JP2012021701A - Humidifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable an electrolytic water mist to be used for sterilization and deodorization of a filter, in a humidifier which discharges the electrolytic water mist for sterilization and deodorization of indoor air.SOLUTION: The humidifier 1 includes: a casing 20; an air circulation path 21 formed in the casing 20, wherein one end is an air inlet 22, the other end serves as a spraying tube 23, and a blower 24 is arranged in the middle; the filter 26 arranged at the air inlet 22; an electrolytic water generation device installed in the casing 20; and an electrolytic water mist generation device 38 in which the generated electrolytic water by the electrolytic water generation device is converted into a mist and this electrolytic water mist is mixing with the air before ejecting from the spraying tube 23. In the spraying tube 35, an air reflux means which makes it possible to reflux at least a part of air mixing with the electrolytic water mist into the air circulation path 21 immediately after the ejection is attached. The air reflux means comprises an ejection direction variable nozzle 44 attached rotatably at the tip of the spraying tube 23.

Description

  The present invention relates to a humidifier.

  Many recent humidifiers and air purifiers have a function of suppressing the activity of microorganisms such as viruses. For example, the humidifier described in Patent Document 1 sprays sterilized water generated by electrolyzing a solution to which an electrolyte has been added, into a spray form using a humidifying function unit, and sprays it while humidifying the room. The air purifier described in Patent Document 2 disperses mist of electrolyzed water outside the apparatus using air purified in the air purifier to sterilize and deodorize indoor air.

JP 2001-33070 A (International Patent Classification: F24F6 / 00) JP 2007-37589 A (International Patent Classification: A61L9 / 14, A61L9 / 01, C02F1 / 46)

A filter is provided at the air intake of the humidifier. If you use the humidifier for a long time,
Microbes trapped in the filter propagate and the filter itself can even emit odors.

  The present invention has been made in view of the above points, and in a humidifier that discharges electrolyzed water mist for sterilization and deodorization of indoor air, the electrolyzed water mist can be used for filter sterilization and deodorization. The purpose is to do.

  According to a preferred embodiment of the present invention, a humidifier is formed in a housing and the housing, one end is an air intake port, the other end is a spray cylinder, and a blower device is disposed in the middle. An air flow path, a filter disposed at the air inlet, an electrolyzed water generating device built in the housing, and a mist of the electrolyzed water generated by the electrolyzed water generating device, also built in the housing. An electrolyzed water mist generating device that mixes the electrolyzed water mist into the air before being discharged from the spray cylinder, and at least a part of the air mixed with the electrolyzed water mist is discharged into the spray cylinder immediately after the air is discharged. Air recirculation means is provided that allows recirculation to the flow path.

  According to a preferred embodiment of the present invention, in the humidifier configured as described above, the air intake port and the spray cylinder are disposed in close proximity to the upper part of the housing, and the air recirculation means is provided at the tip of the spray cylinder. It is comprised by the blowing direction variable nozzle attached rotatably.

  According to a preferred embodiment of the present invention, in the humidifier configured as described above, the blowing direction variable nozzle is rotated by a motor to change the blowing direction.

  According to a preferred embodiment of the present invention, in the humidifier configured as described above, the air intake port and the spray cylinder are disposed in close proximity to the upper portion of the housing, and the spray cylinder is variable in elevation angle, The air recirculation means is constituted by an elevation angle changing device for the spray cylinder.

  According to a preferred embodiment of the present invention, in the humidifier configured as described above, the casing is supported on the pedestal so as to be able to rotate around a vertical axis, and is rotated in an inverted manner by a swing motor. The elevation angle changing device is configured by a cam plate that stands up from the pedestal and supports the spray cylinder from below, and gives a different elevation angle to the spray cylinder according to the rotation angle of the casing.

  According to a preferred embodiment of the present invention, in the humidifier having the above-described configuration, the elevation angle changing device includes a lifting plate that supports the spray cylinder at an upper end and a motor that is displaced by a motor to give a lifting operation to the lifting plate. Consists of cams.

  According to the present invention, at least a part of the air mixed with the electrolyzed water mist discharged from the spray cylinder can be recirculated to the air flow path, and the filter disposed at the air intake can be sterilized and deodorized with the electrolyzed water mist. The humidifier can be used hygienically and comfortably.

