CN210373694U - Disinfection warmer simulating 3D simulated flame - Google Patents

Abstract

The utility model discloses a disinfection room heater of simulation 3D emulation flame, include: the 3D simulation part is arranged at the upper part of the machine body, and the heating part and the sterilization part are arranged at the bottom of the machine body; the 3D simulation part comprises a water storage part, an atomization part, an air outlet part and a lamp flame part; the water storage tank of the water storage part is connected with the water bottle seat, the ultrasonic atomization plate of the atomization part changes the water of the water bottle seat into mist and stores the mist into the mist storage box, and the blower blows the mist into the mist storage box through the mist outlet pipe and flows out of the mist outlet; the lamp direction of the flame lamp strip in the lamp flame part is parallel to the fog outlet direction and is tightly attached to the fog outlet direction, and the cross-flow fan of the air outlet part generates wind to blow fog from the air outlet through the air duct and simultaneously is tightly attached to the lamp light; the DC direct current fan, the heating element fixing frame and the ceramic heating element of the heating part are fixed at the bottom of the machine body in a balanced manner; when the DC direct current fan rotates, the ultraviolet lamp of the sterilization part is lighted to perform sterilization. The utility model discloses a stalk feeding adjustment design of heating, humidification structure and product function realizes that three-dimensional flame simulation humidification effect satisfies portable use simultaneously.

Description

Disinfection warmer simulating 3D simulated flame

Technical Field

The utility model relates to a technical field in the aspect of the environmental protection electrical apparatus, especially a disinfection room heater of simulation 3D emulation flame.

Background

The electric heater is the device that heats with electric energy conversion heat energy, and present electric heater all is by the inside back that generates heat of fuselage, discharges the heat through the opening on the fuselage to heat the space, reach the heating effect. With the development of economy and the progress of society, energy conservation and health become necessary and socially recognized, and various electric appliances are developing in the direction of energy conservation, convenient use, space conservation, safety, high efficiency, multiple functions and the like. The electric heater is an important member of people's life electrical apparatus without exception, because the room heater on the existing market is only single heating function, and service environment is single, uses the room heater under the originally dry condition of weather in winter, and the humidity of indoor environment will receive serious influence.

In order to meet the requirements of energy conservation and practicability, the disinfection warmer is designed, and the unicity of the product use environment is greatly changed.

SUMMERY OF THE UTILITY MODEL

Objects of the invention

The utility model aims at providing a simulation 3D emulation flame's disinfection room heater through the stalk feeding adjustment design to structure and product function, overcomes the single defect of traditional room heater service environment, can satisfy portable use simultaneously, has the effect of heating, humidification air, disinfection and air-purifying, realizes three-dimensional flame simulation humidification effect, effectively adapts to energy saving and practicality demand.

(II) technical scheme

In order to realize the purpose, the utility model discloses a technical scheme:

a disinfecting warmer that simulates a 3D simulated flame, comprising:

a body, which at least comprises a 3D simulation part, a heating part and a sterilization part; the 3D simulation part is arranged at the upper part of the machine body, and the heating part and the sterilization part are arranged at the bottom of the machine body;

the 3D simulation part at least comprises a water storage part, an atomization part, an air outlet part and a lamp flame part; the water storage part is arranged in the upper cavity of the machine body and is close to a rear shell at the top of the machine body, the atomization part is connected with the water storage part and is communicated with the top of the machine body, and the air outlet part and the lamp flame part are arranged at the top of the machine body;

the water storage part comprises a water storage tank and a water bottle seat arranged at the bottom of the water storage tank; the bottom of the water storage tank is provided with a water tank water outlet communicated to the water bottle seat;

