JP2016180515A - Air modification apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air modification apparatus including a Sirocco fan and a fan casing storing the Sirocco fan in which bactericidal action with positive ion and negative ion is also applied to the Sirocco fan with scarcely applying influence against the amount of positive ion and negative ion discharged into a room.SOLUTION: An air cleaner 1 comprises a Sirocco fan 16 and a fan casing 14 storing the Sirocco fan. The fan casing 14 includes an involute wall 14a which an outer circumferential surface of the Sirocco fan 16 oppositely faces and both side walls where both side surfaces of the Sirocco fan 16 oppositely face. An ion generating device 30 for generating positive ion and negative ion is installed in at least one of both side walls. A location in the side walls that is near the outer circumferential part of the Sirocco fan 16 is selected as an installation location for the ion generating device 30.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an air reformer that aims to improve indoor air quality, such as an air purifier or an air conditioner, and more particularly to an air reformer that uses ions to improve air quality.

  Various types of air reforming devices that use ions to improve indoor air quality have been proposed. One example can be seen in Patent Document 1.

  Patent Document 1 describes an air conditioner. This air conditioner has a sirocco fan and a casing that accommodates the sirocco fan, and an ion generator is disposed in the ventilation path in the casing so that the discharge surface faces the outer peripheral surface of the sirocco fan. With this configuration, “the air blown from the sirocco fan 151 directly comes into contact with the discharge surface 172 of the ion generator 170. Therefore, positive ions or negative ions discharged from the ion generator 170 are efficiently included in the airflow. "(Paragraph [0051]).

  Various types of ion generators have been put into practical use, and examples thereof can be seen in Patent Documents 2 and 3. The ion generator described in Patent Document 2 generates positive ions and negative ions using two needle-like electrodes. In the ion generator described in Patent Document 3, the number of needle-like electrodes is four.

JP-A-2005-76906 JP 2014-212871 A JP 2014-35844 A

  The bactericidal action by positive and negative ions is well known. I would like to have a positive ion and negative ion sterilization effect on the fan of air reforming equipment that easily adheres to dust, but if an ion generator is simply placed on the windward side of the fan, the air passes through the fan. At this time, positive ions and negative ions collide with each other and are neutralized, and the amount of positive ions and negative ions released into the room is reduced.

  The present invention has been made in view of the above points, and in an air reformer equipped with a sirocco fan and a fan casing that houses the sirocco fan, the amount of positive ions and negative ions released into the room is greatly affected. An object of the present invention is to provide an air reforming apparatus that can exert a sterilizing effect on positive and negative ions on a sirocco fan.

  An air reforming apparatus according to the present invention includes a sirocco fan and a fan casing that accommodates the sirocco fan. The fan casing includes an involute wall that faces the outer peripheral surface of the sirocco fan, and both sides that face both sides of the sirocco fan. An ion generating device that generates positive ions and negative ions is disposed on at least one side wall of the both side walls, and a location in the side wall adjacent to the outer periphery of the sirocco fan is It is characterized by being selected as an ion generator arrangement location.

  In the air reformer having the above-described configuration, it is preferable that a communication port through which air sucked into the sirocco fan passes is formed in the side wall on which the ion generator is disposed.

  In the air reforming apparatus having the above configuration, the ion generator is preferably embedded in a recess formed in the side wall.

  The air flow generated by the rotation of the sirocco fan is not all the air flow that is discharged from the outer peripheral surface of the sirocco fan and directed toward the air outlet of the fan casing. An accompanying flow that flows along with the rotation of the sirocco fan is generated between the side surface of the sirocco fan and the side wall of the fan casing. Most of the positive ions and negative ions generated from the ion generator located in the side wall near the outer periphery of the sirocco fan are carried away by the air flow toward the outlet, but some of them are accompanied It is mixed. When an accompanying flow in which positive ions and negative ions are mixed is sucked into and discharged from the sirocco fan, the sirocco fan is sterilized by the positive ions and negative ions. Thereby, the sirocco fan itself can be sterilized without greatly reducing the amount of positive ions and negative ions released into the room. Further, the sirocco fan itself and attached dust are neutralized by positive and negative ions, and dust accumulation is suppressed.

