JP5847043B2 - Humidification mechanism - Google Patents

Description

The present invention relates to a humidifier that humidifies an indoor space, and particularly relates to a humidifying mechanism including an ion generator.

  Conventionally, various types of humidification mechanisms such as a vaporization type, a steam type, and an ultrasonic type have been used to humidify indoor spaces. These humidifying mechanisms replenish water and operate the humidifying means to increase indoor humidity. By increasing the indoor humidity, inactivate influenza viruses, cold viruses, etc., and moisturize the skin. Can be expected.

A humidification mechanism equipped with an ion generator that ionizes air molecules is also used. In addition to humidification, negative ions, positive ions, ozone, etc. are released into the room to provide a sterilizing effect and a deodorizing effect. It can also be expected to increase.

  The ion generator is installed inside a housing such as a humidifier that houses a humidification mechanism. The ion generator is activated to generate negative ions and the like, and the negative ions and mist are mixed and released into the room. It is possible.

However, a humidifier or an air conditioner in which an ion generator is housed inside a casing and negative ions are mixed with mist and released into the room cannot release a large amount of negative ions into the room.
JP 54-98034

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a humidifying mechanism that can increase the amount of ions released from an ion generator.

In order to solve the above problem, in the invention according to claim 1, in the humidification mechanism including the water supply unit and the atomization unit that supplies the water of the water supply unit to the space and the ion generation unit, the water is discharged from the atomization unit. As a method in which the atomized flow and the ion flow released from the ion generator do not intersect, the ions are discharged by a fan that is not mixed with the mist and is different from the blower fan that discharges the atomized flow into the room The driving time of the atomization unit and the driving time of the ion generation unit are controlled by the control unit, and the humidification stop and the ion generation are provided with a time lag of several seconds. If the indoor humidity measured by the humidity sensor reaches the target humidity, the humidification operation stops and ion generation starts, and the indoor humidity decreases. The humidification operation is resumed. The ion generation is set to stop.

In the invention according to claim 2, the atomization flow discharged from the atomization section and the ion flow discharged from the ion generation section are arranged so as not to intersect.

In the invention according to claim 3, the atomized flow discharged from the atomizing portion and the ion flow discharged from the ion generating portion are arranged in opposite directions.

In the invention according to claim 4 , the height of the discharge port is made different so that the atomized flow discharged from the atomizing portion and the ion flow discharged from the ion generating portion do not intersect in the height direction. It becomes.

In the invention according to claim 5, the atomization flow discharged from the atomization section has an atomization amount of 500 ml or more per hour.

According to the present invention, it is possible to provide a humidifying mechanism that can efficiently perform humidification and ion generation.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a schematic view of a humidifier according to the present invention. FIG. 2 is a time chart showing the operation timing of the present invention.

(First embodiment)
As shown in FIG. 1, the humidifier of the present invention mainly comprises a humidifier body 2, a water supply unit, a humidification unit, a circulator unit, and an ion generation unit. A water supply unit, a humidification unit, a circulator unit, and an ion generation unit are accommodated in the humidifier body 2 constituting the humidification mechanism. Moreover, in this invention, the atomization part consists of a water supply part and a humidification part at least.

The water supply section is composed of a water supply tank 9 and an ion exchange resin (not shown), and the humidification section is composed of a water communication path 10 from the water supply tank, an ultrasonic vibrator 11, a mist outflow tube 7, and a blower fan 6. Yes.

The circulator unit includes a circulator propeller fan 121 and a cylindrical tube 12 covering the outer periphery thereof, and the ion generation unit includes an ion generator 13 and a generation circuit thereof.

The humidifier body 2 is a housing made of resin, and is not particularly limited as long as the water supply unit, the humidification unit, the circulator unit, and the ion generation unit can be accommodated. It is a case of ~ 50cm. In the present invention, a part of the mist outflow cylinder 7 for discharging the atomized mist protrudes from the upper part of the main body 2.

  The water supply tank 9 is a resin container having a circular opening on the bottom and a hollow cylinder constituting the mist outflow cylinder 7 inside. A handle is provided on the upper surface side of the water supply tank 9, and an opening and a flange projecting downward from the opening end are provided on the bottom surface side. A cap 90 having a valve 99 is provided on the outer periphery of the flange so as to be screwed together.

  By attaching the water supply tank 9 containing water to the humidifier body 2, the valve 99 inside the valve 99 moves upward to form a moving space, and the water in the tank passes through the moving space. It is configured to drop onto the ion exchange resin.