the atomizing part comprises an ultrasonic atomizing plate for converting water in the water bottle seat into mist, an anti-dry heating device for controlling a power supply of the ultrasonic atomizing plate, a mist storage box, a blower for producing wind power to blow the mist into the atomizing box from the mist storage box, a mist outlet pipe for conveying the mist to the atomizing box, and an atomizing box provided with a mist outlet; the bottom of the mist storage box is accommodated in the goblet cavity of the water goblet seat in an open manner, the ultrasonic atomization plate is arranged on one side of the lower end of the mist storage box and penetratingly mounted at the bottom of the water goblet seat, the blower is connected to the bottom of the water goblet seat at a position close to the ultrasonic atomization plate, the bottom of the water goblet seat is provided with a blast port, the blower is communicated to the mist storage box through the blast port, the top end of the mist storage box is communicated to the mist outlet pipe, and the bottom of the water goblet seat is connected with the dry burning prevention device at a position close to the ultrasonic atomization plate;

the ultrasonic atomization plate changes water in the water bottle base into mist through ultrasonic waves and stores the mist in the mist storage box, the air blower at the bottom of the water bottle base blows the mist into the atomization box at the top from the mist storage box through the mist outlet pipe, and the mist flows out through a mist outlet formed in the top of the atomization box to form a mist humidification channel;

the lamp flame part is arranged as a light outlet mechanism for simulating flame, the lamp flame part at least comprises a flame light bar, the flame light bar is arranged at the top of the machine body and is arranged above the fog outlet box, and the light direction of the flame light bar is parallel to and closely attached to the fog outlet direction;

the air outlet part comprises a cross flow fan and an air duct communicated with the cross flow fan, and an air outlet is formed in the top of the machine body at the upper end of the air duct; the cross-flow fan and the air duct are arranged in front of the fog outlet, the air outlet is arranged to be parallel to the fog outlet, the air outlet direction and the fog outlet direction in the air duct have a crossed angle, and the air generated by the cross-flow fan blows fog from the air outlet through the air duct and simultaneously clings to the light of the flame light bar to form an air humidifying channel of the three-dimensional simulated flame;

when the 3D simulation part, the heating part and the sterilization part are arranged to synchronously operate in the machine body, the 3D simulation part needs to carry out air humidification work of three-dimensional simulation flame while the heating part and the sterilization part carry out purification heating or after purification heating; the 3D simulation part is arranged at the upper ends of the heating part and the sterilization part, the heating part influences the fog outlet temperature of the 3D simulation part through heat conduction after heating, and simultaneously after the heating part and the sterilization part are purified and heated, the 3D simulation flame humidification effect realized by the 3D simulation part carries out feedback type heating and humidification on the heating environment in which the heating part generates hot air;

the heating device comprises a heating part, a sterilization part, a heating part and a control part, wherein the sterilization part is connected to one side of the heating part, and is used for sterilizing and disinfecting cold air simultaneously when the heating part works;

the heating part comprises a ceramic heating element, a heating element fixing frame for mounting the ceramic heating element and two DC direct current fans connected to the rear side of the ceramic heating element, wherein the DC direct current fans, the heating element fixing frame and the ceramic heating element are arranged and balanced and fixed at the bottom of the machine body; the front side of the heating part is provided with a transversely arranged air outlet grid, and the rear side of the heating part is provided with a transversely arranged air inlet grid;

the sterilizing part is vertically arranged on the left side of the heating body, is close to and vertical to the air inlet grid, and a light source of the sterilizing part is completely arranged in the machine body; when the DC direct current fan rotates to enable air to form convection, the sterilization and disinfection part performs sterilization and disinfection at the same time to form an air circulation purification channel.

In one or more embodiments of the present invention, the dry-heating preventing device includes a float for detecting a water level, and a reed pipe for controlling the working power supply of the ultrasonic atomization plate; the floater realizes longitudinal movement on the reed pipe by detecting water level to control the electrified contact of the reed pipe to be attracted or disconnected, so that the ultrasonic atomization plate is controlled to be electrified or powered off.

In one or more embodiments of the present invention, the float is a ring body provided with a magnet in the middle, the reed switch is provided with a power-on contact, the float cover is disposed on the reed switch, one end of the reed switch is connected to the power supply, and the other end of the reed switch is connected to the ultrasonic atomization plate.

In one or more embodiments of the present invention, the floater is disposed in the cavity of the water bottle seat, and the reed pipe is penetratingly installed at the bottom of the water bottle seat.

