KR100626580B1 - Humidifier - Google Patents

Abstract

An object of the present invention is to provide a humidifier having a particularly high bactericidal effect.

The solution of the present invention is that when the automatic drive switch 81, the strong drive switch 83, or the weak drive switch 85 is turned on, the switches 81, 83 or 85 that are turned on are operated. Any switch that is turned on is turned off. As a result, the microprocessor 72 operates, the H signal output from the second output terminal 722 is stopped, the seventh transistor 95 is turned off, the second relay coil 94 is deactivated, and 2 relay switch 56 is turned off. When the second relay switch 56 is turned off, the fan motor 58 is turned off, the blower for blowout stops, and the humidification operation of the humidifier stops. In addition, the microprocessor 72 operates and outputs a signal through the signal control output circuit 78 in the same manner as in the humidification operation. For this reason, energization to the electrode 10 is continued for 20 cycles, for example, and the water in the drip tank 6 is sterilized.

humidifier

Description

Humidifier {HUMIDIFIER}

1 is an external perspective view of a humidifier.

Figure 2 is a perspective view showing the inside of the main body, excluding the water supply tank for convenience of explanation.

3 is a perspective view showing the inside of the main body for convenience of explanation.

4 is a partially broken view of the feed tank.

5 is a control circuit diagram of the humidifier.

Fig. 6 is a diagram showing the relationship between time and room humidity in the automatic driving mode.

7 is a diagram illustrating an electrode energization cycle in a strong humidification operation.

Fig. 8 is a diagram showing an electrode energization cycle in weak humidification operation.

9 illustrates an electrode energization cycle.

※ Explanation of code for main part of drawing

1: body of the humidifier 6: drip tank

7: water tank 10: electrode

14 heating tube 21 humidification absorbent

58: fan motor 63: switching electrode

66: polarity switching circuit 72: microprocessor

77: humidity detection sensor

The present invention relates to a humidifier for supplying humidified air indoors.

Humidifiers of this kind are generally known as ultrasonic humidifiers disclosed in Japanese Patent Laid-Open No. 5-115818. The ultrasonic humidifier supplies water to a vaporization tank having an ultrasonic vibrator, mists the water by the vibrator, mixes it with air blown from the outside, generates humidified air, and supplies it to the room. In addition, water may be boiled with an electric heater to obtain humidified air.

However, in the ultrasonic humidifier and the like described above, there is a problem that Legionella is easy to breed under 25 ° C. to 30 ° C. conditions, particularly if the vaporization tank is contaminated, and this is released into the room. In addition, the use of the electric heater had a problem that the operating cost increases.

Therefore, an object of the present invention is to provide a humidifier having a particularly high bactericidal effect.

To this end, the first invention is installed in the air passage formed by the blower, the absorber for partially absorbing the water by the capillary phenomenon is submerged in the water tank receiving the water supply from the water supply tank, vaporized from the absorber and the air passage A humidifier that mixes air in the room, supplies it to the room, humidifies, and embeds a pair of electrodes to generate a substance with bactericidal action in the water of the tank or in the water of the water supply tank. And control means for energizing the electrodes by controlling the on-duty to change the amount of humidification.

Further, the second invention is provided with a humidity detection sensor for detecting the humidity of the humidified space, the control means for controlling the blowing amount and the on-duty of the blower based on the humidity detected by the humidity detection sensor. It is done.

The third invention is characterized in that the control means stops the generation of the bactericidal substance by delaying from the stop of the humidification.

The fourth invention is characterized in that the delay is for a predetermined time from the stop of the humidification.

The fifth aspect of the invention is characterized in that the delay is from the stop of the humidification until it reaches the number of times of switching of the polarity of energization to the pair of electrodes.

The sixth invention is characterized in that the control means makes the on-duty small during the delay.

Embodiment of the invention

EMBODIMENT OF THE INVENTION Hereinafter, 1st Embodiment of this invention is described based on drawing. In FIG. 1, 1 is a main body of a humidifier which has a prismatic case body, and the upper surface opening formed in this main body 1 is closed so that the front lid body 2 and the rear lid body 3 can be detachably attached. do. Air inlets 4 are provided on both side surfaces and the rear surface of the main body 1.

