JPH10318570A - Humidifier using heater and ultrasonic wave - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use multi-functions by providing a first water reservoir for storing water supplied from a water in a heater, providing a heater at its bottom, providing a second water reservoir for storing water from the first reservoir, and providing a vibrator for generating ultrasonic wave at its bottom. SOLUTION: When using a heater type humidifier or ultrasonic type humidifier and operating as the heater type humidifier by selecting a switch, a motor and a heater 322 are energized to supply water in a water tank 316 to a first water reservoir 324 via a valve 318, and to heat the water to boil it. Generated stem is discharged from a scavenging port 380 via a atomizing liquid tube 370 along an air flow from a supply fan 390. Meanwhile, in the case of using it as the ultrasonic type humidifier, the water in the reservoir 324 is supplied to a second water reservoir 334 via a valve assembly 324 opened due to the fact that a temperature of water is relatively low, and atomizing liquid is generated by the ultrasonic wave generated by vibration of a vibrator.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a humidifier, and more particularly, to a heater and an ultrasonic humidifier.

[0002]

2. Description of the Related Art A humidifier is a device for maintaining a constant humidity in a room by atomizing a liquid and supplying the atomized liquid to the room.
Generally, a humidifier is a heater type humidifier that heats water stored in a water tank to a predetermined temperature and sprays the generated atomized liquid into a room, and vibrates the water stored in the water tank with ultrasonic waves. It is classified by the ultrasonic humidifier that sprays the generated atomized liquid into the room.

[0003] The heater type humidifier consumes much energy for heating the water by heating the water stored in the water storage tank with a heater, and the ultrasonic humidifier stores the water in the water storage tank. By vibrating the generated water by ultrasonic waves, less energy is consumed as compared with the heater type humidifier. However, in the case of the ultrasonic humidifier, when the water in the water tank is stored for a long time, bacteria grow,
When the bacteria are sprayed into a room, there is a problem for a human body.

Accordingly, a heating type ultrasonic humidifier in which a heater is attached to the above-mentioned ultrasonic humidifier has been disclosed in order to reduce energy loss and enhance a sterilizing effect.

[0005] An example of such a conventional humidifier is Minaru Ta.
No. 5,176,856 to Kahashi et al.

As shown in FIG. 1, a humidifier 100 includes a housing 110, a water tub 120 mounted on an upper portion of the housing, and a water tub 12 positioned at a lower portion of the water tub 120.
A water tank 130 to which water is supplied and stored from 0, and a heater / vibrator assembly 1 attached to a lower part of the water tank 130
40, attached to the inner bottom of the housing 110,
The blower fan assembly 170 for sending out air, the water storage tank 1
Spray port 180 for guiding the atomized liquid generated in 30 to the outside
It consists of.

At the bottom of the water tub 120, the water tub 120
Is released when is seated on the housing 110,
A valve 122 is installed that is closed when the water tub 120 is removed from the housing 110. The water tank 130 stores water supplied from the water tank 120 through the valve 122. The heater / vibrator assembly 140 is fixed to a lower portion of the water tank 130 and vibrates or heats water. The heater / vibrator assembly 140
When water vibrates, a water column 132 is formed on the water surface, and the water in the water column 132 is atomized. The atomized particles pass through the spray port 180 to the humidifier 10.
Sprayed outside of 0.

[0008] The blower fan assembly 170 sends out the air sucked through an air suction hole 112 formed at one side of the housing 110 in the direction of the arrow 111, and the sent air is generated from the water storage tank 130. Fine particles are sprayed outside the humidifier 100.

FIG. 2 shows a heater / vibrator assembly 140. As shown in FIG. 2, the water storage tank 130 has a rectangular opening 134 formed at the bottom thereof, and a frame 142 is attached to a lower portion of the opening 134.

[0010] The frame 142 has a square shape,
It is composed of a plastic material. The frame 142
A hole (not shown) is formed at each edge of the frame to fix the frame 142 to the water tank 130. The square frame 142 has an upper plate 141
The upper plate 141 has a circular opening (not shown). A first circular groove 144 is formed on the inner peripheral surface of the circular opening 146 along the inner peripheral surface, and the outer peripheral surface of the circular conductive piece 148 is inserted into the first circular groove 144. The conductive piece 148 is made of a material such as copper or aluminum, and transfers heat generated by the heater 160 to water.

On the other hand, a holder 150 is attached to the upper center of the frame 140. A vibrator 154 is mounted inside the holder 150, and the holder 15
Numeral 0 is made of a non-conductive material, and prevents heat generated from the conductive piece 148 from being radiated to the vibrator 154.

A second circular groove 152 is formed on the outer peripheral surface of the holder 150 along the outer peripheral surface. Therefore, the inner peripheral surface of the conductive piece 148 is inserted into the second circular groove 152. As a result, the upper plate 141 and the conductive piece 14
8. The holder 150 and the vibrator 154 are assembled integrally.

