KR200396749Y1 - Humidifier equipped air-flux guide - Google Patents

Abstract

The present invention relates to a humidifier, which is installed inside the main body to supply and store water, and is installed on one side of the first water tank unit to atomize the water supplied from the first water tank unit to one side of the main body. A heater pipe provided with a second water tank unit for supplying to the side of the spray hole formed therein, and a heat transfer device communicating with the first water tank unit and the second water tank unit and increasing a temperature of water flowing from the first water tank unit to the second water tank unit; An amplifier configured to generate ultrasonic waves to atomize water supplied from the first tank portion, and connected to one side of the amplifier to easily transfer heat generated in the amplifier to air; A heat dissipation fin having a large surface area, a blower fan and a motor installed on one side of the heat dissipation fin to cause air flow, and an air flow generated from the blower fan. And a flow guide for guiding copper through the heat dissipation fin, the heater pipe, and the first water tank part to the spray port to discharge the copper particles together with the atomized water particles.

Description

Air Flow Guide Humidifier {HUMIDIFIER EQUIPPED AIR-FLUX GUIDE}

The present invention relates to a humidifier, and more particularly, by installing a flow guide inside the main body of the humidifier to effectively maintain the wind speed and air volume, to prevent the operation and vibration noise, and to efficiently cool the amplifier to generate ultrasonic waves.

In general, the humidifier is a device that emits moisture to the air in order to control the humidity in the room. Usually, the appropriate humidity is 60% to maintain a comfortable indoor atmosphere. A first water tank unit in which water is supplied from the water tank and a second water tank unit in which an amplifier for atomizing water is installed, and a heater pipe is installed to connect therebetween. A blowing fan and a motor for blowing the spray particles generated from the grandfather and discharging them to the indoor side are installed in the main body.

Here, the water of the first tank portion is heated while passing through the heater pipe, the water flows into the second tank portion, the water warmed in the second tank portion is atomized by the amplifier is formed on one side of the main body It is discharged through the spray hole.

In addition, as the blower fan and the motor inside the main body of the air to spray the spray particles to the indoor side, such a humidifier is sprayed to the room side with the air by the operation of the blower fan and the motor warm spray particles are blown There is a problem that the temperature is dropped by the air is difficult to be warm humidification. In addition, since the blower fan and the motor are simply located inside the main body and are operated to blow air, not only the wind speed and the wind volume are lowered due to friction or leakage with surrounding components, but also the operation noise of the blower fan and the motor. There was a problem that vibration noise is generated.

1 is a perspective view showing a bottom of a humidifier including a conventional air flow guide. As shown in FIG. 1 to improve the above-described problems, the first water tank unit 20 is installed inside the humidifier main body 10 to supply and store water, and the first water tank unit 20 is supplied from the first water tank unit 20. A second water tank unit 30 having a built-in amplifier (not shown) for atomizing water and supplying it to a spray hole (not shown) formed on one side of the main body 10, and the first water tank unit 20 and the second water The heater pipe 40 is installed between the tank 30 and the water of the first tank 20 side is heated while passing through the inside and supplied to the second tank 30, and one side of the heater pipe 40 Is installed in the blower fan 50 and the motor 60 and the blower fan 50 and the heater pipe 40 for blowing the heated air around the heater pipe 40, the heater pipe ( 40) flow guide 70 for guiding the heated air around the spray port (not shown) to be discharged together with the spray particles Although a humidifier including a utility model has been registered (360038), there is a problem that the lifespan and performance of the amplifier (not shown) are rapidly reduced due to failure to adequately cool a lot of heat generated from an amplifier (not shown) that atomizes water. there was.

The present invention for solving the problems described above aims to increase the cooling effect by directly cooling the heat generated by the amplifier at a close distance by using the air generated in the heat sink fin and the blower fan connected to the amplifier. .

In addition, by separately forming a structure that secures the flow path of the air generated by the blowing fan in the body of the humidifier to guide the spray hole to maximize the air flow efficiency while reducing noise and vibration for another purpose.