The control box which is not shown in figure is arrange | positioned under the said main body 1, and the control apparatus which controls this humidifier is accommodated. The drip tank 6 is formed in the bottom wall 5 (refer FIG. 2) which forms the upper surface of a control box by forming a recessed part. This water tank 6 has a water supply passage 9 which is circular in plan view in which a projection 8 for lifting a valve (not shown) of the water supply tank 7 shown in FIG. 3 is formed in the center, and an electrode to be described later. The heating vessel in which the channel 11 which is circular in planar view in the plane in which 10 is arrange | positioned, the channel 13 which is circular in planar view in which the float 12 is installed, and the electric heater 55 mentioned later in the center part are embedded. It consists of the channel 15 which is the planar view square in which (14) is arrange | positioned, and the communication channel 16 which connects this channel 15 and the said water supply path 9, and all communicate. The electrode 10 may be disposed in the communication path 16.

In addition, when the water in the said sump tank 6 becomes below a predetermined level, the said float 12 operates the float switch 88 mentioned later, and operation | movement is forcibly stopped.

Then, the projection 8 lifts the valve incorporated in the cap 20 of the water supply tank 7 to control the flow of the replacement air in relation to the position of the cap end and the water level of the water tank 6, The water (tap water) of the water supply tank 7 is supplied to the said water receiving tank 6 so that it may become constant level. In addition, the communication path 16 is formed slightly deeper than the other channels 9, 11, 13, and 15, and the water level is higher than the upper end of the heating tube 14 in the state in which the water receiving tank 6 is filled with water. It is in a high position.

In the channel 15 of the water tank 6, the honeycomb-shaped humidifying absorber 21 surrounds the heating tube 14 in a substantially rectangular shape in plan view, and its end portion (a part) is a channel. It is arrange | positioned so that it may be submerged in the water in (15), and this absorber 21 sucks up the water in this channel 15 to the upper side by capillary phenomenon. This absorbent body 21 is comprised from the nonwoven fabric made from acrylic fiber, polyester fiber, etc., for example. In addition, in FIG. 2, although the shape was partially deleted for convenience of description, the end portions are joined to have a substantially rectangular shape in plan view as shown in FIG.

A blower opening 22 is formed on the upper surface of the rear lid body 3, and the blower for blower which consists of a fan and the fan motor 58 mentioned later in the cylinder 23 fixed to the lower surface is shown. Is provided, and the humidifying absorber 21 sucks up the water around the heating tube 14, which has been heated to 50 ° C to 60 ° C (heats when the humidification amount is increased) by the heating tube 14. And guides the indoor air introduced into the main body 1 from the air intake port 4 by the blower by the air passage forming plate 24 from the outer surface of the honeycomb absorber 21 to absorb the air absorber 21. The air is guided to the inner space and mixed with water vapor vaporized from the absorber 21 to supply humidified air from the blowout opening 22 to the room outside the main body 1 through the cylinder 23.

That is, the air passage forming plate 24 is formed to spread outward from the lower end of the cylinder 23, and forms a air passage connected from the air intake opening 4 to the blowout opening 22. The absorber 21 is disposed in this air path, and all the indoor air introduced into the main body 1 from the air intake 4 is a space in the absorber 21 at the outer side of the honeycomb absorber 21. After being led to, it is supplied to the room through the blower blower.

The electrode 10 has, for example, two electrode plates made of Ti (titanium) and a film layer composed of Ir (iridium), Ta (tantalum), and Pt (platinum). By using mA, a predetermined free residual chlorine concentration (for example, 1 ppm) is generated to obtain a bactericidal and antifouling effect (sterilization effect). In order to improve the durability, the electricity supply to the electrode 10 is polarized at a predetermined cycle, and during the humidification operation, electricity is often supplied to the electricity supply cycle according to the humidity, and at the end of the operation, chlorine generation is maintained for a predetermined time so as to maintain the generation of chlorine in the drip tank 6 Although control is performed to stop the sterilization of the deceased person, this control will be described later.

In addition, when it controls in this way and it energizes the water in the water tank 6 by the said electrode 10, water will be,

The anode 4H ^{+ +} 4e ^-, and a, + (4OH ^{- -)} is 2H ₂ + (4OH)

The anode 2H ₂ O + a 4H ^{+ +} O ₂ ⁺ 4e ^- is a chlorine (with pre-added in tap water) to be contained at the same time in water,

At the anode, 2Cl ⁻ becomes Cl ₂ + 2e ⁻ , and since Cl ₂ (chlorine) is easily soluble in water, Cl ₂ + H ₂ O becomes HClO + HCl again.

Therefore, when the electrode 10 is energized, HClO (hypochlorous acid) having a high bactericidal power is generated.

