CN221354818U - Heat radiation structure of hot fog humidifier - Google Patents

Abstract

The utility model provides a heat radiation structure of hot fog humidifier, including housing assembly and upper cover subassembly, upper cover subassembly lid closes at housing assembly's top, still including setting up the inner bag subassembly in housing assembly, set up the play fog part on upper cover subassembly and set up the first fan between housing assembly and upper cover subassembly, be provided with the external first fresh air inlet of intercommunication on the housing assembly, be provided with first wind channel in the housing assembly, be provided with the second wind channel in the upper cover subassembly, inner bag subassembly, play fog part and external intercommunication in proper order, the air inlet end intercommunication first fresh air inlet of first fan, the air outlet end of first fan, first wind channel and second wind channel communicate in proper order, the inside or play fog part of second wind channel intercommunication inner bag subassembly. When the first fan works, the hot fog humidifier is introduced from the outside to blow into the liner assembly or the fog outlet component, so that the hot fog on the fog outlet component is pressed out, and meanwhile, the hot fog is cooled to a certain extent, the humidifying effect of the hot fog humidifier can be improved, and the human body is prevented from being scalded.

Description

Heat radiation structure of hot fog humidifier

Technical Field

The utility model relates to a humidifier, in particular to a heat dissipation structure of a hot fog humidifier.

Background

The traditional hot fog humidifier comprises a shell component and an upper cover component, wherein the shell component is internally provided with a liner component, the upper cover component is covered above the liner component, the upper cover component is provided with a fog outlet component, the fog outlet component is mutually communicated with the liner component, the liner component is used for heating water, hot fog is generated, the hot fog is sprayed out of the fog outlet component, but the hot fog discharging speed is low, the hot fog is easy to accumulate on the fog outlet component, the humidifying effect is poor, the sprayed hot fog is high in temperature, and a human body is easy to scald.

Therefore, further improvements are needed.

Disclosure of utility model

The utility model aims to provide a heat radiation structure of a hot fog humidifier, which has the advantages of simple structure, good humidifying effect, good heat radiation effect, safety, reliability and strong practicability, so as to overcome the defects of the existing coffee machine.

According to the heat radiation structure of this purpose design of hot fog humidifier, including shell subassembly and upper cover subassembly, upper cover subassembly lid closes at shell subassembly's top, its characterized in that: the inner container assembly is arranged in the shell assembly, the mist outlet component is arranged on the upper cover assembly, the first fan is arranged between the shell assembly and the upper cover assembly, a first air inlet hole communicated with the outside is formed in the shell assembly at a position corresponding to the first fan, a first air channel is formed in the shell assembly at a position corresponding to the first fan, a second air channel is formed in the upper cover assembly at a position corresponding to the first air channel, the inner container assembly, the mist outlet component and the outside are sequentially communicated, an air inlet end of the first fan is communicated with the first air inlet hole, an air outlet end of the first fan, the first air channel and the second air channel are sequentially communicated, and the second air channel is communicated with the inner container assembly or the mist outlet component; when the first fan works, external cold air sequentially passes through the first air inlet hole, the first fan, the first air channel and the second air channel to enter the inner container assembly or the fog outlet component, so that hot fog on the fog outlet component is extruded to the outside.

A first accommodating cavity is formed in the shell assembly, a power supply control board and a second fan are arranged in the first accommodating cavity, the second fan is located on one side of the power supply control board, a second air inlet hole and a first air outlet hole are respectively formed in two sides of the shell assembly, and the second air inlet hole, the first accommodating cavity and the first air outlet hole are communicated in sequence; when the second fan works, external cold air enters the first accommodating cavity through the second air inlet and is discharged through the first air outlet so as to radiate the power supply control board.

A second accommodating cavity is formed in the shell assembly, an electromagnetic heating component is arranged in the second accommodating cavity, the power supply control board is electrically connected with the electromagnetic heating component, a third fan is arranged in the first accommodating cavity, a second air outlet hole is formed in the shell assembly, the air inlet end of the third fan is communicated with the second air inlet hole, and the air outlet end of the third fan, the second accommodating cavity and the second air outlet hole are sequentially communicated; when the third fan works, external cold air sequentially enters the second accommodating cavity through the second air inlet hole and the first accommodating cavity and is discharged through the second air outlet hole so as to radiate the electromagnetic heating component.