A container-like filter filled with an ion exchange resin 92 is placed below the water supply tank 9 to receive water dropped from the water supply tank 9, and the water that has passed through the ion exchange resin is connected to the communication passage 10 and the atomization chamber. Move to 3.

  Although the present invention has been described with the configuration in which the mist outflow tube 7 is provided in the water supply tank 9, the water supply tank 9 and the mist outflow tube 7 are prepared separately so that the water supply tank 9 and the mist outflow tube 7 are arranged side by side. It is also possible to arrange.

  A heater 18 is provided around the communication path 10, and water in the communication path 10 can be heated to sterilize. Then, the water is atomized by the ultrasonic transducer 11 provided in the atomization chamber 3.

The atomizing chamber 3 is provided with an ultrasonic transducer 11, an ultrasonic transducer water tank 111, a large-diameter mist outflow tube 71, a small-diameter mist outflow tube 72, and an ejection port 73. The fog atomized by the ultrasonic vibrator can efficiently humidify the room by this configuration.

  In addition, in order to efficiently discharge the atomized flow into the room, it is possible to install a sirocco fan as a blower fan outside the large-diameter mist outflow cylinder 71 to create a humidified flow more actively.

  Then, a circulator unit 12 is provided adjacent to the mist outflow cylinder 7. The circulator 12 is a propeller fan 121 having a propeller diameter larger than that of the blower fan 6, and has a larger air volume than the blower fan 6. The outside of the circulator is covered with a cylindrical tube 122. The distance between the outlet 73 of the mist outflow cylinder 7 and the end of the circulator 12 is about 0.5 to 15 centimeters, and they are arranged close to each other.

  An ion generating part of the ion generating device 13 is arranged on the cylinder 122 that is leeward of the circulator 12 so as to face the fan.

Humidification and ion generation are performed using the above configuration. In the present invention, it is a great feature that the atomization flow discharged from the atomization unit and the ion flow released from the ion generation unit do not intersect each other. That is, the two elements are controlled so as not to operate simultaneously. When the humidifying unit is on, the ion generating unit is turned off, and conversely, the ion generating unit is turned on while the humidifying unit is off. The timing at which the humidifier is turned on / off can be based on the time (clock) provided in the humidifier or based on the detection value of the humidity sensor provided in the humidifier.

  Since the generation of ions is performed in a state where the humidification is off, the ions diffused in the room need not be affected by the humidified atomization flow, and the ions can be efficiently diffused in the room.

Table 1 shows the measurement results of the amount of ions corresponding to the present invention. (1) When only humidification resulting in an atomization flow is performed, (2) When humidification resulting in an atomization flow and ion generation becoming an ion flow are performed simultaneously, (3)
It is the result of measuring three times for each case where only ion generation that becomes an ion flow is performed. As can be seen from this result, when only ion generation is performed independently (3), the amount of ions is twice that of the case where atomization flow and ion flow are simultaneously generated and mixed (2). You can see that (Measured at 130cm directly above the humidifier)

  The humidifier is set so that it can be operated intermittently. As shown in FIG. 2, the humidifier operates for T1 time (40 to 60 seconds (t1 to t2)) and T2 time (5 to 20 seconds (t2 to t3)). ) The operation is controlled in the cycle to pause. On the other hand, the ion generator is inactive for T1 time (40 to 60 seconds (t1 to t2)) when the humidifier is operating, and T2 time (5 to 20 seconds (t2 to t3)) for which the humidifier is inactive. 3) Controlled to drive.

In other words, humidification and ion generation are not released simultaneously. The operation / rest time can be appropriately set according to indoor humidity, ion amount, and the like. The same tendency as the data shown in Table 1 was obtained even when this system was controlled and operated (Table 2).
That is, (4) humidification and ion generation are also compared in comparison with (21) humidification and ion generation at the same time and (4) intermittent humidification and ion generation (as shown in Fig. 2). It was confirmed that there was an advantage in the amount of ions in the intermittent alternating operation.
In the example shown in Table 2, (4) intermittent alternating operation in which the humidification time T1 is performed for 40 seconds, the humidification is stopped, and the ion generation time T2 is performed for 5 seconds. (Four)
In the intermittent operation, the ion generation is an intermittent operation for only the humidification stop time (5 seconds), and (21) the operation in which the humidification and the ion generation are performed simultaneously and mixed is a continuous operation in which ions are always generated. For this reason, the amount of ion generation (release amount) of both is much higher in the case of continuous operation in which the ions are always generated. Nevertheless, looking at the indoor ion measurement results (Table 2), it was confirmed that even in intermittent operation (21), the amount of ions was equal to or greater than that in mixed operation where humidification and ion generation were performed simultaneously (8 (Measured at the center of the room equivalent to a tatami mat). This demonstrated the superiority of intermittent alternating operation.