The vibrator 154 is in contact with water, and has a first electrode 156 mounted on a bottom surface of the vibrator 154 and a second electrode 156 located below the first electrode 156 and having a smaller diameter than the first electrode 156. An electrode 158 is provided. An electrode 155 for supplying power to the vibrator 154 is provided below the vibrator 154.

The heater 160 has a ring shape and is divided into two parts based on the center. Since the heaters 160 are provided on the rear surface of the conductive piece 148, the heaters 160 do not directly contact the water stored in the water storage tank 130. The pair of heaters 160 are T. C (P
ositive Temperature Coeffcient Cerimics Heater) type heater is used. The P.S. T. The temperature of the C-type heater is automatically adjusted without requiring another external temperature controller.

The pair of heaters 160 includes a pair of electrodes (not shown) for supplying power to the heater 160. A heat shield plate 16 is provided below the pair of heaters 160.
4 to prevent heat generated from the pair of heaters 160 from being radiated to the circuit 166.

A lower plate 168 is provided below the frame 142, and the heater 160 and the vibrator 1
It supports a circuit that supplies power to 54. The frame 1
Walls (not shown) are formed on the four surfaces of 42.

The frame 142 is attached to the bottom of the water tank 130. A water discharging member 169 is attached between the bottom surface of the water storage tank 130 and the frame 142 to prevent water stored in the water storage tank 130 from leaking to the outside.

Power is supplied to the humidifier 100, the pair of heaters 160 is electrically heated, and the vibrator 154 vibrates at the same time. At this time, the pair of heaters 16
0 is transmitted to the conductive piece 148.
Accordingly, the temperature of the water stored in the water storage tank 130 is increased, and bacteria in the water storage tank 130 are sterilized.

The water heated as described above is supplied to the vibrator 1
It becomes an atomized liquid by the vibration of 54. At this time, since the atomized liquid is in a sterilized state at a predetermined temperature,
The humidifier 100 supplies sterilized atomized liquid to the room.

[0020]

However, the conventional humidifier as described above has a problem that it is difficult to appropriately adjust the atomized liquid supplied to the room according to the indoor environment.

Accordingly, the present invention is to solve the above-mentioned problems of the prior art, and an object of the present invention is to provide a multifunctional humidifier.

[0022]

SUMMARY OF THE INVENTION The present invention for achieving the above object has a main body, and is mounted inside the main body,
A water trough for storing water, a heater connected to the water trough by a first flow path, storing and heating water flowing through the first flow path to generate a first atomized liquid; An ultrasonic unit that is connected by two flow paths and vibrates water to generate a second atomized liquid, and is disposed between the heater and the ultrasonic unit. A valve assembly for selectively shutting off a flow of water flowing from the heater section to the ultrasonic section, and a first section for operating the heater section
A humidifier comprising: a switch for selecting a mode, a second mode for operating the ultrasonic unit, and a third mode for simultaneously operating the heater and the ultrasonic unit.

According to the present invention, the heater unit includes a first water tank for storing water supplied from the water tank, and a heater attached to a bottom of the first water tank to generate heat. The ultrasonic unit includes a second water tank for storing water supplied from the first water tank and a vibrator attached to a bottom of the second water tank to generate ultrasonic waves.

The second flow path is formed above a partition formed between the first and second water storage tanks, and the valve assembly is mounted inside the second flow path.

The valve assembly according to the first embodiment of the present invention has a tetrahedral housing, an inlet formed in a first side wall of the housing, and into which water of the first water tank flows,
An outlet formed on a second side wall opposite to the first side wall to discharge water into the second water storage tank, a spring member attached to the first side wall of the housing,
A first valve is integrally connected to the spring member. The spring member includes a coil spring made of a shape memory alloy. A first end of the coil spring is integrally connected to one side of the first valve;
A second end opposite to the first end is fixed to a groove formed in a first side wall of the housing,
By contracting and expanding due to the temperature of the groove in the water tank,
The first valve opens and closes the outlet.

The coil spring expands when the temperature of water stored in the first water storage tank is higher than a predetermined temperature, and a first valve connected to a first end of the coil spring closes the outlet. By doing so, water is prevented from flowing from the first water storage tank to the second water storage tank, and when the temperature of the water is equal to or lower than a predetermined temperature, the water contracts and the second water storage tank is connected to the first end of the spring. When one valve opens the outlet, water flows from the first water storage tank to the second water storage tank. Generally, the predetermined temperature is 70-75 ° C.

A valve assembly according to a second embodiment of the present invention is provided. The valve assembly is formed in a tetrahedral housing, formed in a first side wall of the housing, an inlet through which water in the first water reservoir flows, and a second side wall located in a direction opposite to the first side wall. An outlet for discharging water into the second water storage tank, a bellows attached to the first side wall of the housing, and a valve assembly including a first valve integrally connected to the bellows. The bellows is made of a thin metal plate, in which an ether solution is sealed.