In one or more embodiments of the present invention, the 3D simulation part is disposed in the water mist environment located in the machine body and is communicated with the heating part and the sterilization part in the purified heating environment located in the machine body.

In one or more embodiments of the present invention, the heating unit includes an overheat protection device, and the overheat protection device is installed on the top surface of the heating unit.

In one or more embodiments of the present invention, a water tank cover is disposed behind the water tank to prevent dust from entering the water bottle seat.

In one or more embodiments of the present invention, the light emitting color of the flame light bar is colored light.

In one or more embodiments of the present invention, the lamp flame portion includes a lamp cover, and the lamp cover is installed above the flame light bar.

In one or more embodiments of the present invention, the machine body is provided with a vertical machine leg.

(III) advantageous effects

The utility model discloses compare produced profitable technological effect with the background art:

the above technical scheme is adopted in the utility model, a simulation 3D emulation flame's disinfection room heater is provided, through the stalk feeding adjustment design to on heating structure, humidification structure and the product function, can satisfy portable use simultaneously, has the effect of heating, humidification air, disinfection and air-purifying, realizes three-dimensional flame simulation humidification effect, and high efficiency optimization user experience degree promotes the heating and enjoys the process, uses convenient, effectively adapts to the energy saving, realizes the practicality demand. The novel water-saving device has the characteristics of scientific structure, reasonable design, economy, practicability, safety, environmental protection, reliability, firmness and long service life. Therefore, the novel electric heating furnace is a product with equal superior technical, practical and economic properties.

Drawings

Fig. 1 is a schematic structural view of a 3D simulated flame simulated disinfection warmer according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view of a side of FIG. 1;

fig. 3 is a schematic structural diagram of a 3D simulation part according to an embodiment of the present invention;

FIG. 4 is a rear view of FIG. 3;

FIG. 5 is a top view of FIG. 3;

FIG. 6 is a side view of FIG. 3;

FIG. 7 is a side sectional view of FIG. 3;

fig. 8 is a schematic structural view of a heating unit according to an embodiment of the present invention;

FIG. 9 is a schematic structural view of a sterilization part according to an embodiment of the present invention;

fig. 10 is a schematic view of a reed switch according to an embodiment of the present invention.

Reference numerals:

the device comprises a machine body 1, a top rear shell 11, a top front shell 12, a vertical machine leg 13, a bottom front shell 14, a bottom rear shell 15, a top cover 16, a 3D simulation part 2, a water storage part 21, a water storage tank 211, a water bottle base 212, a water tank water outlet 213, an atomization part 22, a fog outlet 220, an ultrasonic atomization plate 221, an anti-dry burning device 222, a fog storage box 223, an atomization box 224, an air blower 225, a blast port 226, a fog outlet pipe 227, a floater 228, a reed pipe 229, a lamp flame part 23, a flame lamp strip 231, a lamp shade 232, an air outlet part 24, a cross-flow fan 241, an air duct 242, an air outlet 243, an air inlet 244, a heating part 3, a ceramic heating body 31, a heating body fixing frame 32, a DC direct-flow fan 33, an air inlet grid 34, an air outlet grid 35, an overheating protection.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout.

In the description of the present invention, it should be noted that, for the orientation words, if there are terms such as "center", "lateral", "longitudinal", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc., the orientation and positional relationship indicated are based on the orientation or positional relationship shown in the drawings, and only for the convenience of describing the present invention and simplifying the description, it is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and not be construed as limiting the specific scope of the present invention.

Furthermore, if the terms "first" and "second" are used for descriptive purposes only, they are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features. Thus, the definition of "a first" or "a second" feature may explicitly or implicitly include one or more of the features, and in the description of the invention, "at least" means one or more unless specifically defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "assembled", "connected", and "connected", if any, are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally connected; or may be a mechanical connection; the two elements can be directly connected or connected through an intermediate medium, and the two elements can be communicated with each other. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to specific situations.