The shell component is provided with a baffle, the first accommodating cavity and the second accommodating cavity are separated by the baffle, one end of the baffle is provided with a notch, and the first accommodating cavity and the second accommodating cavity are mutually communicated by the notch; when the second fan works, external cold air sequentially enters the second accommodating cavity through the second air inlet hole and the first accommodating cavity and is discharged through the second air outlet hole so as to radiate the electromagnetic heating component.

The shell component comprises an upper shell, a middle shell and a lower shell, wherein a first mounting groove is formed in the upper shell, a second mounting groove is formed in the middle shell, the air outlet end of the first fan is arranged in the first mounting groove, the air inlet end of the first fan is arranged in the second mounting groove, the first air channel is arranged at a position, corresponding to the first mounting groove, on the upper shell, and the first air channel is communicated with the first mounting groove.

The upper cover assembly comprises a first cover body and a second cover body which are connected with each other, the second cover body is positioned between the first cover body and the upper shell, and the first cover body covers the outer side of the second cover body; a groove is formed in one side of the second cover body, and a second air channel is formed between the groove and the inner side wall of the first cover body; the second cover body is provided with an installation cavity, the mist outlet component is installed on the installation cavity, a first through hole is formed in one side of the installation cavity, corresponding to the position of the second air duct, of the mist outlet component, a second through hole is formed in one side of the mist outlet component, and the second air duct is communicated with the mist outlet component through the first through hole and the second through hole in sequence.

The position of upper shell one side corresponds to first wind channel is provided with the third through-hole, and the recess bottom is provided with the fourth through-hole corresponding to the position of third through-hole, and first wind channel loops through third through-hole and fourth through-hole intercommunication second wind channel.

A first accommodating cavity is formed between the upper shell and the middle shell, a second accommodating cavity is formed on the middle shell, a second air outlet hole is formed in the position, corresponding to the second accommodating cavity, of the first side, the second side and the third side of the middle shell, and a first air inlet hole is formed in the position, corresponding to the first fan, of the first side of the middle shell.

The second air inlet hole, the second fan, the power supply control board, the third fan and the first air outlet hole are arranged in a straight line in sequence.

The hot fog humidifier comprises a water tank and a water pump assembly which are arranged in a shell assembly, an electromagnetic heating component is arranged at the bottom of a liner assembly, a fog outlet component is arranged at the top of the liner assembly, the water tank, the water pump assembly and the liner assembly are communicated in sequence, and the liner assembly, the fog outlet component and the outside are communicated in sequence; when the hot fog humidifier works, the water pump assembly pumps water in the water tank into the inner container assembly, the electromagnetic heating component heats the water in the inner container assembly and generates fog, and the fog is discharged to the outside through the fog outlet component.

According to the utility model, the first fan, the first air inlet hole, the first air duct and the second air duct are arranged, the air inlet end of the first fan is communicated with the first air inlet hole, the air outlet end of the first fan, the first air duct and the second air duct are sequentially communicated, the second air duct is communicated with the inner container assembly or the mist outlet component, when the first fan works, air is introduced from the outside to blow into the inner container assembly or the mist outlet component, hot mist on the mist outlet component is extruded, and meanwhile, the temperature of the hot mist is reduced to a certain extent, so that the humidifying effect of the hot mist humidifier can be improved, and the human body is prevented from being scalded; the second fan and the third fan are arranged in the shell assembly and are respectively used for radiating heat of the power supply control board and the electromagnetic heating component, so that the damage or the safety accident caused by the overhigh temperature of the power supply control board and the electromagnetic heating component is avoided.

Drawings

Fig. 1 is a schematic view showing the overall structure of a mist humidifier according to an embodiment of the present utility model.

Fig. 2 is a sectional view showing a part of the structure of a mist humidifier according to an embodiment of the present utility model.

Fig. 3 is a sectional view showing a part of the structure of the mist humidifier in another aspect of an embodiment of the present utility model.