It is a partial cross section front view of the humidifier which concerns on 1st Embodiment of this invention. It is a vertical sectional view of the humidifier according to the first embodiment. It is a vertical sectional view of the humidifier according to the first embodiment, and shows a state different from FIG. It is a front view of the humidifier which concerns on 2nd Embodiment of this invention. It is a vertical sectional view of a humidifier according to a second embodiment. It is a vertical sectional view of the humidifier according to the second embodiment and shows a state different from FIG. It is a top view of the humidifier which concerns on 2nd Embodiment. It is a front view of the humidifier which concerns on 3rd Embodiment of this invention. It is a vertical sectional view of a humidifier according to a third embodiment. It is a vertical sectional view of a humidifier according to a third embodiment, and shows a state different from FIG.

  Hereinafter, the structure and operation of the humidifier according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 3.

  The humidifier 1 includes a planar pedestal 10 having a circular shape, and a cylindrical casing 20 that is supported on the pedestal 10 and that has a vertical axis. The pedestal 10 supports the casing 20 so as to be rotatable about a vertical axis, and a specific structure thereof will be described later.

  An air flow path 21 is formed inside the housing 20. The air flow path 21 starts from an air intake port 22 formed in the upper front portion of the housing 20 and ends with a spray cylinder 23 disposed near the front surface of the top surface of the housing 20. A blower 24 is disposed in the air flow path 21 between the air intake 22 and the spray cylinder 23.

  The air intake port 22 is composed of a plurality of small holes or a set of slits. An air purification unit 25 is disposed at the air intake 22. The air purification unit 25 includes a filter 26 that covers the air intake port 22 from the outside, and a guard grill 27 that attaches the filter 26 to the housing 20. The filter 26 is composed of a coarse dust filter having a relatively coarse mesh, but may be a combination of a deodorizing filter, a fine fine dust filter, or the like, if necessary.

  The blower 24 forms an air flow that is sucked from the air intake port 22 and discharged from the spray cylinder 23, and includes a sirocco fan 28, a motor 29 that rotates the sirocco fan 28, and a fan casing 30 that surrounds the sirocco fan 28. Consists of. The fan casing 30 is formed with a suction port portion 31 facing the end surface of the sirocco fan 28 and a discharge port portion 32 facing the outer peripheral surface of the sirocco fan 28. A duct 33 perpendicular to the discharge port portion 32 is formed. The duct 33 reaches the ceiling surface of the housing 20 and is connected to the spray cylinder 23 there.

  The spray cylinder 23 has a horizontal cylindrical root portion 34 and a nozzle portion 35 that protrudes in a tangential direction with respect to the root portion 34. The spray cylinder 23 is attached to the housing 20 so that the spray cylinder 23 can be rotated around the cylindrical central axis of the root portion 34, in other words, the elevation angle can be changed. An opening 36 communicating with the inside of the duct 33 is provided in a part of the cylindrical surface of the root portion 34.

  A pipe 37 protrudes from the root portion 34 toward the inside of the housing 20. The tip portion of the pipe 37 that spreads in a funnel shape reaches the electrolyzed water mist generating device 38 installed inside the housing 20. The electrolyzed water mist generating device 38 mists the electrolyzed water that has flowed from an electrolyzed water generating device (not shown) (installed inside the housing 20 in the same manner as the electrolyzed water mist generating device 38) with the ultrasonic vibrator 39. Is.

  In the case 40 of the electrolyzed water mist generating device 38, the surface facing the pipe 37 is a cylindrical surface 41 centered on the rotation center of the spray cylinder 23. Since the end surface of the pipe 37 is also a cylindrical surface 42 having the same curvature as the cylindrical surface 41, the pipe 37 can rotate together with the spray cylinder 23 while being in contact with the housing 40.

  An opening 43 communicating with the inside of the pipe 37 is formed in a part of the cylindrical surface 41. The size of the tip of the pipe 37 that expands in a funnel shape is set so as to wrap around the opening 43 even when the spray cylinder 23 is most upward or downward. . As a result, the electrolyzed water mist generated by the electrolyzed water mist generator 38 is not left in the pipe 37, and the electrolyzed water mist does not leak into the housing 20.

  A blowing direction variable nozzle 44 is attached to the tip of the nozzle portion 35. The blowing direction variable nozzle 44 can rotate around the axis of the nozzle portion 35 and has an elbow shape. For this reason, if the blowing direction variable nozzle 44 is pinched with a finger and rotated, the blowing direction can be changed. The blowing direction variable nozzle 44 serves as the air recirculation means in the first embodiment.