It is a front view of the air cleaner concerning a 1st embodiment of the present invention. It is a vertical sectional view of the air cleaner of FIG. It is a horizontal sectional view of the air cleaner of FIG. FIG. 3 is a vertical sectional view showing a state where a sirocco fan is removed from FIG. 2. It is the vertical sectional view which cut | disconnected the air cleaner of FIG. 1 along the AA line. It is a vertical sectional view of an air cleaner concerning a 2nd embodiment of the present invention. It is the vertical sectional view of the state which looked at the air cleaner of Drawing 6 from the back. It is sectional drawing of the sirocco fan used for the air cleaner which concerns on 3rd Embodiment of this invention.

<First Embodiment>
An air cleaner is taken up as an example of an air reforming apparatus, and a first embodiment thereof is shown in FIGS. The air purifier 1 includes a thin box-shaped casing 10 having a frontal shape of a rounded square and a small depth in front and rear as compared with the vertical and horizontal dimensions. An intake port 11 (see FIG. 5) formed of a collection of many small holes is formed on the back surface of the housing 10, and a filter chamber 12 is defined inside the intake port 11.

  A filter 13 for collecting dust is stored in the filter chamber 12. The filter 13 is a HEPA filter. The filter chamber 12 and the filter 13 are each divided into two upper and lower parts, and a predetermined gap is provided between the two upper and lower parts. A motor for rotating a sirocco fan, which will be described later, is disposed in this gap.

  A fan casing 14 is formed between the filter chamber 12 and the front surface of the housing 10. The fan casing 14 includes a spiral air flow path portion that receives the air discharged from the fan and guides it toward the outlet. The spiral air flow path portion has an involute shape whose cross-sectional area gradually increases toward the downstream side.

  The inside of the filter chamber 12 and the inside of the fan casing 14 communicate with each other through a communication port 15 (see FIG. 4) that is a set of many small holes. A communication port 15 is provided in each of the upper and lower filter chambers 12.

  A sirocco fan 16 is disposed inside the fan casing 14. The sirocco fan 16 has a structure in which a large number of blades 16b are arranged on the periphery of a circular main plate 16a, and a plurality of communication ports 16c made of circular holes are arranged in a ring shape at the center of the main plate 16a. The sirocco fan 16 rotates counterclockwise in the fan casing 14 in FIG. The end of the fan casing 14 is a blowout port 17. The blower outlet 17 is open to the top surface of the housing 10.

  As shown in FIG. 3 or FIG. 5, the fan casing 14 includes an involute wall 14 a that faces the outer peripheral surface of the sirocco fan 16 and side walls 14 b and 14 c that face both sides of the sirocco fan 16. A partition wall separating the filter chamber 12 and the fan casing 14 serves as a side wall 14b, and a front wall of the housing 10 serves as a side wall 14c. The communication port 15 is formed in the side wall 14b. The involute wall 14a gives the spiral air flow path portion an involute shape whose cross-sectional area gradually increases toward the downstream side.

  The involute wall 14 a is formed with a protruding portion 14 d that forms a throat portion that becomes the beginning of the blowout port 17. The involute wall 14a is closest to the outer peripheral surface of the sirocco fan 16 at the location of the protrusion 14d.

  When a motor 18 (see FIG. 3) disposed in the gap between the upper and lower filter chambers 12 rotates the sirocco fan 16, room air is sucked into the filter chamber 12 from the intake port 11. The sucked air passes through the filter 13, and dust in the air is collected by the filter 13. The air purified by passing through the filter 13 enters the fan casing 14 through the communication port 15 and is sucked into the sirocco fan 16. The air sucked into the sirocco fan 16 is discharged from the outer periphery of the sirocco fan 16, turns inside the fan casing 14, and is blown upward from the air outlet 17.

  A wind direction plate 20 is disposed at the air outlet 17. The wind direction plate 20 has a long rectangle in the left-right direction. The wind direction plate 20 causes the air direction changing surface 21 on one side to interfere with the air flow blown out from the air outlet 17 to change the air blowing direction. In the air cleaner 1, the wind direction plate 20 changes the air blowing direction toward the front by the wind direction changing surface 21.