Hereinafter, the controller of the humidifier will be described in detail with reference to FIGS. 5 to 8.

5 is a control circuit diagram of the humidifier, in which 40 is a plug, 50 and 51 are AC power lines, 52 is a varistor, 53 is a fuse, 54 is a first relay switch, and 55 is an electric embedded in the heating tube 14 of the humidifier. It is a heater, and is connected between the AC power supply lines 50 and 51 via a fuse. 56 is a second relay switch, 57 is a third relay switch, 57L is a low-speed contact (hereinafter referred to as "L contact") of the switch 57, 57H is a high-speed contact of the switch 57 (hereinafter, 58 is a fan motor (induction motor) of the blower for blow-out, for example, and is connected between AC power supply lines 50 and 51.

In addition, 59 is a noise filter, 60 is a rectification smoothing circuit, 61 and 62 are DC power supply lines connected to this rectification smoothing circuit 60, 79 is a flat connection connected between these DC power supply lines 61 and 62, respectively. The utilization capacitor 63 is a switching power supply, and the switching power supply 63 is composed of the first transistor 64, the condenser 65, and the like. In addition, 66 is a polarity switching circuit (single-phase bridge circuit), and this polarity switching circuit 66 is composed of second to fifth transistors 67 to 70, and the electrode 10 is connected to the polarity switching circuit 66. ) Is connected.

71 is, for example, a 5 V power supply line connected to the rectification smoothing circuit 60, 72 is a humidifier control microprocessor, and power is supplied from the power supply line 71 to the microprocessor 72. The microprocessor 72 stores data of temperature or humidity detected by a ROM 73, an indoor temperature detection sensor 76, or a humidity detection sensor 77 in which a program for controlling the humidifier is stored, and automatic humidification described later. RAM 74 that stores the set humidity (for example, 40%) at the time of operation, and controls the operation of the humidifier according to a program stored in the ROM based on data such as temperature or humidity stored in the RAM 74. CPU 75 or the like.

78 is a signal output circuit composed of a buffer and a photocoupler, and is connected to each base (signal input terminal) of the first to fifth transistors 64 and 67 to 70. In addition, 80 is an operation display part provided in the front of the main body 1 of a humidifier, and it is automatic operation which is LED, for example, LED which lights up when the automatic operation switch 81 and this automatic operation switch 81 are turned on. The light driving 82, the light driving switch 83, the light driving switch 85, and the light driving switch 85 that are turned on when the strong driving switch 83 is turned on, for example, are weak. It consists of the weak operation indicator 86 etc. which are LED which light up at the time of switch ON, for example.

87 is a conduction switch which is turned off when the humidifier is inverted, 88 is turned on by the action of the float 12 when the water level of the drip tank 6 is above the set level, and is turned off when the level is lower than the set level. As a switch, each switch is connected to a power supply line 71 and a microprocessor 72. The operation level indicator 83 is provided with a water level lowering indicator 89 such as an LED, and the water level lowering indicator 89 is a microprocessor 72 when the float switch 88 is lower than the set level and turned off. It lights up based on the signal from.

90 is a 12 V power supply line connected to the rectification smoothing circuit 60, and 91 is a buffer connected to the first, second and third output terminals 721, 722 and 723 of the microprocessor 72. 92 is the first relay coil, 93 is the sixth transistor, 94 is the second relay coil, 95 is the seventh transistor, 96 is the third relay coil, and 97 is the eighth transistor. In addition, 98 is a direct current detection circuit which detects the electric current which flows in the said direct current power supply line 62, For example, 5 V DC power is supplied and it is connected to the microprocessor 72. As shown in FIG.

By the above structure, if water (tap water) is put into the water supply tank 7 first, and it is put in the main body 1, water will be supplied from the water supply tank 7 to the drip tank 6 through the valve in the cap 20, The humidifying absorber 21 sucks up the water in the channel 15 of the drip tank 6 evenly.

Then, when the plug 40 is plugged into, for example, a 100 V AC commercial power outlet and an AC current flows through the AC power lines 50 and 51, the DC power line 61, through the rectifying smoothing circuit 60, is connected. DC power is supplied to each circuit from (71, 90). In this state, if the user presses the autonomous operation switch 81 to turn off, for example, at time T1 shown in Fig. 6, the microprocessor 72 (CPU 75) is placed on the front surface of the main body 1; The automatic operation indicator (82) lights up to indicate that the automatic operation is in progress.