  The pedestal 10 supports the housing 20 by the following mechanism. A base-like support shaft 11 is formed at the center of the upper surface of the base 10. The support shaft 11 passes through a bearing portion 45 formed on the bottom surface of the housing 20 and protrudes from the inside of the housing 20. The pedestal 10 is provided with a plurality of rollers 12 that support the bottom surface of the housing 20. The rollers 12 are arranged at predetermined angular intervals so as to surround the bearing portion 45, and the axes thereof are aligned in the diameter direction of the support shaft 11. As described above, the plurality of rollers 12 support the housing 20, so that the housing 20 rotates stably around the support shaft 11 without being inclined or rattling.

  The housing 20 is rotated reversely with respect to the pedestal 10 so that the electric fan swings its head. For that purpose, a swing motor 46 is arranged inside the housing 20. The head motor 46 is supported by a stay 47 that rises from the bottom of the housing 20. The swing motor 46 has a horizontal axis and is a built-in reduction mechanism, and projects an output shaft 48 horizontally.

  A gear shaft 49 is fixed to the output shaft 48. The gear shaft 49 is disposed above the support shaft 11 and parallel to the diameter line of the support shaft 11, and the tip is rotatably supported by a stay 50 fixed to the bottom surface of the housing 20. A gear 51 is integrally formed on the gear shaft 49, and the gear 51 meshes with a gear portion 52 formed on the periphery of the upper surface of the support shaft 11. When the swing motor 46 rotates the gear shaft 49, the gear 51 moves along the tooth profile of the gear portion 52, and the housing 20 also rotates accordingly. When the swing motor 46 rotates the gear shaft 49 in the reverse direction, the rotation direction of the housing 20 is also reversed. As the swing motor 46 repeats normal rotation and reverse rotation, the casing 20 moves to swing its head.

  Next, the operation of the humidifier 1 will be described. When the humidifier 1 is operated, power is supplied to the blower 24, the electrolyzed water generator (not shown), and the electrolyzed water mist generator 38, and these components start their respective operations.

  When a predetermined voltage (for example, 10 V) is applied to the electrode of the electrolyzed water generating device, the water in which the electrode is immersed is electrolyzed to become electrolyzed water.

The voltage is applied so that the pair of electrodes are alternately reversed in polarity (for example, about 3 to 10 minutes every hour). If the water is tap water containing chlorine, the following electrochemical reaction occurs.
<Anode side>
4H ₂ O-4e ⁻ → 4H ⁺ + O ₂ ↑ + 2H ₂ O
2Cl ⁻ → Cl ₂ + 2e ⁻
H ₂ O + Cl ₂ ← → HClO + H ⁺ + Cl ⁻
<Cathode side>
4H ₂ O + 4e ⁻ → 2H ₂ ↑ + 4OH ⁻
<Between electrodes>
H ⁺ + OH ⁻ → H ₂ O
By the above reaction, electrolyzed water containing hypochlorous acid (HClO) and active oxygen having sterilizing action and deodorizing action is born.

  The electrolyzed water generated by the electrolyzed water generating device flows to the electrolyzed water mist generating device 38. When the ultrasonic vibrator 39 of the electrolyzed water mist generator 38 is oscillated, mist is generated from the surface of the electrolyzed water and fills the upper space of the casing 40 of the electrolyzed water mist generator 38.

  Here, when the blower 24 is driven, an air flow of the filter 26 → the air intake 22 → the blower 24 → the spray cylinder 23 is generated. The air sucked from the air intake port 22 is cleaned by collecting dust and microorganisms when passing through the filter 26. The cleaned air is sucked into the blower 24 and discharged to the duct 33.

  Electrolyzed water mist flowing out from the pipe 37 is mixed in the air that has entered the spray cylinder 23 from the duct 33. The air mixed with the electrolyzed water mist passes through the nozzle portion 35 and further passes through the blowing direction variable nozzle 44 to be blown out. FIG. 2 shows a state in which the spray cylinder 23 has the most downward elevation angle, that is, the posture in which the nozzle portion 35 is horizontal, while the blowing direction variable nozzle 44 has a state in which the blowing direction is at an upward angle. Show. In this state, the exhaust gas mixed with the electrolyzed water mist blows obliquely upward, and the electrolyzed water mist diffuses over a wide range. If the elevation angle of the spray cylinder 23 is changed so that the nozzle portion 35 faces upward, the exhaust blow-out direction can be made further upward. Normally, the humidifier 1 is used in such a manner that the exhaust is blown upward.