  As another control method, a humidity sensor is provided in the humidifier, and when the humidity in the room reaches the humidity to be set (for example, 50%), the humidification operation is stopped and the ion generation is controlled. It is also possible. As the humidifier is stopped, the operation of the ion generator is started and ions are released into the room. Again, when the indoor humidity decreases, the humidification is resumed and the ion generator is controlled to stop.

  It should be noted that the humidification stop and the ion generation can be controlled so that a time lag of several seconds is provided and the ion generation is released after a few seconds have passed after the humidification stop.

(Second embodiment)
In the present invention, in addition to controlling the driving time not to intersect, it is also possible to increase the amount of ions by physically arranging the atomizing flow and the ion flow so as not to intersect. For example, it can also be set as the structure by which the atomization flow discharge | released from the atomization part and the ion flow discharge | released from an ion generation part are arrange | positioned in the opposite direction.

It is also possible to adopt a configuration in which the height of the discharge port is made different so that the atomized flow discharged from the atomizing portion and the ion flow discharged from the ion generating portion do not intersect in the height direction. . With this configuration, since the atomization flow and the ion flow are not mixed, efficient atomization and ion generation can be performed.

In addition, the humidifying mechanism of this configuration is a particularly advantageous configuration in the case of large-capacity humidification. The atomization flow discharged from the atomization section can be particularly effective when the amount of atomization per hour is 500 ml or more.

  In the claims and specifications of the present invention, a series of explanations have been made with expressions such as fog and atomization, but similar humidification generated by a general humidification method such as a vaporization type and a steam type. If there is, it is not limited to them, and the same applies to steam and steam flow.

The humidification mechanism of the present invention can be applied to uses such as a humidifier, an air conditioner, an air cleaner with a humidifier, and an air conditioner.

Shows a schematic view of the humidifier of the present invention. These are time charts showing the operation timing of the present invention.

1 Humidifier
2 Body
3 Atomization chamber
4 Tank storage room
5 Air duct
6 Blower fan
7 Fog spill tube
71 Large-diameter fog spill tube
72 Small-diameter mist outflow cylinder
73 Outlet
8 Liquid (water)
9 Water tank
10 communication path
11 Ultrasonic transducer
111 Ultrasonic vibrator tank
115 Ultrasonic vibrator water tank recess (112 Drive circuit part)
12 Circulator
121 propeller fan
122 tubes
13 Ion generator
90 cap
91 Water tank housing
92 Ion exchange resin (filter)
93 Container (filter part)
94 pipe
96 cartridges

Claims (5)

In a humidifying mechanism including an atomizing unit and an ion generating unit for supplying water to the space with water from the water supplying unit, the atomized flow discharged from the atomizing unit and the ion flow discharged from the ion generating unit As a system that does not intersect with the mist, ions are not mixed with the mist, and the atomized flow is discharged by a fan other than the blower fan that discharges the atomized flow into the room. Control is performed by the control unit so that the drive time of the unit is different, and the humidification stop and ion generation are provided with a time lag of several seconds, and after a few seconds have elapsed after the humidification stop, the ion generation is controlled to operate, and the humidity sensor When the measured indoor humidity reaches the target humidity, the humidification operation stops and ion generation starts.When the indoor humidity decreases, the humidification operation restarts and ion generation stops. Configuration Ion generating function humidifying mechanism, characterized by being. 2. The humidification mechanism with an ion generation function according to claim 1, wherein the atomization flow discharged from the atomization unit and the ion flow discharged from the ion generation unit are arranged so as not to intersect with each other. The atomization flow discharged from the atomization unit and the ion flow discharged from the ion generation unit are arranged in opposite directions, according to any one of claims 1 and 2 . Humidification mechanism with ion generation function. 2. The height of the discharge port is made different so that the atomization flow discharged from the atomization portion and the ion flow discharged from the ion generation portion do not intersect in the height direction. The humidification mechanism with an ion generating function according to any one of claims 3 to 4. The humidification with an ion generation function according to any one of claims 1 to 4 , wherein the atomization flow discharged from the atomization unit is formed of an atomization amount per hour of 500 ml or more. mechanism.