[0028] A first end of the bellows is integrally connected to one side of the first valve, and a second end opposite to the first end is fixed to a first side wall of the housing. The first valve opens and closes the outlet by contracting and expanding according to the temperature of the water in the first storage tank.

The bellows expands when the temperature of the water stored in the first water reservoir is higher than a predetermined temperature, and the first valve connected to the first end of the bellows closes the outlet. Thereby, water is prevented from flowing from the first water storage tank to the second water storage tank, and when the temperature of the water is equal to or lower than a predetermined temperature, the first water storage tank contracts and is connected to the first end of the bellows. When the valve opens the outlet, water flows from the first water tank to the second water tank.
The bellows is filled with alcohol, and expands and contracts depending on temperature.

A valve assembly according to a third embodiment of the present invention is provided. The valve assembly is formed in a tetrahedral housing, an inlet formed in a first side wall of the housing, through which water in the first water reservoir flows, and a second wall located in a direction opposite to the first side wall. The housing comprises an outlet for discharging water into the second water storage tank, a cylinder assembly attached to the first side wall of the housing, and a first valve integrally connected to the cylinder assembly.

The cylinder assembly is a sealed cylindrical cylinder having one end fixed to a first side wall of the housing, and is slidably mounted inside the cylinder. One end of the cylinder assembly is connected to the first valve. A piston is integrally connected, and includes a tension spring mounted inside the cylinder and biasing the piston against a first side wall of the housing.

Wax is injected into the cylinder to urge the piston toward the second side wall of the housing when the temperature rises.

The cylinder expands when the temperature of water stored in the first water storage tank is higher than a predetermined temperature, and a first valve connected to a first end of the cylinder closes the outlet. As a result, water is transferred from the first water tank to the second water tank.
The first valve connected to the first end of the cylinder opens to open the outlet when the water is prevented from flowing into the water storage tank and the temperature of the water is equal to or lower than a predetermined temperature. Water flows from the first water reservoir to the second water reservoir.

The switch unit includes a switch for cross-selecting a first mode, a second mode, and a third mode, and a circuit connected to the switch for selectively operating the heater unit and the ultrasonic unit. .

[0035]

The humidifier according to the present invention having such a configuration can be used in a heater humidifier and an ultrasonic humidifier by selecting the switch. First, when the switch is set to the third mode, power is transmitted to the heater, the heater is heated, and the water stored in the first water storage tank boils. The heated water flows into the valve assembly. At this time, the water temperature is 75 ° C
Is maintained in. The coil spring of the valve assembly expands when the temperature of the water in the first water reservoir is higher than a predetermined temperature, preferably 70-75 ° C. Accordingly, the first valve connected to the first end of the coil spring closes the outlet of the valve assembly, thereby preventing water from flowing from the first water reservoir to the second water reservoir. I do. The temperature of the water is a predetermined temperature, preferably 70-7
When the temperature is not more than 5 ° C., the coil spring contracts and the first valve opens the outlet, so that water flows from the first water storage tank to the second water storage tank. Ultrasonic waves generated by the vibration of the vibrator vibrate water in the second water storage tank to generate an atomized liquid. Therefore, the sterilized atomized liquid which is not bad for the human body is supplied into the room.

By selecting the switch, the humidifier can be used as a heater humidifier and an ultrasonic humidifier. When the switch is set to the first mode, the heater operates and the water in the first water tank boils. Therefore, the generated atomized liquid is sprayed to the outside through the atomized liquid pipe.

When the user switches the switch from the first mode to the second mode, power supplied to the heater is cut off and supplied to the transducer of the ultrasonic unit. Accordingly, the heater is cooled, the temperature of the water stored in the first water storage tank decreases, and the valve is opened again. Therefore, the water in the first water tank flows into the second water tank.
Ultrasonic waves generated by the vibrator vibrate water stored in the second water storage tank. Therefore, an atomized liquid is generated on the water surface of the second water storage tank, and the atomized liquid is sprayed to the outside through the atomized liquid pipe.

At this time, when the user switches the switch from the second mode to the first mode again, power supplied to the vibrator is cut off, and power is supplied to the heater of the heater unit. . Therefore, the heater is heated again and the water stored in the first water storage tank is boiled. The atomized liquid generated from the first water storage tank is sprayed outside through the atomized liquid pipe.

The humidifier may be a heater humidifier, an ultrasonic humidifier, and a heater, depending on the indoor environment, by a temperature-sensitive valve assembly incorporating a shape memory alloy or other thermally expandable medium. And there is an advantage that it can be used in an ultrasonic humidifier.

The above objects and other features and advantages of the present invention will become apparent from the following description of some preferred embodiments of the present invention to which reference is now made.

