 1 is a perspective view of a steam atomized 3D flame simulating electric fireplace of the present utility model;

FIG. 2 is a front view of a steam atomized 3D flame simulating electric fireplace of the present utility model;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is a schematic view showing a structure in which the steam discharging device of the present utility model is installed in a drawer frame;

fig. 5 is an exploded schematic view of the steam discharging device of the present utility model.

[ detailed description ] of the utility model

In order to make the technical problems, technical schemes and beneficial effects solved by the utility model more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

When embodiments of the present utility model refer to the ordinal terms "first," "second," etc., it is to be understood that they are merely used for distinguishing between them unless the order of their presentation is indeed dependent on the context.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Examples: the steam atomization 3D flame simulation electric fireplace as shown in fig. 1 to 5 comprises a shell 1, wherein a simulated fuel bed 2 is arranged in the shell 1, a steam discharging device 3 is arranged below the simulated fuel bed 2 in the shell 1, the steam discharging device 3 is used for discharging steam upwards to form a steam discharging area above the steam discharging device 3, a first light source 4 used for irradiating the steam discharging area is arranged in the shell 1, and the steam discharging device 3 comprises a water storage tank 31 used for storing liquid and a heating mechanism 32 used for heating the liquid to form steam. In the embodiment, the electric fireplace adopts a mode of directly heating liquid to generate steam to form an atomization effect so as to form a 3D flame effect in a matching way, and compared with the ultrasonic atomization technology, the electric fireplace has low cost and effectively improves the market competitiveness of products.

The water storage tank 31 is internally provided with a water storage cavity 311, the heating mechanism 32 comprises a heating chamber 321, a heating component 322 for heating the heating chamber 321 and a partition plate 323 for separating the heating chamber 321 and the water storage cavity 311, and the partition plate 323 is provided with a communicating part 324 for communicating the water storage cavity 311 and the heating chamber 321. In this embodiment, since the partition 323 is used to separate the heating chamber 321 from the water storage chamber 311, the heating chamber 321 and the water storage chamber 311 are only connected by the connection portion 324 on the partition 323, so that the heating mechanism 32 can effectively reduce the heat transfer of the liquid in the heating chamber 321 to the liquid in the water storage chamber 311 when heating the liquid in the heating chamber 321, and can quickly heat and boil the liquid in the heating chamber 321 to form vapor. Therefore, the embodiment can adopt the heating steam technology to replace the ultrasonic atomization technology to reduce the cost of the electric fireplace, and can quickly generate steam so that the electric fireplace can be used for forming the 3D flame effect.

In order to further reduce the heat transferred from the liquid in the heating chamber 321 into the water storage chamber 311, the partition 323 includes a first shroud 3231 surrounding the heating chamber 321 and a second shroud 3232 surrounding the outside of the first shroud 3231, a water inlet passage 33 is formed between the first shroud 3231 and the second shroud 3232, and the communication portion 324 includes a first communication hole 3241 provided on the first shroud 3231 for communicating the heating chamber 321 and the water inlet passage 33, and a second communication hole 3242 provided on the second shroud 3232 for communicating the water storage chamber 311 and the water inlet passage 33. Through the double coaming structure, the contact area between the water storage cavity 311 and the heating chamber 321 is reduced, so that the efficiency of transferring the heat of the liquid in the heating chamber 321 into the water storage cavity 311 is effectively further reduced, and the liquid in the heating chamber 321 forms steam faster.

Further, the first communication hole 3241 is provided on a side of the first surrounding plate 3231, and the second communication hole 3242 is provided on a side of the second surrounding plate 3232 away from the first communication hole 3241. The first communication hole 3241 and the second communication hole 3242 are spaced apart by a relatively large distance, and further reduce the efficiency of heat transfer of the liquid in the heating chamber 321 into the water storage chamber 311.

Further, in order to ensure that a realistic 3D flame effect is formed on the whole of the simulated fuel bed 2, the steam discharging device 3 includes a steam discharging portion 34 for discharging steam upward, and the steam discharging portion 34 is provided to extend in the length direction of the simulated fuel bed 2. Specifically, the steam discharge portion 34 in the present embodiment is a discharge groove that opens upward.

Further, in order to enable the steam in the heating chamber 321 to smoothly flow to the steam discharge portion 34, the steam discharge device 3 includes a steam guide mechanism 35 for communicating the heating chamber 321 and the steam discharge portion 34.

Specifically, the steam guiding mechanism 35 includes a guiding substrate 351, and the guiding substrate 351 is provided with a sleeve-connection side plate 352 for being sleeved on the outer side of the first enclosing plate 3231, a steam through hole 353 for communicating the heating chamber 321 with the steam discharging portion 34, and a guiding side plate 354 for guiding steam to the steam discharging portion 34. The above structure ensures that the steam generated in the heating chamber 321 can flow to the steam discharge portion 34 in its entirety.