In addition, another object is to discharge the air heated by the heat radiation fin and the heater pipe together with the spray particles to the room to achieve a warm humidification.

The present invention for achieving the object as described above is installed in the main body and the water supply and storage is installed in the first tank portion, the first water tank is installed on one side to atomize the water supplied from the first tank portion The second water tank unit for supplying to the spray port side formed on one side of the main body, the first water tank unit and the second water tank unit communicates, the heat transfer device for raising the temperature of the water flowing from the first water tank unit to the second water tank unit An installed heater pipe, an amplifier installed at one side of the second tank unit to generate ultrasonic waves to atomize the water supplied from the first tank unit, and connected to one side of the amplifier to heat air generated in the amplifier into the air A heat dissipation fin having a large surface area for easy transmission, a blower fan and a motor installed on one side of the heat dissipation fin to cause air flow, and from the blower fan An air flow guide humidifier comprising a flow guide for guiding the generated air flow to the spray hole through the heat radiating fin, the heater pipe, and the first water tank, and discharged together with the atomized water particles. to be.

In addition, the heat radiation fin is another feature of the present invention to include a connection having a streamlined cross section.

In addition, the heat dissipation fin is another feature of the present invention to include a heat dissipation portion formed with a fin having a large surface area.

In addition, the heat dissipating unit is another feature of the present invention that a plurality of fins are formed.

The flow guide may include a fan case installed to surround the blower fan, a fin case connected to the fan case to surround the heat dissipation fins, and a heater case connected to the fin case to surround the heater pipe. It is another feature of the present invention that the guide cover is connected to the heater case and is provided to be in contact with the spray hole.

In addition, the fan case is characterized in that the fixed end is formed on both sides and screw assembly to a pair of fastening boss formed to protrude downward on one side of the bottom surface of the main body.

In addition, the pin case is characterized in that the fixed end is formed on both sides and the screw assembly to the pair of fastening boss formed to protrude downward on the bottom surface of the second tank portion.

In addition, the heater case is characterized in that the fixing end is formed on both sides and the screw assembly to one fastening boss so as to project downward on the bottom surface of the first tank.

Hereinafter, an embodiment of the present invention constituting the configuration as described above will be described in more detail with reference to the accompanying drawings.

Figure 2 is a plan view showing the bottom surface of the air flow guide humidifier constituting the subject innovation, Figure 3 is a perspective view of the upper surface showing the air flow of the air flow guide humidifier constituting the subject innovation, Figure 4 is an air constituting the subject innovation 5 is a perspective view illustrating the inside of a flow guide of an air flow guide humidifier constituting the present invention, and FIG. 6 is a perspective view of an amplifier and a heat dissipation fin constituting the present invention.

As shown in FIG. 2, the present invention includes a first water tank unit 200, a second water tank unit 300, a heater pipe 400, an amplifier 500, a heat dissipation fin 600, and a blowing fan ( 700 and the motor 800, the flow guide 900 is characterized in that it comprises a.

The first water tank unit 200 is recessed and installed in the main body 100, and receives and stores water from a water tank (not shown). In addition, the first water tank 200 is mounted with a lower end of the water tank (not shown) in close contact.

As shown in FIGS. 3 and 4, the second tank unit 300 is installed at one side of the first tank unit 200 to receive water stored in the first tank unit 200 to be described later. Using the ultrasonic wave generated in), atomize. In addition, the atomized water is supplied to the spray hole 110 formed on one side of the main body 100.

As shown in FIG. 5, the heater pipe 400 communicates with the first water tank unit 200 and the second water tank unit 300 to store water stored in the first water tank unit 200 with the second water tank unit. A connection passage flowing to 300 is provided. In addition, it is usually made of a metal pipe, the heat transfer device is mounted to increase the temperature of the water while the water is flowing. The heating device is usually made of a hot wire.