[0041]

Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. FIG. 3 is a sectional view showing the structure of the humidifier according to the present invention. FIG. 4 is a plan view of a humidifier according to the present invention. As shown in FIGS. 3 and 4, the humidifier 300 includes a housing 305, a water trough 310 located at an upper portion inside the housing 305, and is connected to the water trough 310 to supply water supplied from the water trough 310. A heater unit 320 that generates an atomized liquid by heating; an ultrasonic unit 330 that is connected to the heater unit 320 by a second flow path 328 and vibrates water supplied from the heater unit 320 to generate an atomized liquid; A valve assembly 340 attached to the inside of the second flow path 328 formed between the heater unit 320 and the ultrasonic unit 330, and atomized liquid generated from the heater unit 320 and the ultrasonic unit 330 are removed. Blower fan assembly 3 for sending air for sending outside
90, an atomizing liquid pipe 370 for spraying the atomizing liquid to the outside of the humidifier 300, a first mode 397 for operating the heater unit 320, a second mode 399 for operating the ultrasonic unit 330, and a heater. 320 and ultrasonic unit 33
It comprises a switch unit 395 having a third mode 398 for selecting 0 in a crossover manner.

The water trough 310 has a protrusion 31 on its bottom surface.
2, a hole 314 is formed at the center of the protrusion 312. A water trough 316 is attached to the water trough 310 so as to be freely attached.
A valve 318 is attached to the bottom surface of. The water trough 3
When the water tank 16 is attached to the water trough 310, the valve 318 of the water trough 316 is
14 through. At this time, the lower end of the valve 318 contacts a protruding protrusion 319 formed to protrude upward at a position corresponding to the lower end. Therefore, the valve 318 of the water trough 316 contacts the upper end of the protrusion 319 and is opened.

The heater section 320 is connected to the water trough section 310 by a first flow path 321, and water stored in the water trough 316 passes through the first flow path 321 to form the heater section 3.
20. The heater unit 320 includes a first water storage tank 324 for storing water, and a heater 322 attached to the bottom of the first water storage tank 324 to generate heat.

The ultrasonic section 330 includes the heater section 32.
A second water storage tank 334 for storing water supplied from 0, and a vibrator 332 attached to the bottom of the second water storage tank 334 to vibrate water are provided.

The heater section 320 and the ultrasonic section 330
The second flow path 328 is formed between the second flow path and the water, and the water stored in the heater unit 320 flows to the ultrasonic unit 330 through the second flow path 328. A valve assembly 34 for controlling the flow of the water is provided inside the second flow path 328.
0 is attached.

FIG. 5 shows the valve assembly 340 according to the first embodiment of the present invention in detail. As shown in FIG. 5, the valve assembly 340 is formed on a tetrahedral housing 342 and a first side wall 343 of the housing 342 so that the water of the first water storage tank 324 flows into the housing 342. An inlet 344 is formed in the second side wall 345 opposite to the first side wall 343, and the second water storage tank 33
4, an outlet 346 for supplying water to the housing 4
Spring 3 attached to the first side wall 343 of FIG.
48, a first valve 349 integrally connected to a first end 347 of the coil spring 348.

The outer wall surfaces 35 on both sides of the housing 342
At 0, a projection 352 projecting outward from the outer wall surface 350 is formed. The protrusion 352 is coupled to a groove 327 formed on an inner wall surface 329 of the second flow path 328. Therefore, the valve assembly 340 is connected to the second
It is fixed inside the flow path 328.

The inflow port 344 is connected to the first water storage tank 324.
The water stored in the first water storage tank 324 flows into the valve assembly 340 through the inflow port 344. The outlet 346 communicates with the second water storage tank 334, and water that has passed through the valve assembly 340 flows out to the second water storage tank 334.

The coil spring 348 is made of a shape memory alloy component. The first valve 349 is integrally connected to a first end 347 of the coil spring 348, and a second end 353 opposite to the first end 347 is connected to a first side wall 343 of the housing 342. It is fixed to a groove 354 formed in the inner surface 353.

The coil spring 348 of the valve assembly 340 expands when the temperature of the water in the first water storage tank 324 is higher than a predetermined temperature, preferably 70-75 ° C. Accordingly, the first end 3 of the coil spring 348
The first valve 349 connected to 47 closes the outlet 346 of the valve assembly 340 to prevent water from flowing to the second water reservoir 334 in the first water reservoir 324. When the temperature of the water is a predetermined temperature, preferably 70-75 ° C. or less, the coil spring 3
When the first valve 349 connected to the first end of the coil spring 348 opens the outflow port 346, the water is compressed in the first water storage tank 324 and the second
It flows to the water storage tank 334.

Referring again to FIGS. 3 and 4, the water flowing through the second flow path 328 is stored in the second water storage tank 334 of the ultrasonic unit 330. The second water storage tank 334
The vibrator 332 attached to the bottom surface of the device generates an ultrasonic wave by vibrating when power is supplied.

The generated ultrasonic wave is transmitted to the second water tank 3
The water is transmitted to the water stored in the storage tank and generates an atomized liquid on the surface of the water.

The atomizing liquid pipe 370 is connected to the first and second liquid pipes.
It is attached to the upper part of the water storage tanks 324 and 334, and is attached vertically to the bottom part 307 of the housing 305, and is a hollow tube.