  When it is desired to sterilize or deodorize the filter 26, as shown in FIG. 3, the spray cylinder 23 is placed in a posture in which the elevation angle is most downward, and the blowing direction variable nozzle 44 is pinched with a finger to turn the blowing direction downward To. Then, a part of the air mixed with the electrolyzed water mist discharged from the blowing direction variable nozzle 44 returns to the air flow path 21 immediately after being discharged, and the electrolyzed water mist passes through the filter 26. As a result, the microorganisms that have been collected by the filter 26 and have propagated, or that have been trying to propagate, die or lose their vitality, and the cause of bad odor is eliminated.

  Here, the blowing direction variable nozzle 44 is rotated by hand. However, a motor for rotating the blowing direction variable nozzle 44 is provided, and the blowing direction variable nozzle 44 automatically rotates at a predetermined timing so that the blowing direction is downward. It can also be configured to change.

  4 to 7 show a second embodiment of the present invention. In the second embodiment, structural elements that are functionally common to the first embodiment are denoted by the same reference numerals used in the first embodiment, and description thereof is omitted. The same applies to the third embodiment described after the second embodiment.

  In the second embodiment, the spray direction variable nozzle 44 is not provided in the spray cylinder 23. Instead, an elevation angle changing device 60 for the spray cylinder 23 is provided. The elevation / elevation angle changing device 60 serves as air recirculation means in the second embodiment.

  A cam plate 61 that rises vertically from the pedestal 10 constitutes the elevation angle changing device 60. The cam plate 61 is fixed to the pedestal 10, and a cam surface 62 that supports the spray cylinder 23 from below is formed on the upper edge thereof. The cam surface 62 has a circular arc that is lowest at the center and higher at both ends when viewed from the front. Further, as shown in FIG. 7, the cam plate 61 has an arc shape when viewed from above, and covers an angular region in which the spray cylinder 23 can swing 60 ° left and right from the neutral position in FIG.

  An air intake 63 is formed in the cam plate 61 at a position corresponding to the air intake 22 of the housing 20. The air intake port 63 is composed of a set of horizontally long slits, but may be a set of small holes. In the case of the second embodiment, the air purification unit 25 disposed at the air intake port 22 is configured by only the filter 26 without the guard grille 27.

  The swing motor 46 rotates the casing 20 in reverse by 60 degrees left and right from the swing origin position. In this movement, the spray cylinder 23 that is in contact with the cam surface 62 by its own weight changes the elevation angle according to the undulation of the cam surface 62.

  FIG. 5 shows a state when the housing 20 reaches the swinging origin position. The spray cylinder 23 is supported by the central portion of the cam surface 62, and the elevation angle is the most downward. At this time, a part of the air mixed with the electrolyzed water mist discharged from the spray cylinder 23 returns to the air flow path 21 immediately after being discharged, and the electrolyzed water mist passes through the filter 26. As a result, the microorganisms that have been collected by the filter 26 and have propagated, or that have been trying to propagate, die or lose their vitality, and the cause of bad odor is eliminated.

  When the housing 20 swings from side to side from the state of FIG. 5 and the spray cylinder 23 is supported near the end of the cam surface 62, the elevation angle of the spray cylinder 23 becomes upward as shown in FIG. The air mixed with the electrolyzed water mist discharged from the air no longer flows back to the air circulation path 21 and is blown away far away. Thereby, electrolyzed water mist spreads in a wide range.

  As long as the swing motor 46 swings the housing 20, a part of the air mixed with the electrolyzed water mist returns to the air flow path 21 during the swing, and the filter 26 is sterilized and deodorized. If the filter 26 is sterilized and deodorized intensively, the swing motor 46 may be stopped when the casing 20 reaches the swinging origin position to stop the movement of the casing 20.

  8 to 10 show a third embodiment of the present invention. It is also the elevation angle changing device 60 of the spray cylinder 23 that constitutes the air reflux means in the third embodiment.

  In the third embodiment, the elevation angle changing device 60 includes a vertical lift plate 65 that supports the spray cylinder 23 at the upper end and a cam 66 that is displaced by a motor to give the lift plate 65 a lift operation. The elevating plate 65 is supported by a guide portion 67 provided on the inner surface of the housing 20 so that the elevating plate 65 can move up and down, and the upper end protrudes above the top surface of the housing 20 and contacts the lower surface of the nozzle portion 35 of the spray cylinder 23. A horizontal cam follower 68 protruding in the center direction of the housing 20 is formed at the lower end of the elevating plate 65, and this cam follower 68 is placed on the cam 66. The cam 66 has a shape with rounded corners at the four corners of the rhombus, and is fixed to the end of the gear shaft 49.