Fig. 4-7 are schematic views of a part of a hot fog humidifier in different orientations according to an embodiment of the present utility model.

Fig. 8 is a schematic diagram of the overall structure of the second cover according to an embodiment of the utility model.

Fig. 9 is a schematic view showing the overall structure of the middle case according to an embodiment of the present utility model.

Fig. 10 is a schematic overall structure of the first cover according to an embodiment of the utility model.

Fig. 11 is a schematic view showing a part of the structure of the hot mist humidifier when the upper cover assembly is opened in accordance with an embodiment of the present utility model.

Fig. 12 is a schematic view showing a partial structure of a mist humidifier according to an embodiment of the present utility model.

Fig. 13 is a partially exploded view of a mist humidifier according to an embodiment of the utility model.

Detailed Description

The utility model is further described below with reference to the drawings and examples.

Referring to fig. 1-13, the heat radiation structure of the hot fog humidifier comprises a shell component a and an upper cover component b, wherein the upper cover component b covers the top of the shell component a, the heat radiation structure further comprises a liner component c arranged in the shell component a, a fog outlet component 1 arranged on the upper cover component b and a first fan 2 arranged between the shell component a and the upper cover component b, a first air inlet 3 communicated with the outside is arranged at a position corresponding to the first fan 2 on the shell component a, a first air channel 4 is arranged at a position corresponding to the first fan 2 in the shell component a, a second air channel 5 is arranged at a position corresponding to the first air channel 4 in the upper cover component b, the liner component c, the fog outlet component 1 and the outside are sequentially communicated, an air inlet end of the first fan 2 is communicated with the first air inlet 3, an air outlet end of the first fan 2, the first air channel 4 and the second air channel 5 are sequentially communicated, and the second air channel 5 is communicated with the inside of the liner component c or the fog outlet component 1; as shown by arrows in fig. 2 and 3, when the first fan 2 works, external cold air sequentially passes through the first air inlet hole 3, the first fan 2, the first air duct 4 and the second air duct 5 to enter the inner container assembly c or the mist outlet component 1, so that hot mist on the mist outlet component 1 is extruded to the outside.

A first accommodating cavity 6 is formed in the shell component a, a power supply control board 7 and a second fan 8 are arranged in the first accommodating cavity 6, the second fan 8 is positioned on one side of the power supply control board 7, a second air inlet hole 9 and a first air outlet hole 10 are respectively formed in two sides of the shell component a, the second air inlet hole 9, the first accommodating cavity 6 and the first air outlet hole 10 are communicated in sequence, and the second fan 8 is arranged close to the second air inlet hole 9; as shown by the arrow in fig. 4, when the second fan 8 is operated, external cold air enters the first accommodating cavity 6 through the second air inlet hole 9, passes through the power control board 7, and is discharged through the first air outlet hole 10 to dissipate heat of the power control board 7.

A second accommodating cavity 11 is formed in the shell component a, an electromagnetic heating component 12 is arranged in the second accommodating cavity 11, the power supply control board 7 is electrically connected with the electromagnetic heating component 12, the electromagnetic heating component 12 is an IH coil, a third fan 13 is arranged in the first accommodating cavity 6, a second air outlet hole 14 is formed in the shell component a, the air inlet end of the third fan 13 is communicated with the second air inlet hole 9, and the air outlet end of the third fan 13, the second accommodating cavity 11 and the second air outlet hole 14 are sequentially communicated; as shown by the arrow in fig. 5, when the third fan 13 works, external cold air sequentially enters the second accommodating cavity 11 through the second air inlet hole 9 and the first accommodating cavity 6 and is discharged through the second air outlet hole 14, so as to radiate heat of the electromagnetic heating component 12.

The power control board 7 is electrically connected to the first fan 2, the second fan 8, and the third fan 13, respectively.