The amplifier 500 is provided with a main body 510 at the lower end of the second tank 300, and protrudes through a metal part for generating ultrasonic waves to the second tank 300. The main body 510 is connected to a power supply to receive power to generate ultrasonic waves by vibrating a metal to be described later. The metal part (not shown) converts electrical energy transmitted from the body part 510 into vibration energy. Accordingly, the metal part (not shown) vibrates with the frequency of ultrasonic waves and atomizes the water stored in the second water tank part 300.

As shown in FIG. 6, the heat dissipation fin 600 is connected to one side of the amplifier 500 to connect the connection part 610 and the heat dissipation part 620 so as to easily transfer heat generated from the amplifier 500 to the air. Include. The connection part 610 is fixed to one side of the amplifier 500 to receive heat generated from the amplifier 500. In addition, it is usually formed of a metal material having good thermal conductivity. The heat dissipation part 620 is formed of a plurality of fins in the heat connection part and has a large surface area to facilitate heat transfer. In addition, it is usually formed of a metal material having good thermal conductivity, and has a streamlined cross section to smooth air flow. In addition, it is arranged in parallel with the flow direction of the air so that the air flows out smoothly.

As shown in Figure 5, the blowing fan 700 is installed on one side of the heat radiation fin 600 to cause the flow of air. In addition, the motor 800 connected to the blowing fan 700 is connected to a power source to transfer the rotational force to the blowing fan 700.

As shown in FIG. 4, the flow guide 900 includes a fan case 910, a pin case 920, a heater case 930, and a guide cover 940. The fan case 910 is formed to surround the blowing fan 700 and fixed ends are formed at both sides thereof. In addition, the fixed end is screw-assembled to a pair of fastening boss formed to protrude downward on one side of the bottom surface of the main body 100. The pin case 920 is connected to the fan case 910 and is formed to surround the heat dissipation fin 600. In addition, the fixed end is formed on both sides is screw assembled to a pair of fastening boss formed to protrude downward on the bottom surface of the second water tank (300). The heater case 930 is connected to the pin case 920 and formed to surround the heater pipe 400. In addition, the fixed end is formed on one side is screw-assembled to one fastening boss so as to project downward on the bottom surface of the first tank 200. As shown in FIG. 3, the guide cover 940 is formed to be connected to the heater case 930 and to be in contact with the spray hole 110.

Hereinafter, the operation of the present invention constituting the configuration as described above in more detail.

3 and 5, the water supplied from the water tank to the first water tank 200 flows to the second water tank 300 through the heater pipe 400. In addition, the temperature is increased by the heat transfer device while flowing to the second water tank unit 300 through the heater pipe 400. At the same time, the amplifier 500 connected to the second bath 300 converts electrical energy into vibration energy to generate ultrasonic waves in the second bath 300 through the metal. Accordingly, the water stored in the second water tank unit 300 is atomized.

As shown in FIG. 6, heat is generated while the amplifier 500 converts electrical energy into vibration energy, and the generated heat is transferred to the heat dissipation part 620 through the connection part 610. At the same time, as shown in FIG. 5, the motor 800 transmits a rotational force to the blowing fan 700 and a flow of air is generated by the rotation of the blowing fan 700. Air flows along the fan case 910 and the fin case 920 surrounding the blowing fan 700 and the heat dissipating part 620, and receives heat generated by the heat dissipating part 620 in this process. do. In addition, as shown in Figure 6, as the cross-section of the heat dissipation portion 620 is formed in a streamline, the air flow is smooth. At this time, heat is transferred from the heat dissipation unit 620 to the air, and the heat dissipation unit 620 is cooled, and the air is raised in temperature. Accordingly, by effectively cooling the heat generated by the amplifier 500 to extend the life of the amplifier 500 and to maintain the performance.

In addition, as shown in FIGS. 4 and 5, the air flows along the heater case 930 connected to the pin case 920 and surrounding the heater pipe 400. At the same time, the heat generated from the heater pipe 400 is received. At this time, the heat generated from the heater pipe 400 is transferred to the air so that the temperature of the air rises. Finally, as shown in Figure 3, it flows along the guide cover 940 connected to the heater case 930 is discharged to the spray hole (110).