In the present application, unless otherwise specified or limited, "above" or "below" a first feature may include the first and second features being in direct contact, and may also include the first and second features not being in direct contact but being in contact with each other through another feature therebetween. Also, the first feature being "above," "below," and "above" the second feature includes the first feature being directly above and obliquely above the second feature, or simply an elevation which indicates a level of the first feature being higher than an elevation of the second feature. The first feature being "above", "below" and "beneath" the second feature includes the first feature being directly below or obliquely below the second feature, or merely means that the first feature is at a lower level than the second feature.

The technical solution and the advantages of the present invention will be more clear and clear by further describing the embodiments of the present invention with reference to the drawings of the specification. The embodiments described below are exemplary and are intended to be illustrative of the present invention, but should not be construed as limiting the invention.

As shown in fig. 1-10, the present embodiment provides a better technical solution of a disinfecting warmer for simulating a 3D simulated flame, which includes: the vertical type machine body 1 is characterized in that the upper portion of the machine body 1 comprises a top rear shell 11 and a top front shell 12 which are arranged on the front and rear sides of a 3D simulation part 2, a heating part 3 and a sterilization part 4 are arranged at the bottom of the machine body 1, the bottom of the machine body 1 comprises a bottom front shell 14 and a bottom rear shell 15 which are arranged on the front and rear sides of the heating part 3 and the sterilization part 4, a top cover 16 is arranged at the top of the machine body 1, and a vertical type machine foot 13 is arranged at the bottom of the machine body 1. The disinfection room heater of this embodiment sets up to vertical disinfection room heater, realizes portable use, convenient environmental protection.

Specifically, as shown in fig. 1 to 9, the machine body 1 includes a 3D simulation part 2, a heating part 3, and a sterilization part 44, and the 3D simulation part 2 is disposed on the upper part of the machine body 1. The 3D simulation part 2, the heating part 3 and the sterilization part 4 synchronously operate in the machine body 1, and the 3D simulation part 2 is arranged to carry out air humidification work of three-dimensional simulation flame, wherein the heating part 3 and the sterilization part 4 need to carry out purification heating work at the same time or after the purification heating work is carried out; 3D emulation portion 2 sets up in heating portion 3 and 4 upper ends of disinfection portion that disinfects, and heating portion 3 indirectly promotes the temperature of fog that goes out of 3D emulation portion 2 through generating heat at 1 lower extreme of organism, purifies the heating back at heating portion 3 and disinfection portion 4 that disinfects, and the produced simulation 3D emulation flame humidification effect of 3D emulation portion 2's air humidifying passageway produces warms up the humidification to heating portion 3 and produces hot-blast heating environment.

The 3D simulation part 2 includes a water storage part 21, an atomization part 22, a lamp flame part 23, and an air outlet part 24, the water storage part 21 is disposed in the cavity of the body 1 near the top rear shell 11 of the body 1, the atomization part 22 is connected to the water storage part 21 and communicated to the top of the body 1, and the lamp flame part 23 and the air outlet part 24 are disposed at the top of the body 1. As shown in fig. 2-9, the 3D simulation part 2 realizes a three-dimensional flame humidification effect through the cooperation of the water storage part 21, the atomization part 22, the lamp flame part 23 and the air outlet part 24, so as to efficiently optimize the user experience, improve the heating enjoyment process, and be convenient and fast to use, effectively adapt to energy conservation and realize the practicability requirement.

The water supply mechanism for converting water into mist provided in this embodiment is a water storage unit 21, specifically: the water storage portion 21 includes a water storage tank 211 and a water bottle base 212 disposed at the bottom of the water storage tank 211, the bottom of the water storage tank 211 is disposed with a water tank outlet 213 communicated to the water bottle base 212, and the water storage tank 21 is disposed with a water tank cover (not shown) for preventing dust from entering the water bottle base 212.