A partition plate 15 is arranged on the shell component a, the first accommodating cavity 6 and the second accommodating cavity 11 are separated by the partition plate 15, a gap 16 is arranged at one end of the partition plate 15, the first accommodating cavity 6 and the second accommodating cavity 11 are communicated with each other through the gap 16, and the third fan 13 is arranged on the gap 16; when the second fan 8 works, external cold air sequentially enters the second accommodating cavity 11 through the second air inlet hole 9 and the first accommodating cavity 6 and is discharged through the second air outlet hole 14 so as to radiate heat to the electromagnetic heating component 12, part of air blown out by the second fan 8 can reach the first air outlet hole 10, and the other part of air can enter the second accommodating cavity 11 through the notch 16 so as to radiate heat to the electromagnetic heating component 12, so that if the heating temperature rise of the electromagnetic heating component 12 is not large, the third fan 13 can not be arranged.

The shell assembly a comprises an upper shell 17, a middle shell 18 and a lower shell 19, wherein a first mounting groove 17.1 is formed in the upper shell 17, a second mounting groove 18.1 is formed in the middle shell 18, the air outlet end of the first fan 2 is arranged in the first mounting groove 17.1, the air inlet end of the first fan 2 is arranged in the second mounting groove 18.1, the first air duct 4 is arranged at a position, corresponding to the first mounting groove 17.1, on the upper shell 17, and the first air duct 4 is communicated with the first mounting groove 17.1.

The upper cover assembly b comprises a first cover body 20 and a second cover body 21 which are connected with each other, the second cover body 21 is positioned between the first cover body 20 and the upper shell 17, and the first cover body 20 covers the outer side of the second cover body 21; a groove 21.1 is formed in one side of the second cover body 21, and a second air channel 5 is formed between the groove 21.1 and the inner side wall of the first cover body 20; the second cover body 21 is provided with a mounting cavity 22, the mist outlet component 1 is mounted on the mounting cavity 22, a first through hole 23 is formed in one side of the mounting cavity 22 and corresponds to the position of the second air duct 5, a second through hole 1.1 is formed in one side of the mist outlet component 1, the second air duct 5 is communicated with the mist outlet component 1 through the first through hole 23 and the second through hole 1.1 in sequence, a mist outlet 1.2 communicated with the outside is formed in the top of the mist outlet component 1, and the mist outlet component 1 is a mist outlet nozzle.

The position of one side of the upper shell 17 corresponding to the first air duct 4 is provided with a third through hole 17.2, the bottom of the groove 21.1 is provided with a fourth through hole 21.2 corresponding to the position of the third through hole 17.2, and the first air duct 4 is communicated with the second air duct 5 through the third through hole 17.2 and the fourth through hole 21.2 in sequence.

A first accommodating cavity 6 is formed between the upper shell 17 and the middle shell 18, the second accommodating cavity 11 is arranged on the middle shell 18, the second air outlet holes 14 are formed in positions of the first side 18.2, the second side 18.3 and the third side 18.4 of the middle shell 18 corresponding to the second accommodating cavity 11, the first air inlet holes 3 are formed in positions of the first side 18.2 of the middle shell 18 corresponding to the first fan 2, and the second air inlet holes 9 and the first air outlet holes 10 are respectively formed on two sides of the upper shell 17.

The second air inlet hole 9, the second fan 8, the power supply control board 7, the third fan 13 and the first air outlet hole 10 are arranged in a straight line in sequence, so that the heat dissipation efficiency is improved.

The hot fog humidifier comprises a water tank 24 and a water pump assembly d which are arranged in a shell assembly a, an electromagnetic heating component 12 is arranged at the bottom of a liner assembly c, a fog outlet component 1 is arranged at the top of the liner assembly c, the water tank 24, the water pump assembly d and the liner assembly c are sequentially communicated, and the liner assembly c, the fog outlet component 1 and the outside are sequentially communicated; when the hot mist humidifier works, the water pump assembly d pumps water in the water tank 24 into the inner container assembly c, the electromagnetic heating component 12 heats the water in the inner container assembly c and generates mist, and the mist is discharged to the outside through the mist outlet component 1 so as to sterilize and humidify the outside.

The middle shell 18 is supported on the water tank 24, the upper shell 17 is connected with the middle shell 18 in a matching way, the upper cover component b is arranged on the upper shell 17 in a rotating and opening way, the water tank 24 is arranged in the lower shell 19, and the liner component c is supported on the upper shell 17 and/or the middle shell 18.