In addition, when the humidifier is properly placed (horizontal state), the conduction switch 87 is turned on, and when the water level of the drip tank 6 of the humidifier is a predetermined level and the float switch 88 is turned on, When the automatic operation switch 81 is turned on again and the detected humidity by the humidity sensor 77 does not satisfy the set humidity, the microprocessor 72 receives a high level signal from the first output terminal 721. Hereinafter, the "H signal") is output. This signal is sent to the sixth transistor 93 through the buffer 91 so that the sixth transistor 93 is turned on, and the first relay coil 92 is excited to turn on the first relay switch 54. . By turning on the first relay switch 54, the electric heater 55 is energized, and the heating cylinder 14 is heated to heat water around the heating cylinder 14 at 50 ° C to 60 ° C. That is, the electric heater 55 is energized during the strong humidification operation to heat the water in the drip tank 6.

In addition, when the humidifier is properly placed, the conduction switch 87 is turned on and the float switch 88 is turned on as described above, the second operation of the microprocessor 72 is turned on by the automatic operation switch 81 turned on. The H signal is output from the output terminal 722. As a result, the seventh transistor 95 is turned on, and the second relay coil 94 is energized to turn on the second relay switch 56.

As described above, the microprocessor 72 inputs a detection signal from the humidity detection sensor 77, and the humidity data stored in the detected RAM 74 and the set humidity (40%) stored in the RAM 74 are stored. In comparison, when the detected humidity is lower than the set humidity, the strong driving of the humidifier is started. In this strong driving operation, the H signal is output from the third output terminal 723 of the microprocessor 72. The eighth transistor 97 turns on by this H signal, energizes the third relay coil 96, and closes the third relay switch 57 to the H contact.

For this reason, the fan motor 58 of the blower blower is energized, rotates at high speed, and strong humidification operation is started. The room is humidified by the strong humidification operation by this humidifier. That is, the humidifying absorber 21 sucks up the water around the heating tube 14 heated at 50 ° C. to 60 ° C. by the heating tube 14, and the air inlet is blown out by the blower. (4) guides the indoor air introduced into the main body (1) by the air passage forming plate (24) to guide the space from the outer surface of the honeycomb absorber (21) to the space in the absorber (21). Air humidified by mixing with water vapor vaporized from 21) is supplied from the blowout opening 22 to the room outside the main body 1 through the cylinder 23, and humidified.

In addition, the microprocessor 72 receives the on-signal output of the second transistor 67 and the fifth transistor 70 for 130 seconds from the time T1 through the signal control output circuit 78, for example, for 50 seconds. Stops the signal output, the on-signal output of the fourth transistor 69 and the third transistor 68 for 50 seconds and the signal output stop for 130 seconds are repeated. Therefore, as shown in Figs. 7 and 9, the electrode 10 is energized for 50 seconds and is deenergized for 130 seconds, the polarity is switched for 50 seconds and is deenergized for 130 seconds. do.

Thus, since the polarity is switched every predetermined time at the time of energization to the electrode 10, the durability of the electrode 10 can be improved.

In addition, as described above, with the strong humidification operation, electricity is supplied to the electrode 10 embedded in the drip tank 6 in the water, whereby 2Cl ⁻ becomes Cl ₂ + 2e ⁻ in the anode, and this Cl ₂ (Chlorine) is easily soluble in water, so Cl ₂ + H ₂ O becomes HClO + HCl. Therefore, HClO (hypochlorous acid) with a high bactericidal power is generated. Due to this, it is possible to prevent the growth of Legionella, Escherichia coli, and other fungi, and to release the Legionella bacteria and the like in the room.

Moreover, even if a scale of brownish color occurs, it is not attached to the drip tray 6 or the like, so that cleaning by drainage is easy.

In addition, the current flowing through the DC power supply line 62 is detected by the DC current detection circuit 98 and the microcomputer 72 causes the detection current, that is, the current flowing through the electrode 10 to be 40 milliampere, for example. The on-duty of the first transistor 64 is controlled by outputting the on-signal to the first transistor 64.

In addition, when an earthquake occurs during the humidification operation or when the user catches the humidifier and the humidifier conducts, the conduction switch 87 is turned off and the signals from the first and second output terminals 721 and 722 of the microprocessor 72 are turned off. Stops. As a result, the sixth and seventh transistors 93 and 95 are turned off, the first and second relay coils 92 and 94 are deformed, and the first and second relay switches 54 and 56 are turned off. When the electric heater 55 is turned off, the fan motor 58 of the blower blower is stopped while the heating of the electric heater 55 is stopped.