As shown in fig. 3 to 7, the mist supply mechanism provided in this embodiment is an atomizing part 22, specifically: the atomizing part 22 includes an ultrasonic atomizing plate 221 for atomizing water in the water bottle base 212, an anti-dry heating device 222 for controlling the power of the ultrasonic atomizing plate 221, a mist storage box 223, an atomizing box 224 with a mist outlet 220, a blower 225 for blowing mist from the mist storage box 223 to the atomizing box 224 by wind force, and a mist outlet pipe 227 for delivering mist to the atomizing box 224. Specifically, the method comprises the following steps: the bottom surface of the mist storage box 223 is accommodated in the goblet cavity of the water goblet seat 212 in an open manner, the ultrasonic atomization plate 221 is arranged on one side of the lower end of the mist storage box 221 and penetratingly mounted at the bottom of the water goblet seat 212, the blower 225 is connected to the bottom of the water goblet seat 212 at a position close to the ultrasonic atomization plate 221, the bottom surface of the water goblet seat 212 is provided with a blast port 226, the blower 225 blows through the blast port 226 and is communicated to the mist storage box 223, the top end of the mist storage box 223 is communicated to the mist outlet pipe 227, the bottom of the water goblet seat 212 is connected with the anti-dry burning device 222 at a position close to the ultrasonic atomization plate 221, the anti-dry burning device 222 comprises a floater 228 for detecting the water level and a reed pipe 229 for controlling the working power supply of the ultrasonic atomization plate, the floater 228 is arranged in the goblet cavity. As shown in fig. 10, specifically: the floater 228 is a ring body with a magnet in the middle, the reed switch 229 is provided with a power-on contact 10, the floater 228 is sleeved on the reed switch 229, one end of the reed switch 229 is connected with a power supply, and the other end of the reed switch 229 is connected with the ultrasonic atomization plate 221. When water exists, the floater 228 floats upwards to enable the middle of the reed switch 229 to be electrified and electrically contacted with the electric shock 10 for suction, so that the ultrasonic atomization plate 221 is electrified and has fog; in the absence of water, the float 228 moves downward, the middle of the reed switch 229 is energized, the electric shock 10 is cut off, the ultrasonic atomization plate 221 is not energized, and the mist discharge operation is not performed.

In this embodiment, when the 3D simulation part 2, the heating part 3 and the sterilization part 4 are set to operate in the machine body 1 synchronously, the 3D simulation part 2 must perform air humidification work of three-dimensional simulation flame while the heating part 3 and the sterilization part 4 perform heating or after heating; 3D emulation portion 2 sets up in heating portion 3 and 4 upper ends of disinfection portion that disinfects, and heating portion 3 is through the play fog temperature of heat-conduction influence 3D emulation portion after generating heat, and after heating portion 3 and disinfection portion 4 that disinfects purified the heating simultaneously, the warm humidification of feedback formula is carried out to the heating portion 3 to the warm environment that produces hot-blast heating of 3D emulation flame humidification effect that 3D emulation portion 2 realized. Specifically, the method comprises the following steps: the embodiment communicates heating unit 3 and sterilization unit 4 in the purification heating environment that organism 1 is located on the heat conduction space through setting up the water smoke environment that 3D emulation portion 2 is located in organism 1. After the heating part 3 and the sterilization part 4 are purified and heated, the heating environment in which the heating part 3 generates hot air is heated and humidified by the simulated 3D simulated flame humidifying effect generated by the air humidifying channel of the 3D simulation part 2.

As shown in fig. 2, 3 and 7, the light emitting mechanism provided in this embodiment is a lamp flame portion 23, specifically: lamp flame portion 23 is the light-emitting mechanism of simulation flame, and lamp flame portion 23 includes a flame lamp strip 231, and flame lamp strip 231 sets up in 1 top of organism and installs in atomizing box 224 top, and sets up the light direction of flame lamp strip 231 and goes out that the fog direction is parallel and paste tightly to guarantee that light direction and play fog direction can cooperate the air-out of air-out portion 24 to realize the emulation humidification effect of 3D's light simulation flame. In the present embodiment, the light emitting color of the flame light bar 231 is colored light, and preferably, the light emitting effect similar to flame and capable of simulating flame is selected. Specifically, the method comprises the following steps: lamp flame portion 23 includes lamp shade 232, and lamp shade 232 is installed in flame lamp strip 231 top, and is further, the utility model discloses setting up lamp shade 232 and adopting the printing opacity material to make, the light-emitting effect that combines flame lamp strip 231 through the light transmissivity of lamp shade 232 forms lifelike flame light-emitting state.