Further, in order to facilitate the disassembly of the steam discharging device 3 in the casing 1, a drawer frame 5 detachably connected with the casing 1 is arranged on the casing 1, and the steam discharging device 3 and the first light source 4 are both arranged on the drawer frame 5.

Further, in order to facilitate the replenishment of the liquid in the water storage chamber 311, the steam discharging device 3 further comprises a water replenishing device 6 communicating with the water storage chamber 311.

In order to further beautify the visual effect of the electric fireplace, a second light source 7 is further arranged in the shell 1, and the second light source 7 is arranged below the simulated fuel bed 2 and is used for upwards irradiating the simulated fuel bed 2.

Further, a hot air outlet device 8 is arranged at the upper part of the shell 1. The hot air outlet device 8 comprises a fan and a heating element, and the hot air outlet device 8 can discharge the steam generated by the steam discharge device 3 to the use environment when blowing hot air, so that a certain humidifying effect can be brought to the use environment.

The working principle of the embodiment is as follows:

the steam generated by heating liquid by the steam discharging device 3 of the electric fireplace of the embodiment passes through the steam guiding mechanism 35 from the simulated fuel bed 2, and the first light source 4 cooperatively arranged irradiates the steam and the flame shape forming structure in the shell 1 so as to form a dynamic flame drifting effect in the shell 1, thereby forming a realistic effect of burning flame on the fuel bed.

The above description of various embodiments provided in connection with the specific disclosure is not intended to limit the practice of the utility model to those descriptions. The method, structure, etc. similar to or identical to those of the present utility model, or some technical deductions or substitutions are made on the premise of the inventive concept, should be regarded as the protection scope of the present utility model.

Claims (9)

1. Steam atomization 3D flame emulation electricity fireplace, including casing (1), be equipped with simulation fuel bed (2) in casing (1), its characterized in that, be equipped with steam discharging equipment (3) in casing (1) in simulation fuel bed (2) below, steam discharging equipment (3) are used for upwards discharging steam in order to form steam discharging area above steam discharging equipment (3), be equipped with in casing (1) and be used for shining first light source (4) in steam discharging area, steam discharging equipment (3) are including storage water tank (31) that are used for storing liquid and heating mechanism (32) that are used for heating liquid formation steam.

2. The steam atomization 3D flame simulation electric fireplace as defined in claim 1, wherein a water storage cavity (311) is provided in the water storage tank (31), the heating mechanism (32) comprises a heating chamber (321), a heating component (322) for heating the heating chamber (321) and a partition plate (323) for separating the heating chamber (321) and the water storage cavity (311), and a communicating part (324) for communicating the water storage cavity (311) and the heating chamber (321) is provided on the partition plate (323).

3. The steam atomizing 3D flame simulating electric fireplace as set forth in claim 2, wherein said partition (323) includes a first shroud (3231) for enclosing said heating chamber (321) and a second shroud (3232) for enclosing an outside of said first shroud (3231), a water inlet passage (33) is formed between said first shroud (3231) and said second shroud (3232), and said communication portion (324) includes a first communication hole (3241) provided on said first shroud (3231) for communicating said heating chamber (321) with said water inlet passage (33) and a second communication hole (3242) provided on said second shroud (3232) for communicating said water storage chamber (311) with said water inlet passage (33).

4. A steam atomizing 3D flame simulating electric fireplace as claimed in claim 3 wherein the first communicating hole (3241) is provided on a side of the first shroud (3231), and the second communicating hole (3242) is provided on a side of the second shroud (3232) remote from the first communicating hole (3241).

5. A steam atomizing 3D flame simulating electric fireplace as claimed in claim 3 wherein said steam discharge means (3) includes a steam discharge portion (34) for discharging steam upwardly, said steam discharge portion (34) being disposed extending along a length of said simulated fuel bed (2).

6. The steam atomizing 3D flame simulating electric fireplace of claim 5 wherein said steam discharge means (3) includes a steam deflector mechanism (35) for communicating said heating chamber (321) with said steam discharge portion (34).

7. The steam atomizing 3D flame simulating electric fireplace of claim 6, wherein the steam guiding mechanism (35) comprises a guiding base plate (351), and the guiding base plate (351) is provided with a sleeving side plate (352) used for sleeving the outer side of the first coaming (3231), a steam through hole (353) used for communicating the heating chamber (321) and the steam discharging part (34), and a guiding side plate (354) used for guiding steam to the steam discharging part (34).

8. The steam atomizing 3D flame simulating electric fireplace of claim 1, wherein the casing (1) is provided with a drawer frame (5) detachably connected with the casing (1), and the steam discharging device (3) and the first light source (4) are both arranged on the drawer frame (5).

9. The steam atomizing 3D flame simulating electric fireplace of claim 2 wherein said steam discharge means (3) further comprises water replenishment means (6) in communication with said water storage cavity (311).