By the humidification operation by the humidifier as described above, when the humidity in the room rises with the passage of time, and reaches 40% of the set humidity at the time T2, the microprocessor 72 reaches this with a timer (not shown). After 3 minutes have elapsed from one time point, the H signal output from the third output terminal 723 is stopped, and the eighth transistor 97 is turned off. The third relay coil 96 is turned off by the eighth transistor 97 off, and the third relay switch 57 is switched to the L contact. That is, as mentioned above, it delays for 3 minutes from the time when the set humidity is reached, and is switching from strong humidification operation to weak humid operation. By this switching, the fan motor 58 changes from high speed rotation to low speed rotation, and the amount of suction from the humidifier decreases, and the room is humidified by the humidification operation by the humidifier.

In addition, the microprocessor 72 stops the H signal output from the first output terminal 721 after 3 minutes elapsed by the timer, thereby turning off the sixth transistor 93, so that the first relay coil 92 The first relay switch 54 is turned on so that the electric heater 55 is not energized to stop the heating of the water in the drip tank 6.

In addition, the microprocessor 72 receives the on-signal output of the second transistor 67 and the fifth transistor 70 for 145 seconds, for example, from the time T2 through the signal control output circuit 78. The signal output stop of?, The on-signal output of the fourth transistor 69 and the third transistor 68 for 35 seconds, and the signal output stop of 145 seconds are repeated. For this reason, as shown in FIGS. 8 and 9, the electrode 10 is energized by switching polarity in an energization pattern every 35 seconds and 145 seconds, and the electrode 10 is intermittently shorter than the time of the strong humidification operation. And the water in the drip tank 6 is sterilized as described above.

When the indoor humidity gradually decreases due to the weak humidification operation and becomes lower than the set humidity at the time T3, the microprocessor 72 starts the H from the third output terminal 723 from the time when the microprocessor 72 reaches its timer. A signal is output, and the eighth transistor 97 is turned off in the same manner as in the strong humidification operation. As a result, the third relay coil 96 is demagnetized and the third relay switch 57 is switched to the H contact. The fan motor 58 changes from low speed rotation to high speed rotation, and the suction amount of the humidified air from the humidifier increases, so that the fan motor 58 is switched to the strong humidification operation. Therefore, the room is humidified by the strong humidification operation by this humidifier.

Further, since the microprocessor 72 outputs the H signal from the first output terminal 721 and turns on the sixth transistor 93, the first relay coil 92 is excited and the first relay switch 54 is turned on. Is turned off so that the electric heater 55 is energized to start heating the water in the drip tank 6.

The microprocessor 72 also turns on the signal output of the second transistor 67 and the fifth transistor 70 for 50 seconds and the signal output stop for 130 seconds from the time T3 through the signal control output circuit 78 again. The on-signal output of the fourth transistor 69 and the third transistor 68 for 50 seconds and the signal output stop for 130 seconds are repeated. For this reason, as shown in FIG. 7, the electrode 10 is energized by switching polarity in the electricity supply pattern for every 50 seconds and 130 seconds, and the electrode 10 has the same time as the strong humidification operation from above (T1). Intermittently energized, the water in the drip tank 6 is sterilized.

Subsequently, with the change of the indoor humidity, the strong humidification operation and the weak humidification operation of the humidifier are alternately repeated, and the water in the drip tank 6 is sterilized by energization to the electrode 10.

Further, when the user operates the strong driving switch 83 of the operation display unit 80 and the strong driving switch 83 is turned on, the strong driving indicator 84 lights up, and the humidity detection sensor 77 Regardless of the detected humidity, water sterilization is performed in the drip tank 6 by energizing the electrode 10 based on the strong humidification operation and the energization pattern shown in FIG. 7.

When the weak operation switch 85 is turned on by the user operating the weak operation switch 85 of the operation display unit 80, the weak operation indicator 86 lights up and the humidity detection sensor 77 is detected. Regardless of the humidity, the water in the drip tank 6 is sterilized by the weak humidification operation and the energization of the electrode 10 based on the energization pattern shown in FIG. 8.

The operation at the time of stopping the humidifier will be described below.                     