The atomized liquid generated from the first and second water storage tanks 324 and 334 is sprayed to the outside of the humidifier 300 through the atomized liquid pipe 370. The atomized liquid pipe 3
Reference numeral 70 denotes a first end 372 corresponding to the heater unit 320 and the ultrasonic unit 330, into which the nebulized liquid is sucked, and located in a direction opposite to the first end 372 and guided through the nebulized liquid pipe 370. A second end 374 is integrally connected to a discharge port 380 for spraying the atomized liquid to the outside.

On the other hand, the blower fan assembly 390 is attached to the bottom 307 of the housing 305. Air sucked through a suction hole 308 formed in a rear wall 309 of the housing 305 is sent out by the sending fan assembly 390, and the sent air sends the atomized liquid to the outside through the atomized liquid pipe 370. Spray.

The switch 395 is connected to the housing 30
5 is attached to the rear wall surface 309. Referring to FIGS. 3 and 8, the switch 395 is a first mode 397 for using the humidifier 300 as a heater type humidifier, and a second mode for using the humidifier 300 as an ultrasonic type humidifier. 399, and a third mode 398 for using the humidifier 300 as a heater and an ultrasonic humidifier. When the switch 395 is set to the first mode 397, the heater 322 of the heater unit 320 is operated. When the switch 395 is set to the second mode 399, the vibrator 332 of the ultrasonic unit 330 is operated. When the switch 395 is set to the third mode 398, the heater 322 and the vibrator 332 operate simultaneously.

FIG. 6 shows a valve assembly 440 according to a second embodiment of the present invention. As shown in FIG. 6, the valve assembly 440 has a tetrahedral housing 442 and is formed on a first side wall 443 of the housing 442 so that the water in the first water storage tank 324 flows into the housing 442. An inlet 444, an outlet 446 formed on the second side wall 445 opposite to the first side wall 443 to supply water to the second water storage tank 334, and a bellows 448 attached to the first side wall 443 of the housing 442. And a first valve 449 integrally connected to a first end 447 of the bellows 448.

Outer wall surfaces 45 on both sides of the housing 442
The protrusions 452 protruding outward from the outer wall surface 450 are formed on the outer wall surface 450, respectively. The protrusion 452 is coupled to a groove 327 formed on an inner wall surface 329 of the second flow path 328. Accordingly, the valve assembly 440 is fixed inside the second flow path 328.

The inflow port 444 is connected to the first water storage tank 324.
The water stored in the first water storage tank 324 flows into the valve assembly 440 through the inlet 444. The outflow port 446 is connected to the second water storage tank 334.
The water passing through the valve assembly 440 is discharged to the second water storage tank 334.

The bellows 448 is made of a thin metal plate, into which ether and alcohol sensitive to temperature change are injected. First end 44 of the bellows 448
7, the first valve 449 is integrally connected, and a second end 453 opposite to the first end 447 is provided with a foot 454 having a predetermined length. The foot 45
4 is the first member of the housing 442 by the fixing member 455.
The bellows 448 is fixed to the housing 442 by being fixed to the inner surface of the side wall 443. The ether and alcohol increase in bulk as the temperature increases,
There is a characteristic that the bulk decreases as the temperature decreases.

Accordingly, the bellows 448 can contract and expand according to the temperature of the water flowing through the inlet 444. As a result, the second valve 449 also moves left and right due to the contraction and expansion of the bellows 448, and opens and closes the outlet 446.

FIG. 7 shows a valve assembly 540 according to a third embodiment of the present invention. As shown in FIG. 7, the valve assembly 540 is formed on a tetrahedral housing 542 and a first side wall 543 of the housing 542, and water in the first water storage tank 324 flows into the housing 542. An inlet 544, an outlet 546 formed on a second side wall 545 opposite to the first side wall 543 to supply water to the second water storage tank 334, and a cylinder attached to the first side wall 543 of the housing 542. Assembly 548,
A first valve 549 is integrally connected to the cylinder assembly 548.

The outer wall surfaces 55 on both sides of the housing 542
The projections 552 protruding outward from the outer wall surface 550 are formed on the outer wall 550, respectively. The protrusion 552 is formed in a groove 327 formed on an inner wall surface 329 of the second flow path 328.
Is combined with Accordingly, the valve assembly 540 is fixed inside the second flow path 328.

The inflow port 544 is connected to the first water storage tank 324.
The water stored in the first water storage tank 324 flows into the valve assembly 540 through the inlet 544. The outlet 546 is connected to the second water storage tank 33.
4, the water that has passed through the valve assembly 540 flows out to the second water storage tank 334.

The cylinder assembly 548 includes a closed cylindrical cylinder 569, a piston 556 slidably mounted inside the cylinder 569, and the cylinder 5
The tension spring 558 is located inside the housing 69 and biases the piston 556 toward the first side wall 543 of the housing 542.