The air whose temperature rises while passing through the heat dissipation unit 620 and the heater pipe 400 is discharged to the spray hole 110 to move the atomized water from the second water tank unit 300 to the outside of the humidifier. The atomized water is discharged. Accordingly, the warm air prevents thermal loss of the atomized particles and decreases the flow loss due to the flow of air according to the flow guide 900, thereby increasing the efficiency of the wind speed and air volume.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person having ordinary skill in the art to which the present invention belongs without departing from the gist of the present invention claimed in the claims, various modifications Of course, such changes are within the scope of the claims.

The present invention by the configuration and operation as described above by directly cooling the heat generated by the amplifier at a close distance by using the heat generated by the heat radiation fin and the blowing fan connected to the amplifier to increase the cooling effect and the life of the amplifier And the effect of maintaining performance.

In addition, by separately forming a structure for securing the flow path of the air generated by the blowing fan in the body of the humidifier to guide the spray hole has the effect of maximizing air flow efficiency and reducing noise and vibration at the same time.

In addition, there is another effect of discharging the air heated in the heat radiation fin and the heater pipe together with the spray particles to the room to make the warm humidification.

1 is a perspective view of a humidifier equipped with a conventional air flow guide.

Figure 2 is a bottom view of the air flow guide humidifier constituting the present invention.

Figure 3 is a perspective view of the air flow guide humidifier constituting the present invention.

Figure 4 is a bottom perspective view of the air flow guide humidifier constituting the present invention.

5 is an internal view of the air flow guide humidifier constituting the present invention.

Figure 6 is a perspective view of the heat dissipation fins constituting the present invention.

<Description of main parts of drawing>

100-body 110-spray ball

200-First water tank 300- Second water tank

400-Heatpipe 500-Amplifier

510-body 600-heat sink

610 connection 620 heat dissipation

700-Blowing Fan 800-Motor

900-Flow Guide 910-Fancase

920-Pincase 930-Heatcase

940-guide cover

Claims (8)

A first water tank unit installed inside the main body to supply and store water; A second water tank unit installed at one side of the first water tank unit to atomize water supplied from the first water tank unit, and to supply to the spray hole formed at one side of the main body; A heater pipe communicating with the first water tank unit and the second water tank unit and configured to raise a temperature of water flowing from the first water tank unit to the second water tank unit; An amplifier installed at one side of the second tank part to generate ultrasonic waves to atomize the water supplied from the first tank part; A heat dissipation fin connected to one side of the amplifier and having a large surface area to easily transfer heat generated from the amplifier to air; A blowing fan and a motor installed at one side of the heat dissipation fin to cause air flow; And a flow guide for guiding the flow of air generated from the blower fan to the spray hole through the heat dissipation fin, the heater pipe, and the first water tank, to be discharged together with the atomized water particles. Air Flow Guide Humidifier. The method of claim 1, The heat radiation fin is an air flow guide humidifier, characterized in that it comprises a connection having a streamlined cross section. The method according to claim 1 or 2, The heat dissipation fin is an air flow guide humidifier, characterized in that it comprises a heat dissipation portion is formed with a wide surface fin. The method of claim 3, The air flow guide humidifier, characterized in that the heat radiating portion is formed with a plurality of fins. The method of claim 1, The flow guide is a fan case installed to surround the blowing fan, A pin case connected to the fan case and installed to surround the heat dissipation fins; A heater case connected to the pin case and installed to surround the heater pipe; An air flow guide humidifier, characterized in that made of a guide cover connected to the heater case and abuts the spray hole. The method of claim 5, The fan case is fixed air is formed on both sides and the air flow guide humidifier, characterized in that the screw is assembled to a pair of fastening boss formed to protrude downward on one side of the bottom surface of the main body. The method of claim 5, The pin case has a fixed end is formed on both sides of the air flow guide humidifier, characterized in that the screw assembly to a pair of fastening boss formed to protrude downward on the bottom surface of the second tank. The method of claim 5, The heater case is a fixed end is formed on one side air flow guide humidifier, characterized in that the screw is assembled to one fastening boss so as to project downward on the bottom surface of the first tank.