In combination with the above arrangement structure of the lamp flame portion 23: as shown in fig. 2, 3 and 7, the air outlet portion 24 provided in this embodiment specifically includes: the cross-flow fan 241 and the air duct 242 are communicated with the cross-flow fan 241, an air outlet 243 is formed in the top of the machine body 1 at the upper end of the air duct 242, an air inlet 244 is formed in the top of the machine body 1 of the cross-flow fan 241, the cross-flow fan 241 and the air duct 242 are arranged in front of the fog outlet 220, the air outlet 243 is arranged to be parallel to the fog outlet 220, the air outlet direction and the fog outlet direction in the air duct 242 have a cross angle, and the air generated by the cross-flow fan 241 blows fog from the air outlet 243 and simultaneously clings to the light of the flame light bar 231 to form an air humidifying channel with a three-dimensional simulated flame effect.

Through the specific structural arrangement of the water storage part 21, the atomization part 22 and the lamp flame part 23, the following atomization and humidification process of the embodiment is realized: the ultrasonic atomization plate 221 changes water in the water bottle base 212 into mist through ultrasonic waves and stores the mist in the mist storage box 223, the blower 225 at the bottom of the water bottle base 211 blows the mist from the mist storage box 223 into the atomization box 224 at the top through the mist outlet pipe 227, and the mist flows out through the mist outlet 220 formed in the top of the atomization box 224 to form a mist humidification channel. Meanwhile, to avoid the danger of dry burning without water, the float 228 controls the power-on contact of the reed switch 229 to be closed or opened by detecting the water level to move longitudinally on the reed switch 229, thereby controlling the power-on or power-off of the ultrasonic atomization plate 221. The air outlet 243 is arranged at the front side of the fog outlet 220, the fog outlet 220 is arranged at the front side of the lamp flame part 23, the fog from the fog outlet 220 is blown by the wind generated by the cross flow fan 241 through the air outlet 243 and simultaneously clings to the light of the flame light bar 231, and an air humidifying channel with a three-dimensional simulated flame effect is formed.

The disinfection heating process of the embodiment is realized as follows:

the disinfection portion 4 that disinfects connects in heating portion 3 left sides, and the disinfection portion 4 that disinfects of 3 during operations of heating portion disinfects the disinfection simultaneously, and heating portion 3 converts cold wind into hot-blast in-process, sets up the disinfection portion 4 that disinfects and carries out the air sterilization disinfection processing to cold wind before cold wind gets into the room heater. Specifically, the method comprises the following steps: as shown in fig. 2 and 8, the heating mechanism is a heating unit 3, which includes a ceramic heating element 31, a heating element holder 32 for mounting the ceramic heating element 31, and two DC fans 33 connected to the rear side of the ceramic heating element 31; the DC direct current fan 33, the heating element fixing frame 32 and the ceramic heating element 31 are arranged and balanced and fixed at the bottom of the machine body 1; the front side of the heating part 3 is a transversely arranged air outlet grid 35, and the rear side is a transversely arranged air inlet grid 34. The heating unit 3 includes an overheat protection unit 36, and the overheat protection unit 36 is mounted on the top surface of the ceramic heating element 31. As shown in fig. 2 and 9, the sterilization and disinfection part 4 as a disinfection mechanism includes an ultraviolet lamp 41, the ultraviolet lamp 41 is vertically disposed at the left side of the ceramic heating body 31, close to and perpendicular to the air inlet grid 34, and the light source of the ultraviolet lamp 41 is completely disposed in the machine body 1. When the DC fan 33 rotates to form convection of air, the ultraviolet lamp 41 is lighted to sterilize and disinfect, and an air circulation purification channel is formed.