A foot 557 is formed at the first end 560 of the cylinder 569, and the foot 557 is
9 is integrally fixed to the first side wall 543. A through hole 564 is formed at the center of the second end 562 opposite to the first end 560.

The first end 547 of the piston 556 protrudes outside the cylinder 569 through the through hole 564, and the first valve 549 is integrally connected to the first end of the piston 556. The first end 54
7, a circular plate 566 is integrally connected to the second end 568 located in the opposite direction. The circular plate 566
A tension spring 558 is mounted in a first internal space 551 between the first inner space 551 and the second end 562 of the cylinder 548 to urge the circular plate 566 toward the first end 547 of the cylinder 548.

On the other hand, the second internal space 55 between the circular plate 566 and the first end 560 of the cylinder 569
A wax sensitive to temperature change is injected into 3. The wax increases in bulk when the temperature increases above a predetermined temperature,
When the temperature is lower than a predetermined temperature, there is a characteristic that the bulk is reduced.

Accordingly, the cylinder assembly 548 can contract and expand according to the temperature of the water flowing through the inlet 544. Accordingly, the cylinder assembly 548
The first valve 549 integrally connected to the first valve 549 is also moved right and left, and the first valve 549 opens and closes the outlet 546.

Hereinafter, the operation of the humidifier according to the first embodiment of the present invention will be described. As shown in FIGS. 3 and 4, the water trough 316 is attached to the water trough 310. One end of the valve 318 attached to the bottom of the water trough 316 contacts the protrusion 319, and the valve 318 moves upward. At this time, the water stored in the water trough 316 passes through the opened valve 318 to form the water trough 31.
0 is fed to the bottom. The supplied water passes through the first flow path 321 and passes through the first water storage tank 3 of the heater unit 320.
24. When a predetermined amount of water is stored in the first water storage tank 324, the water flows to the second water storage tank 334 of the ultrasonic unit 330 through the valve 340.

The humidifier 300 can be used as a heater humidifier, an ultrasonic humidifier, and a heater / ultrasonic humidifier by selecting the switch 395.
First, when the switch 395 is set to the third mode 398, a signal is transmitted to the circuit, and power is transmitted to the heater 322 by the signal. Therefore, the heater 3
22 is heated, and the water stored in the first water storage tank 324 boils. The heated water flows into the valve assembly 340. At this time, the water temperature is 75 ° C
Is maintained in.

Referring to FIG. 5, the valve assembly 34
The coil spring 348 of the first water storage tank 32
When the temperature of the water of No. 4 is a predetermined temperature, preferably 70-75 ° C or more, the water expands. Therefore, the coil spring 3
48 closes the outlet 346 of the valve assembly 340 so that water is stored in the first water reservoir 324 and the second water reservoir 33.
4 is prevented from flowing. The temperature of the water is a predetermined temperature,
Preferably, when the temperature is lower than 70-75 ° C., the coil spring 348 contracts and the first valve 349 connected to the first end of the coil spring 348 is connected to the outlet 3.
By opening the first water tank 324,
Flows into the second water storage tank 334. Again, FIGS. 3 and 4
Referring to, the water boiled in the first water reservoir 324 flows to the second water reservoir 334 through the valve assembly 340 and is cooled in the second water reservoir 334. The ultrasonic waves generated by the vibration of the vibrator 332 are transmitted to the second water storage tank 3.
The water of 34 is vibrated to generate an atomized liquid. Therefore, the sterilized atomized liquid which is not bad for the human body is supplied into the room.

The user can select the first mode or the second mode from among the third modes.

When the switch 395 is set to the first mode 397, the signal of the switch 395 is transmitted to the circuit, and the power is transmitted to the heater 322 by the signal. Therefore, the heater 322 is heated and the first
The water stored in the water storage tank 324 boils to generate an atomized liquid.

Referring to FIG. 5, the valve assembly 34
The coil spring 348 of the first water storage tank 32
When the temperature of the water of No. 4 is a predetermined temperature, preferably 70-75 ° C. or more, the water expands. Accordingly, when the first valve 349 connected to the first end of the coil spring 348 closes the outlet 346 of the valve assembly 340, water flows from the first water reservoir 324 to the second water reservoir. 334. Therefore, referring to FIGS. 3 and 4 again, the atomized liquid is supplied to the atomized liquid pipe 370.
And is sprayed to the outside of the humidifier 300 through the discharge port 380.

Also, the bacteria in the first water storage tank 324 are sterilized by boiling the water in the first water storage tank 324.
Therefore, the atomized liquid that is not bad for the human body can be supplied to the room.

When the switch 395 is switched from the first mode 397 to the second mode 399, the heater 322
The power transmitted to the ultrasonic unit 330 is cut off,
It is supplied to the vibrator 332 of the water storage tank 334. Accordingly, the heater 322 is cooled, the temperature of the water stored in the first water storage tank 324 decreases, and the valve assembly 340 is opened again. Therefore, the water in the first water storage tank 324 flows to the second water storage tank 334. The vibrator 332 vibrates to generate ultrasonic waves, and the ultrasonic waves are transmitted to the second water storage tank 3.
The water stored in 34 is vibrated. Therefore, atomized liquid is generated on the water surface of the second water storage tank 334. The atomized liquid is sucked into the atomized liquid pipe 370, and the
It is sprayed to the outside of the humidifier 300 through 80.