  When the swing motor 46 rotates the gear shaft 49, the housing 20 swings and the cam 66 also rotates. When the long axis of the rhombus of the cam 66 becomes horizontal, the elevating plate 65 is lowered most. The elevation angle of the spray cylinder 23 is also most downward. This is the state shown in FIG. At this time, a part of the air mixed with the electrolyzed water mist discharged from the spray cylinder 23 returns to the air flow path 21 immediately after being discharged, and the electrolyzed water mist passes through the filter 26. As a result, the microorganisms that have been collected by the filter 26 and have propagated, or that have been trying to propagate, die or lose their vitality, and the cause of bad odor is eliminated.

  When the long axis of the rhombus of the cam 66 becomes vertical, the elevating plate 65 rises most. As shown in FIG. 10, the elevation angle of the spray cylinder 23 becomes upward, and the air mixed with the electrolyzed water mist discharged from the spray cylinder 23 is blown away far away without being recirculated to the air flow path 21. Become. Thereby, electrolyzed water mist spreads in a wide range.

  As long as the swing motor 46 swings the housing 20, the elevation angle of the spray cylinder 23 becomes downward in the middle of swinging, and a part of the air mixed with the electrolyzed water mist flows back to the air flow path 21, and the filter 26 Is sterilized and deodorized. If the filter 26 is sterilized and deodorized intensively, the swing motor 46 is stopped when the lifting plate 65 is lowered, and the swinging of the housing 20 and the lifting plate 65 are stopped.

  Although the embodiments of the present invention have been described above, the scope of the present invention is not limited to these embodiments, and various modifications can be made without departing from the spirit of the invention.

  In the above description, the humidifier has been described as an example. However, since the humidifier includes the air purification unit 25, the humidifier described can be regarded as an air cleaner. In this case, the spray cylinder 23 can be regarded as a discharge port from which the purified air is discharged, and can be regarded as a discharge of electrolytic water mist together with the clean air discharged from the discharge port.

  The present invention is widely applicable to humidifiers.

DESCRIPTION OF SYMBOLS 1 Humidifier 10 Base 20 Case 21 Air distribution path 22 Air inlet 23 Spray cylinder 24 Blower 25 Air purification unit 26 Filter 38 Electrolyzed water mist production | generation apparatus 44 Blowing direction variable nozzle 46 Swing motor 60 Elevation angle change apparatus 61 Cam Plate 65 Lift plate 66 Cam

Claims (6)

A housing,
Formed in the housing, one end is an air intake port, the other end is a spray cylinder, and an air flow path in which a blower is arranged in the middle;
A filter disposed at the air intake;
An electrolyzed water generator built in the housing;
Similarly, the electrolyzed water generated by the electrolyzed water generating device is built in the housing, and the electrolyzed water mist generating device mixes the electrolyzed water mist into the air before being discharged from the spray cylinder.
The humidifier according to claim 1, wherein the spray cylinder is provided with air recirculation means that allows at least part of the air mixed with electrolyzed water mist to recirculate to the air flow path immediately after being discharged.   The air inlet and the spray cylinder are arranged in close proximity to the upper part of the housing, and the air recirculation means is constituted by a blowing direction variable nozzle that is rotatably attached to the tip of the spray cylinder. The humidifier according to claim 1, wherein   The humidifier according to claim 2, wherein the blowing direction variable nozzle is rotated by a motor to change an exhaust direction.   The air intake port and the spray cylinder are arranged in close proximity to the upper part of the housing, the spray cylinder is variable in elevation angle, and the air recirculation means is configured by an elevation angle changing device for the spray cylinder. The humidifier according to claim 1.   The casing is supported on the pedestal so as to be rotatable about a vertical axis, and is rotated in reverse by a swing motor, and the elevation angle changing device rises from the pedestal and lifts the spray cylinder from below. The humidifier according to claim 4, wherein the humidifier is configured by a cam plate that supports and gives a different elevation angle to the spray cylinder according to a rotation angle of the casing.   5. The humidification according to claim 4, wherein the elevation angle changing device includes a lifting plate that supports the spray cylinder at an upper end, and a cam that is displaced by a motor to give the lifting plate a lifting operation. Machine.