As described above, when the automatic humidification operation by the ON of the automatic operation switch 81 is performed, when the strong humidification operation by the ON of the strong driving switch 83 is performed, or when the weak operation switch 85 is turned on. Is turned on when the automatic drive switch 81, the strong drive switch 83, or the weak drive switch 85, which is turned on when the low humidification operation is performed, is turned off. As a result, the microprocessor 72 operates to stop the H signal output from the first output terminal 721 and the sixth transistor 93 is turned off. For this reason, when the 1st relay coil 92 is an element, the 1st relay switch 54 is turned off, and the electric heater 55 is energized, it is non-energized and the water of this electric heater 55 is heated. Stops.

Further, the microprocessor 72 operates, the H signal output from the second output terminal 722 is stopped and the seventh transistor 95 is turned off, the second relay coil 94 is demagnetized and the second relay switch is turned off. 56 is turned off. When the second relay switch 56 is turned off, the fan motor 58 is turned off, the blower for blowout stops, and the humidification operation of the humidifier stops.

In addition, the microprocessor 72 operates, and outputs a signal through the signal control output circuit 78 as in the case of the weak humidification operation. For this reason, the electricity supply to the electrode 10 is continued similarly to the electrode electricity supply pattern shown in FIG. 8, and the water in the drip tank 6 is sterilized. And when the energization to the electrode 10 based on the electricity supply pattern shown in FIG. 8 is repeated 20 cycles (refer FIG. 9), the signal output of the microprocessor 72 will stop and the electrode 10 will be non-energized. After the transfer, the sterilization of the water in the drip tank 6 is stopped.

In this way, it is possible to suppress the growth of Legionella bacteria or the like in the drip tank 6 after the humidification operation is stopped by energizing the electrode 10 after the humidification operation of the humidifier is stopped, that is, the operation of the blower is stopped. Of course, power supply to the electrode 10 can be suppressed to reduce power consumption, and the life of the electrode 10 can be extended.

The present invention is not limited to the above-described embodiment, and the electrode 10 is supplied by applying the current to the electrode 10 during the humidification operation to obtain a current supply pattern in which sterilization capacity equivalent to the amount of humidification by the operation of the fan motor 58 is obtained. Can be reduced to extend the life of the electrode 10.

Also, when the humidification operation of the humidifier is stopped, that is, the energization time (for example, 15 minutes) to the electrode 10 after the fan motor 58 of the blower is stopped, the microprocessor 72 is not shown in advance. It can also be set as a timer.

In addition, the automatic operation switch 81, the strong operation switch 83 and the weak operation switch 85 of the operation display unit 80 are integrated into one operation switch, and each time the operation switch is operated, the automatic humidification operation and the strong humidification operation are performed. For example, it may be switched to weak humidification operation and operation stop.

4 shows a second embodiment, which is an embodiment in which the electrode 10 is provided in the water supply tank 7. That is, it is provided in the shoulder part near the cap 20 of the said water supply tank 7, and arrange | positioned so that the electrode 10 may protrude in this tank 7. It is effective even if there is little water in the water supply tank 7 by installing in this shoulder, and the electrode 10 does not interfere with water supply in this tank 7, The effect by the said electrode 10 can be exhibited with respect to the water to supply water.

As mentioned above, this invention can provide the humidifier with a high disinfection effect especially. That is, the electricity supply to the electrode after the humidification operation is stopped, that is, after the operation of the blower is stopped, can suppress the growth of Legionella bacteria or the like in the drip tank after the humidification operation is stopped, as well as suppress the energization to the electrode. Therefore, power consumption can be reduced, and the life of this electrode can be extended.

Claims (9)

A part of the tank is supplied to the water tank receiving water from the water supply tank, and an absorber that sucks up the water by capillary action is installed in the air passage formed in the blower, and the vaporized vapor from the absorber is mixed with air in the air passage. As a humidifier for supplying and humidifying and at the same time, a pair of electrodes for generating a substance with bactericidal action is buried in the water of the tank or in the water of the water supply tank, And a control means for switching the conducting electrode characteristics at a predetermined cycle and conducting electricity to the electrodes by controlling the on-duty to change the amount of humidification. The humidifier according to claim 1, wherein the control means stops the generation of the substance having the bactericidal action by delaying the stop of the humidification. The method of claim 1, And a humidity detection sensor for detecting the humidity of the humidified space, wherein the control means controls the air blowing amount and the on-duty of the blower based on the humidity detected by the humidity detection sensor. delete The method of claim 1, The delay is a humidifier, characterized in that for a predetermined time from the stop of the humidification. The method of claim 1, And the delay is from the stop of the humidification until the polarity switching frequency of energization is reached to the pair of electrodes. The method of claim 1, And said control means reduces said on-duty during said delay. delete delete delete

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