At this time, when the user switches the switch 395 to the first mode 397 again in the second mode 399, the power supplied to the vibrator 332 is cut off and the heater 322 of the heater section 320 is turned off. Is supplied with power. Accordingly, the heater 322 is heated again to generate heat, and the water stored in the first water storage tank 324 boils. The temperature of the water rises to a predetermined temperature, preferably 70-75 ° C., and the opened valve assembly 340 is closed again. An atomized liquid is generated from the boiled water, and the atomized liquid is sucked into the atomized liquid pipe 370 and sprayed to the outside of the humidifier 300 through the discharge port 380.

The humidifier 300 according to the second embodiment of the present invention is the same as the humidifier 300 according to the first embodiment of the present invention, except that all the components except for the coil spring 348 of the valve assembly 340 are the same. In the example, description of parts other than the coil spring 348 will be omitted.

Referring to FIG. 6, the bellows 44
8 expands when the temperature of the water in the first water storage tank 324 is a predetermined temperature, preferably 70-75 ° C. or more. Therefore,
A first valve 449 connected to a first end of the bellows 448 closes the outlet 446 of the valve assembly 440, so that water flows from the first water reservoir 324 to the second water reservoir 334. To prevent that. When the temperature of the water is below a predetermined temperature, preferably 70-75 ° C., the bellows 448 contracts and the first valve 449 connected to the first end of the bellows 448 opens the outlet 446. As a result, the water is stored in the first water tank 3
At 24, it flows into the second water storage tank 334.

The humidifier 300 according to the third embodiment of the present invention is the same as the humidifier 300 according to the first embodiment of the present invention, except that all components except the coil spring 348 of the valve assembly 340 are the same. In the example, description of parts other than the coil spring 348 will be omitted.

Referring to FIG. 7, when the temperature of the water in the first water storage tank 324 is higher than a predetermined temperature, preferably 70-75 ° C., the wax injected into the cylinder assembly 548 expands. I do. Accordingly, the first valve 549 connected to the first end of the piston 556 closes the outlet 546 of the valve assembly 540, so that water is stored in the first water reservoir 324 and the second water reservoir 334. To prevent flowing. When the temperature of the water is below a predetermined temperature, preferably 70-75 ° C., the cylinder assembly 548 contracts and the first valve 549 connected to the first end of the piston 556 connects the outlet 54.
By opening 6, water flows from the first water reservoir 324 to the second water reservoir 334.

[0083]

As described above, the humidifier is a temperature responsive valve assembly incorporating a shape memory alloy or other thermally expandable medium, and one humidifier is a heater type humidifier depending on the indoor environment. There is an advantage that it can be used in an ultrasonic humidifier, and a heater and an ultrasonic humidifier.

Although the present invention has been described in detail with reference to the embodiments, the present invention is not limited to the embodiments, and any person having ordinary knowledge in the technical field to which the present invention belongs may depart from the spirit and spirit of the present invention. Rather, the invention could be modified or changed.

[Brief description of the drawings]

FIG. 1 is a sectional view schematically showing a structure of a conventional humidifier.

FIG. 2 is a cross-sectional view showing that a heater / vibrator assembly of a conventional humidifier is attached to a bottom of a water storage tank.

FIG. 3 is a sectional view showing the structure of a humidifier according to the present invention.

FIG. 4 is a plan view of a humidifier according to the present invention.

FIG. 5 is a detailed sectional view showing a coil spring of the valve assembly according to the first embodiment of the present invention in detail.

FIG. 6 is a sectional view showing a bellows of a valve according to a second embodiment of the present invention in detail;

FIG. 7 is a sectional view showing a cylinder of a valve according to a third embodiment of the present invention in detail.

FIG. 8 is a plan view showing a switch of the humidifier according to the present invention.

[Explanation of symbols]

 300 Humidifier 305 Housing 310 Water trough 312 Projection 314 Hole 316 Water trough 318 Valve 319 Projection protrusion 320 Heater part 321 First flow path 322 Heater 328 Second flow path 330 Ultrasonic wave part 332 Vibrator 334 Second water storage tank 340 Valve set Solid 370 Atomized liquid tube 390 Blower fan assembly 395 Switch unit 397 First mode 398 Third mode 399 Second mode

Claims (18)