The inner container assembly e comprises an installation outer frame 25, an inner container 26 and a cover body 27, wherein the installation outer frame 25 is supported and installed on the upper shell 17 and/or the middle shell 18, the inner container 26 is supported and installed in the installation outer frame 25, the cover body 27 is installed at the opening of the top of the inner container 26 in a covering mode, the mist outlet component 1 is arranged above the cover body 27, a fifth through hole 27.1 is formed in the cover body 27, the mist outlet component 1 is communicated with the inner container 26 through the fifth through hole 27.1, and hot mist in the inner container 26 enters the mist outlet component 1 through the fifth through hole 27.1.

The water pump assembly d comprises a water pump 28 and an adapter 29, a water pumping nozzle 30 is arranged on the middle shell 18, the upper end of the water pumping nozzle 18 is connected with a water inlet of the water pump 28 through a water pipe, the lower end of the water pumping nozzle 30 is connected with a water pipe extending into the water tank 24, a water outlet of the water pump 28 is connected with a water inlet of the adapter 29 through the water pipe, a water outlet of the adapter 29 is connected with a cover 27 through the water pipe, and the water pipe penetrates through the cover 27 and extends into the liner 26.

The foregoing is a preferred embodiment of the utility model showing and describing the general principles, features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, which have been described in the foregoing description merely illustrates the principles of the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a heat radiation structure of hot fog humidifier, includes shell subassembly (a) and upper cover subassembly (b), and upper cover subassembly (b) lid closes at the top of shell subassembly (a), its characterized in that: the novel air conditioner further comprises an inner container assembly (c) arranged in the shell assembly (a), a fog outlet component (1) arranged on the upper cover assembly (b) and a first fan (2) arranged between the shell assembly (a) and the upper cover assembly (b), wherein a first air inlet hole (3) communicated with the outside is formed in the position, corresponding to the first fan (2), of the shell assembly (a), a first air channel (4) is formed in the position, corresponding to the first fan (2), of the shell assembly (a), a second air channel (5) is formed in the position, corresponding to the first air channel (4), of the upper cover assembly (b), the inner container assembly (c), the fog outlet component (1) and the outside are sequentially communicated, the air inlet end of the first fan (2) is communicated with the first air inlet hole (3), the air outlet end of the first fan (2), the first air channel (4) and the second air channel (5) are sequentially communicated with the inner container assembly (c) or the fog outlet component (1); when the first fan (2) works, external cold air sequentially passes through the first air inlet hole (3), the first fan (2), the first air duct (4) and the second air duct (5) to enter the inner container assembly (c) or the fog outlet component (1) so as to press out hot fog on the fog outlet component (1) to the outside.

2. The heat dissipation structure of a thermal mist humidifier of claim 1, wherein: a first accommodating cavity (6) is formed in the shell component (a), a power supply control board (7) and a second fan (8) are arranged in the first accommodating cavity (6), the second fan (8) is positioned on one side of the power supply control board (7), a second air inlet hole (9) and a first air outlet hole (10) are respectively formed in two sides of the shell component (a), and the second air inlet hole (9), the first accommodating cavity (6) and the first air outlet hole (10) are communicated in sequence; when the second fan (8) works, external cold air enters the first accommodating cavity (6) through the second air inlet hole (9) and is discharged through the first air outlet hole (10) so as to radiate heat of the power supply control board (7).

3. The heat radiation structure of the hot mist humidifier according to claim 2, wherein: a second accommodating cavity (11) is formed in the shell component (a), an electromagnetic heating component (12) is arranged in the second accommodating cavity (11), a power supply control board (7) is electrically connected with the electromagnetic heating component (12), a third fan (13) is arranged in the first accommodating cavity (6), a second air outlet hole (14) is formed in the shell component (a), the air inlet end of the third fan (13) is communicated with the second air inlet hole (9), and the air outlet end of the third fan (13), the second accommodating cavity (11) and the second air outlet hole (14) are sequentially communicated; when the third fan (13) works, external cold air sequentially enters the second accommodating cavity (11) through the second air inlet hole (9) and the first accommodating cavity (6) and is discharged through the second air outlet hole (14) so as to radiate heat of the electromagnetic heating component (12).