  The wind direction plate 20 is attached to the air outlet 17 so as to be able to rotate in a vertical plane with the rear end as the center of rotation, and is held in one of the following two postures by a motor (not shown). The first posture is a posture in which the air blowing direction is changed by the wind direction changing surface 21, and this is shown in FIG. A 2nd attitude | position is an attitude | position which closes the blower outlet 17. FIG. The surface opposite to the wind direction changing surface 21 of the wind direction plate 20 is a flat surface, and this flat surface is flush with the top surface of the housing 10 when the wind direction plate 20 closes the outlet 17.

The air cleaner 1 mixes ions generated by the ion generator 30 into the air blown from the blowout port 17. The ion generator 30 generates a plasma discharge by applying a high-voltage AC voltage between the electrodes, charges water molecules in the air, and positive ions H ⁺ (H ₂ O) _m (m is an arbitrary natural number) and negative. Ion O ₂ ⁻ (H ₂ O) _n (n is an arbitrary natural number) is generated. These positive ions and negative ions cause a chemical reaction on the cell surface of airborne bacteria in the air to generate hydrogen peroxide H ₂ O ₂ or hydroxyl radicals / OH which are active species. Due to the action of the active species, the cell membrane of suspended bacteria is destroyed, and the suspended bacteria are sterilized. Thereby, indoor air can be purified.

  The ion generator 30 is disposed on the side wall 14 b of the fan casing 14, particularly in a location close to the outer periphery of the sirocco fan 16. A recess 31 is formed in the side wall 14b, and the ion generator 30 is embedded therein.

  The ion generator 30 generates positive ions and negative ions by two needle-like electrodes 30a and 30b. The needle-like electrode 30a is placed at a position closer to the sirocco fan 16 than the needle-like electrode 30b, that is, a position substantially aligned with the outer peripheral surface of the sirocco fan 30a when viewed from the front.

  The ion generator 30 is provided with two needle-like electrodes as in the ion generator described in Patent Document 2, but the four needle-like electrodes are provided as in the ion generator described in Patent Document 3. It may be provided.

  When the ion generator 30 is operated while the sirocco fan 16 is rotated, positive and negative ions generated from the ion generator 30 are included in the air flow generated by the rotation of the sirocco fan 16. Most of the air flow containing ions goes directly to the air outlet 17 and is blown out from the air outlet 17 to sterilize the room.

  A part of the air flow containing ions does not go to the blowout port 17 as it is, but becomes an accompanying flow that rotates with the rotation of the sirocco fan 16 between the side surface of the sirocco fan 16 and the side wall 14b of the fan casing 14. This accompanying flow is finally sucked into the sirocco fan 16 and discharged through the blades 16b. As the air moves, positive ions and negative ions come into contact with the surface of the sirocco fan 16, and at this time, bacteria attached to the surface of the sirocco fan 16 are sterilized by the mechanism described above.

  The air passage in the fan casing 14 including the sirocco fan 16 is prevented from being charged by being in contact with ions. Thereby, dust adhesion with respect to the fan casing 14 and the sirocco fan 16 is suppressed, and the air cleaner 1 can be used hygienically.

  The action of mixing positive ions and negative ions in the accompanying flow generated between the side surface of the sirocco fan 16 and the side wall 14b of the fan casing 14 as the sirocco fan 16 rotates is caused by the outer periphery of the sirocco fan 16 on the side wall 14b. This is caused by arranging the ion generator 30 in a close location. If the ion generator 30 is arranged at the location of the involute wall 14a as in Patent Document 1, such an action does not occur.

  It is also possible to arrange the ion generator 30 on the side of the side wall 14 c of the fan casing 14. It is good also as providing the ion generator 30 in both the side walls 14b and 14c.

Second Embodiment
6 and 7 show a second embodiment of the air purifier 1. The air cleaner 1 according to the second embodiment is characterized in that in addition to the configuration of the air cleaner 1 of the first embodiment, a sensor for knowing the state of room air is provided.

  6 and 7 show two types of sensors. The first sensor is a dust sensor 40 that measures the amount of dust in the air. The second sensor is a gas sensor 41 that measures the amount of gas that is not preferably present in a large amount in the air. Needless to say, the combination of the dust sensor 40 and the gas sensor 41 is merely an example, and may be limited to only one or may be combined with other types of sensors.