The heating part 3 indirectly promotes the fog temperature of the 3D simulation part 2 through heating at the lower end of the machine body 1, specifically: when the heating part 3 performs heating operation at the bottom of the machine body 1 through the ceramic heating body 31, a heating environment is formed in the machine body 1 of the ceramic heating body 31 to be different from a cold environment in which the heater is placed, in the process, when the heating part 3 is matched with the sterilization and disinfection part 4 to perform purification and heating, the bottom of the machine body 1 forms the heating environment, a water mist environment in which the 3D simulation part 2 at the upper part of the machine body 1 is located is also influenced by the hot environment of the heating part 3 to form a heating environment, the water mist environment comprises water in the water storage tank 211 and the water goblet seat 212 in the water storage part 21 and mist in the mist storage box 223 in the mist spraying part 22, specifically, the water mist setting mechanism of the 3D simulation part 2 such as the water storage tank 211, the water goblet seat 212, the mist storage box 223 and the like can be made of materials which are easy to conduct heat conduction, therefore, the rest of the heat energy generated by the, can be effectively utilized to 3D emulation portion 2 and carry out cyclic utilization, further promote the result of use of warm humidification when realizing that 3D flame simulation goes out fog effect. Foretell 3D emulation portion 2, heating portion 3, the cooperation setting of disinfection portion 4 that disinfects realize the utility model relates to a disinfection room heater of simulation 3D emulation flame, through the stalk feeding adjustment design to heating structure, humidification structure and product function, overcome the defect that traditional room heater service environment is single, changed product service environment's unicity greatly.

The utility model discloses can satisfy portable use simultaneously, have heating, humidification air, disinfection and air-purifying's effect, realize three-dimensional flame simulation humidification effect, high-efficient optimization user experience degree promotes the heating and enjoys the process, uses convenient, effectively adapt to the energy saving, realizes the practicality demand. The novel water-saving device has the characteristics of scientific structure, reasonable design, economy, practicability, safety, environmental protection, reliability, firmness and long service life. Therefore, the novel electric heating furnace is a product with equal superior technical, practical and economic properties.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (10)

1. The utility model provides a disinfection room heater of simulation 3D emulation flame which characterized in that includes:

a body, which at least comprises a 3D simulation part, a heating part and a sterilization part; the 3D simulation part is arranged at the upper part of the machine body, and the heating part and the sterilization part are arranged at the bottom of the machine body;

the 3D simulation part at least comprises a water storage part, an atomization part, an air outlet part and a lamp flame part; the water storage part is arranged in the upper cavity of the machine body and is close to a rear shell at the top of the machine body, the atomization part is connected with the water storage part and is communicated with the top of the machine body, and the air outlet part and the lamp flame part are arranged at the top of the machine body;

the water storage part comprises a water storage tank and a water bottle seat arranged at the bottom of the water storage tank; the bottom of the water storage tank is provided with a water tank water outlet communicated to the water bottle seat;

the atomizing part comprises an ultrasonic atomizing plate for converting water in the water bottle seat into mist, an anti-dry heating device for controlling a power supply of the ultrasonic atomizing plate, a mist storage box, a blower for producing wind power to blow the mist into the atomizing box from the mist storage box, a mist outlet pipe for conveying the mist to the atomizing box, and an atomizing box provided with a mist outlet; the bottom of the mist storage box is accommodated in the goblet cavity of the water goblet seat in an open manner, the ultrasonic atomization plate is arranged on one side of the lower end of the mist storage box and penetratingly mounted at the bottom of the water goblet seat, the blower is connected to the bottom of the water goblet seat at a position close to the ultrasonic atomization plate, the bottom of the water goblet seat is provided with a blast port, the blower is communicated to the mist storage box through the blast port, the top end of the mist storage box is communicated to the mist outlet pipe, and the bottom of the water goblet seat is connected with the dry burning prevention device at a position close to the ultrasonic atomization plate;

the ultrasonic atomization plate changes water in the water bottle base into mist through ultrasonic waves and stores the mist in the mist storage box, the air blower at the bottom of the water bottle base blows the mist into the atomization box at the top from the mist storage box through the mist outlet pipe, and the mist flows out through a mist outlet formed in the top of the atomization box to form a mist humidification channel;

the lamp flame part is arranged as a light outlet mechanism for simulating flame, the lamp flame part at least comprises a flame light bar, the flame light bar is arranged at the top of the machine body and is arranged above the fog outlet box, and the light direction of the flame light bar is parallel to and closely attached to the fog outlet direction;