4. A heat dissipating structure for a hot mist humidifier according to claim 3, characterized in that: a partition plate (15) is arranged on the shell component (a), the first accommodating cavity (6) and the second accommodating cavity (11) are separated by the partition plate (15), a notch (16) is arranged at one end of the partition plate (15), and the first accommodating cavity (6) and the second accommodating cavity (11) are mutually communicated through the notch (16); when the second fan (8) works, external cold air sequentially enters the second accommodating cavity (11) through the second air inlet hole (9) and the first accommodating cavity (6) and is discharged through the second air outlet hole (14) so as to radiate heat of the electromagnetic heating component (12).

5. The heat dissipation structure of a thermal mist humidifier of claim 1, wherein: the shell assembly (a) comprises an upper shell (17), a middle shell (18) and a lower shell (19), wherein a first mounting groove (17.1) is formed in the upper shell (17), a second mounting groove (18.1) is formed in the middle shell (18), the air outlet end of the first fan (2) is arranged in the first mounting groove (17.1), the air inlet end of the first fan (2) is arranged in the second mounting groove (18.1), the first air duct (4) is arranged at a position, corresponding to the first mounting groove (17.1), on the upper shell (17), and the first air duct (4) is communicated with the first mounting groove (17.1).

6. The heat dissipation structure of a thermal mist humidifier of claim 5, wherein: the upper cover assembly (b) comprises a first cover body (20) and a second cover body (21) which are connected with each other, the second cover body (21) is positioned between the first cover body (20) and the upper shell (17), and the first cover body (20) covers the outer side of the second cover body (21); a groove (21.1) is formed in one side of the second cover body (21), and a second air channel (5) is formed between the groove (21.1) and the inner side wall of the first cover body (20); be provided with installation cavity (22) on second lid (21), go out fog part (1) and install on installation cavity (22), installation cavity (22) one side is provided with first through-hole (23) corresponding to the position of second wind channel (5), goes out fog part (1) one side and is provided with second through-hole (1.1), and second wind channel (5) pass through first through-hole (23) and second through-hole (1.1) intercommunication play fog part (1) in proper order.

7. The heat dissipation structure of a thermal mist humidifier of claim 6, wherein: the position of one side of the upper shell (17) corresponding to the first air duct (4) is provided with a third through hole (17.2), the position of the bottom of the groove (21.1) corresponding to the third through hole (17.2) is provided with a fourth through hole (21.2), and the first air duct (4) is communicated with the second air duct (5) through the third through hole (17.2) and the fourth through hole (21.2) in sequence.

8. The heat dissipation structure of a thermal mist humidifier of claim 5, wherein: a first accommodating cavity (6) is formed between the upper shell (17) and the middle shell (18), the second accommodating cavity (11) is formed in the middle shell (18), the second air outlet hole (14) is formed in the first side (18.2), the second side (18.3) and the third side (18.4) of the middle shell (18) corresponding to the positions of the second accommodating cavity (11), and the first air inlet hole (3) is formed in the first side (18.2) of the middle shell (18) corresponding to the positions of the first fan (2).

9. The heat dissipation structure of a thermal mist humidifier of claim 4, wherein: the second air inlet hole (9), the second fan (8), the power supply control board (7), the third fan (13) and the first air outlet hole (10) are sequentially arranged in a straight line.

10. The heat dissipation structure of a thermal mist humidifier of claim 4, wherein: the hot fog humidifier comprises a water tank (24) and a water pump assembly (d) which are arranged in a shell assembly (a), an electromagnetic heating component (12) is arranged at the bottom of a liner assembly (c), a fog outlet component (1) is arranged at the top of the liner assembly (c), the water tank (24), the water pump assembly (d) and the liner assembly (c) are sequentially communicated, and the liner assembly (c), the fog outlet component (1) and the outside are sequentially communicated; when the hot fog humidifier works, the water pump assembly (d) pumps water in the water tank (24) into the inner container assembly (c), the electromagnetic heating component (12) heats the water in the inner container assembly (c) and generates fog, and the fog is discharged to the outside through the fog outlet component (1).