  A sensor air passage 42 is formed in the gap between the upper and lower filter chambers 12, and a dust sensor 40 and a gas sensor 41 are disposed in the sensor air passage 42. The dust sensor 40 is placed on the upstream side of the sensor air passage 42, and the gas sensor 41 is placed on the downstream side of the sensor air passage 42.

  An inlet of the sensor air passage 42 is provided on the back surface of the housing 10. This inlet is not shown. The outlet 42 a of the sensor air passage 42 opens at a position on the windward side of the filter 13 on the inner side wall of the upper filter chamber 12. This position is also a position close to the communication port 15 that allows the upper filter chamber 12 and the inside of the fan casing 14 to communicate with each other.

  As a matter of course, the air suction force generated at the communication port 15 when the sirocco fan 16 rotates strongly acts on a portion of the filter 13 that is close to the communication port 15. Since the outlet 42a of the sensor air passage 42 is provided at this location, a stable air flow can be secured in the sensor air passage 42 with the negative pressure acting on the outlet 42a. Thereby, the fall of the detection sensitivity of dust or gas can be prevented.

  Since air exits to the windward side of the filter 13 through the outlet 42a, air that does not pass through the filter 13, that is, uncleaned air, is not blown out from the air cleaner 1.

  In order to make air suction through the sensor air passage 42 more powerful, a nozzle may be attached to the outlet 42 a and the outlet of the nozzle may be placed at a position facing the communication port 15 with the filter 13 therebetween.

<Third Embodiment>
FIG. 8 shows a third embodiment of the air cleaner 1. The air cleaner 1 according to the third embodiment is characterized in that, in addition to the configuration of the air cleaner 1 of the first embodiment or the second embodiment, a sirocco fan 16 having the structure shown in FIG. 8 is used. It has become.

  In the sirocco fan 16 shown in FIG. 8, a ring-shaped convex portion 16 d facing the side wall 14 b of the fan casing 14 is formed on the main plate 16 a. The tip of the convex portion 16d faces the side wall 14b with a slight interval.

  When the sirocco fan 16 is rotating, when the sirocco fan 16 is tilted for some reason, the protrusion 16d contacts the side wall 14b before the blade 16b contacts the side wall 14b, and the sirocco fan 16 is further tilted. Do not leave. This prevents the blade 16b from coming into contact with the side plate 14b and causing the blade 16b to be chipped.

  For the purpose of vibration isolation, an elastic body such as rubber is often interposed between the rotating shaft of the motor 18 and the sirocco fan 16. Although the sirocco fan 16 configured as described above is easy to tilt, the risk of the blades 16b coming into contact with the side plates 14b can be reduced by providing the convex portions 16d.

  Instead of providing the convex portion 16d on the sirocco fan 16 side, a ring-shaped convex portion facing the main plate 16a of the sirocco fan 16 may be provided on the side plate 14b side.

  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.

  INDUSTRIAL APPLICABILITY The present invention is widely applicable to an air reforming apparatus that includes a sirocco fan and a fan casing that accommodates the sirocco fan and blows out an air flow containing positive ions and negative ions generated by an ion generator.

DESCRIPTION OF SYMBOLS 1 Air cleaner 10 Case 11 Intake port 12 Filter chamber 13 Filter 14 Fan casing 14a Involute wall 14b, 14c Side wall 15 Communication port 16 Sirocco fan 30 Ion generator 30a, 30b Needle-shaped electrode 31 Recessed part

Claims (3)

An air reformer equipped with a sirocco fan and a fan casing that houses the sirocco fan,
The fan casing includes an involute wall facing an outer peripheral surface of the sirocco fan, and both side walls facing both side surfaces of the sirocco fan,
An ion generator for generating positive ions and negative ions is disposed on at least one side wall of the both side walls,
An air reforming apparatus characterized in that a location close to the outer periphery of the sirocco fan in the side wall is selected as an arrangement location of the ion generator.   The air reformer according to claim 1, wherein a communication port through which air sucked into the sirocco fan passes is formed in the side wall where the ion generator is disposed.   The air reformer according to claim 1 or 2, wherein the ion generator is embedded in a recess formed in the side wall.