the air outlet part comprises a cross flow fan and an air duct communicated with the cross flow fan, and an air outlet is formed in the top of the machine body at the upper end of the air duct; the cross-flow fan and the air duct are arranged in front of the fog outlet, the air outlet is arranged to be parallel to the fog outlet, the air outlet direction and the fog outlet direction in the air duct have a crossed angle, and the air generated by the cross-flow fan blows fog from the air outlet through the air duct and simultaneously clings to the light of the flame light bar to form an air humidifying channel of the three-dimensional simulated flame;

when the 3D simulation part, the heating part and the sterilization part are arranged to synchronously operate in the machine body, the 3D simulation part needs to carry out air humidification work of three-dimensional simulation flame while the heating part and the sterilization part carry out purification heating or after purification heating; the 3D simulation part is arranged at the upper ends of the heating part and the sterilization part, the heating part influences the fog outlet temperature of the 3D simulation part through heat conduction after heating, and simultaneously after the heating part and the sterilization part are purified and heated, the 3D simulation flame humidification effect realized by the 3D simulation part carries out feedback type heating and humidification on the heating environment in which the heating part generates hot air;

the heating device comprises a heating part, a sterilization part, a heating part and a control part, wherein the sterilization part is connected to one side of the heating part, and is used for sterilizing and disinfecting cold air simultaneously when the heating part works;

the heating part comprises a ceramic heating element, a heating element fixing frame for mounting the ceramic heating element and two DC direct current fans connected to the rear side of the ceramic heating element, wherein the DC direct current fans, the heating element fixing frame and the ceramic heating element are arranged and balanced and fixed at the bottom of the machine body; the front side of the heating part is provided with a transversely arranged air outlet grid, and the rear side of the heating part is provided with a transversely arranged air inlet grid;

the sterilizing part is vertically arranged on the left side of the heating body, is close to and vertical to the air inlet grid, and a light source of the sterilizing part is completely arranged in the machine body; when the DC direct current fan rotates to enable air to form convection, the sterilization and disinfection part performs sterilization and disinfection at the same time to form an air circulation purification channel.

2. The simulated 3D simulated flame disinfecting warmer of claim 1, characterized in that: the dry burning prevention device comprises a floater for detecting the water level and a reed switch for controlling the working power supply of the ultrasonic atomization plate; the floater realizes longitudinal movement on the reed pipe by detecting water level to control the electrified contact of the reed pipe to be attracted or disconnected, so that the ultrasonic atomization plate is controlled to be electrified or powered off.

3. The simulated 3D simulated flame disinfecting warmer of claim 2, characterized in that: the floater is a ring body with a magnet in the middle, the reed switch is provided with a power-on contact, the floater is sleeved on the reed switch, one end of the reed switch is connected with a power supply, and the other end of the reed switch is connected with the ultrasonic atomization plate.

4. A disinfecting warmer that simulates a 3D simulated flame as claimed in claim 3, characterized by: the floater is arranged in the goblet cavity of the water goblet seat, and the reed pipe is penetratingly arranged at the bottom of the water goblet seat.

5. A disinfecting warmer simulating a 3D simulated flame as claimed in any one of claims 1-4, characterized in that: the water mist environment where the 3D simulation part is arranged in the machine body is communicated with the heating part and the purified heating environment where the sterilization part is arranged in the machine body in a heat conduction space.

6. The simulated 3D simulated flame disinfecting warmer of claim 5, characterized in that: the heating part comprises an overheating protection device, and the overheating protection device is arranged on the top surface of the heating body.

7. The simulated 3D simulated flame disinfecting warmer of claim 6, characterized in that: a water tank cover for preventing dust from entering the water bottle seat is arranged behind the water tank.

8. The simulated 3D simulated flame disinfecting warmer of claim 7, characterized in that: the light emitting color of the flame light bar is colored light.

9. The simulated 3D simulated flame disinfecting warmer of claim 8, wherein: the lamp flame portion includes a lamp cover installed above the flame light bar.

10. A disinfecting warmer simulating a 3D simulated flame as claimed in any one of claims 6-9, characterized in that: the machine body is provided with a vertical machine leg.

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