[Claims] A main body, a water tub attached to the inside of the main body for storing water, connected to the water tub by a first flow path, and storing and heating water flowing through the first flow path. 1st means for generating 1 atomized liquid, 2nd means connected to the 1st means by the 2nd flow path, and generating the 2nd atomized liquid by oscillating water, 1st and 2nd means A third means disposed between the first means for contracting and expanding according to the temperature of water to selectively block a flow of water flowing from the first means to the second means; and a first means for operating the first means. A humidifier, comprising: a fourth mode for selecting a mode, a second mode for operating the second means, and a third mode for simultaneously operating the first and second means. 2. The apparatus according to claim 1, wherein the first means includes a first water storage tank for storing water supplied from the water tank, and a heater attached to a bottom of the first water storage tank to generate heat. The humidifier according to the above. 3. The second means includes a second water storage tank for storing water overflowing from the first water storage tank, and a vibrator attached to a bottom of the second water storage tank to generate ultrasonic waves. The humidifier according to claim 2. 4. The method according to claim 1, wherein the second flow path is formed above a partition formed between the first and second water storage tanks, and the third means is mounted inside the second flow path. The humidifier according to claim 1, wherein: 5. The third means is located in a tetrahedral housing, an inlet formed in a first side wall of the housing, through which water in the first water reservoir flows, and opposite to the first side wall. An outlet formed on the second side wall to discharge water into the second water storage tank, a spring member attached to the first side wall of the housing, and a first valve integrally connected to the spring member. The humidifier according to claim 4, further comprising a valve assembly. 6. The humidifier according to claim 5, wherein the spring member is a coil spring made of a shape memory alloy. 7. A first end of the coil spring is integrally connected to one side of the first valve, and a second end opposite to the first end is connected to a first side wall of the housing. The humidifier according to claim 6, wherein the first valve opens and closes the outlet by being fixed to the formed groove and contracting and expanding according to the temperature of the groove of the first water storage tank. vessel. 8. The coil spring expands when the temperature of water stored in the first water storage tank is equal to or higher than a predetermined temperature, and a first valve connected to a first end of the coil spring is connected to the outlet. By closing the water,
A first valve connected to a first end of the spring opens the outlet when the temperature of the water is lower than a predetermined temperature, preventing the water from flowing from the water storage tank to the second water storage tank. The humidifier according to claim 7, wherein water flows from the first water storage tank to the second water storage tank. 9. The third means includes a tetrahedral housing, an inlet formed in a first side wall of the housing, through which water in the first water reservoir flows, and a third side located in a direction opposite to the first side wall. A valve assembly formed on two side walls and configured to include an outlet for discharging water into the second water storage tank, a bellows attached to the first side wall of the housing, and a first valve integrally connected to the bellows; The humidifier according to claim 4, comprising: 10. The humidifier according to claim 9, wherein the bellows is made of a thin metal plate, and an ether solution is sealed therein. 11. A first end of the bellows is integrally connected to one side of the first valve, and a second end opposite to the first end is fixed to a first side wall of the housing. The humidifier according to claim 10, wherein the first valve opens and closes the outlet by contracting and expanding according to the temperature of the water in the first water storage tank. 12. The bellows expands when the temperature of water stored in the first water storage tank is equal to or higher than a predetermined temperature, and the first valve connected to a first end of the bellows connects the outlet with the outlet. By closing, water is prevented from flowing from the first water storage tank to the second water storage tank, and when the temperature of the water is below a predetermined temperature, the water contracts and is connected to the first end of the bellows. The humidifier according to claim 11, wherein the first valve opens the outlet, so that water flows from the first water tank to the second water tank. 13. The humidifier according to claim 9, wherein the bellows is filled with alcohol, and expands and contracts depending on temperature. 14. The third means includes a tetrahedral housing, an inlet formed in a first side wall of the housing, into which water in the first water reservoir flows, and a third side located in a direction opposite to the first side wall. It is formed of a two-walled body, an outlet for discharging water into the second water storage tank, a cylinder assembly attached to the first side wall of the housing, and a first valve integrally connected to the cylinder assembly. The humidifier of claim 4, comprising a valve assembly. 15. The cylinder assembly is a sealed cylindrical cylinder having one end fixed to a first side wall of the housing, slidably mounted inside the cylinder, and one end of the cylinder assembly is connected to the first side wall. The humidifier according to claim 14, further comprising: a piston integrally connected to the valve, and a tension spring mounted inside the cylinder and for urging the piston against the first side wall of the housing. 16. The humidifier according to claim 15, wherein wax is injected into the cylinder to urge the piston toward the second side wall of the housing when the temperature rises. 17. The cylinder expands when the temperature of water stored in the first water storage tank is equal to or higher than a predetermined temperature, and a first valve connected to a first end of the cylinder closes the outlet. By preventing water from flowing from the first water storage tank to the second water storage tank, when the temperature of the water is equal to or lower than a predetermined temperature, the water contracts and is connected to the first end of the cylinder. A first valve opens the outlet. The humidifier according to claim 16, wherein water flows from the first water tank to the second water tank. 18. A switch for selecting a heater mode, an ultrasonic mode, and a combined heater and ultrasonic mode, and the fourth means is connected to the switch, and selectively connects the first means and the second means. The humidifier according to claim 1, wherein the humidifier is operated.