JP5261555B2 - Ion generator - Google Patents

Abstract

To alleviate mutual interference between electrical fields which a plurality of ion emission apparatuses emit, and to emit a high concentration of ions, an ion emission device comprises a duct (40) which forms a flow path of a gaseous medium, a first ion emission apparatus (15) which emits ions from a first region of the wall of the duct, and a second ion emission apparatus (25) which emits ions from a second region of the wall of the duct. The ion emission device further comprises an electrical field alleviation unit (45) which divides the flow path space which includes a region between the first region and the second region into a first ion emission apparatus side and a second ion emission apparatus side. The electrical field alleviation unit is configured from a conductive material for making the electrical field alleviation unit equipotential.

Description

  The present invention relates to an ion generator having a plurality of ion generators.

  In recent years, ion generators have been used to purify, sterilize, or deodorize indoor air. For example, in an ion generator, an ion generator that generates positive ions and negative ions is arranged in the middle of a ventilation path inside the apparatus, and the generated ions are discharged to an external space. Here, the positive ions and negative ions released from the ion generator have the effect of purifying, deodorizing or sterilizing the air.

  A standard ion generator generates corona discharge by applying a high-voltage driving voltage between a needle electrode and a counter electrode to generate positive ions or negative ions.

  Since there is a limit to the amount of ions generated by one ion generator, the ions generated by a plurality of ion generators arranged in the ventilation path are released to the external space, and the ion generator releases them. Attempts have been made to increase the total amount of ions. Here, even if a plurality of ion generators are provided in the ventilation path space, it has been known that the amount of ions does not increase in proportion to the number of ion generators provided.

  Patent Document 1 describes an ion generator shown in FIG. In the ion generating apparatus, the connecting wall 141, the connecting portion 142, and the duct 140 allow the air sucked from the suction ports 195 and 195 to be supplied from two of the ion generators 115a and 115c and the ion generators 115b and 115d, respectively. To the other fitting hole 111 and the other fitting hole 111. In addition, the ion generators 115a and 115d and the ion generators 115b and 115c are alternately turned on / off every second, and the ion generators 115a and 115d are turned on / off in the same phase every second. is there.

JP 2010-55960 A

  In the ion generator, when corona discharge occurs and ions are generated, a non-uniform electric field (hereinafter referred to as “electric field”) is generated around the electrode.

  When the electric field generated by a predetermined ion generator causes mutual interference between the electric fields that affect the electric fields generated by different ion generators, the ion generation capability of each ion generator decreases. Here, it is considered that such mutual interference of electric fields is one of the reasons that the amount of ions does not increase in proportion to the number of ion generators provided.

  Therefore, if the ion generator is partitioned by the wall of the ventilation path as in the ion generator described in Patent Document 1, there is a possibility that the electric field may interfere with each other beyond the wall of the ventilation path. In such a case, the ion generation capability of each ion generator cannot be fully exhibited.

  The present invention has been made in view of the above problems, and an object of the present invention is to suppress the mutual interference of electric fields generated by a plurality of ion generators and generate an ion of high concentration. The purpose is to provide.

An ion generator according to the present invention is an ion generator including a duct that forms a flow path of a gaseous medium, and a first ion generator and a second ion generator that are formed in the duct , and the duct includes the gas An inner wall that separates the flow path of the medium into a first ventilation path and a second ventilation path, wherein the first ion generator is in the first ventilation path, the second ion generator is in the second ventilation path, and has been arranged spaced to the inner wall, said inner wall, said inhibit field suppressing unit an electric field of the first ion generator and the second ion generator is formed, the electric field suppression section, the It is composed of a conductive member for a duct with different materials and equipotential electric field suppression section Rutotomoni, an ion generation region of at least the first ion generator or ion generator of the second ion generator Includes area of the same size Characterized in that it is formed as.

  Preferably, the equipotential potential is a ground potential.

  Preferably, the first ion generator has a plurality of ion generating elements for generating ions, and the plurality of ion generating elements are driven alternately.

  In the ion generator of this invention, it becomes possible to suppress the mutual interference of the electric field which a 1st ion generator and a 2nd ion generator generate | occur | produce by an electric field suppression part, and to generate a high concentration ion.

It is a perspective view showing the whole ion generator 1 composition concerning a 1st embodiment. It is the top view seen from one direction which shows the whole structure of the ion generator 1 which concerns on 1st Embodiment. It is a timing chart which shows the time at the time of each ion generating element of the ion generator 1 changing to an ON state or an OFF state. 4 is a flowchart showing a processing procedure of an ion generation controller 80. It is a perspective view which shows the whole structure of the ion generator 2 which concerns on 2nd Embodiment. 4 is a timing chart showing the timing when each ion generating element of the ion generator 2 transitions to an on state or an off state. 5 is a flowchart showing a processing procedure of an ion generation controller 81. It is the top view seen from one direction which shows the whole structure of the ion generator 3 which concerns on 3rd Embodiment. It is a figure which shows the structure of the conventional ion generator.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description of the processing contents, “step” is represented by “S”, and each processing is distinguished by a number.

[First Embodiment]
FIG.1 and FIG.2 shows schematic structure of the ion generator 1 which concerns on 1st Embodiment, The structure of the ion generator 1 is demonstrated below using this figure.

  The ion generator 1 includes a duct 40, a blower unit 50, and an ion generation controller 80 that controls drive elements of various electronic devices built in the ion generator 1.

  The blower unit 50 incorporates a blower 51 and takes in external air from an inlet 55 provided on a side surface of the blower unit 50, and the external air is taken into the first inlet 12 or the second inlet 22 of the duct 40. To blow. Here, instead of external air, another gas medium for generating ions may be blown to the duct 40.

  The duct 40 forms a flow path for discharging the gaseous medium blown from the blower unit 50 to the discharge port together with the generated ions. Specifically, it is configured in a cylindrical shape so that the hollow portion becomes a flow path of the gas medium by combining a single member or a plurality of members made of a dielectric material.

  Further, the duct 40 is formed with an inner wall 41 for diverting a flow path for discharging the gaseous medium blown from the blower unit 50 to the discharge port into two paths.

  Specifically, the appearance of the duct 40 has a substantially rectangular shape, and the duct 40 is formed with two flow paths of the first ventilation path 10 and the second ventilation path 20 having the same shape and the same size. Yes. The first ventilation path 10 is a flow path for discharging the gaseous medium blown from the blower unit 50 through the first inlet 12 to the first discharge port 11, and the second ventilation path 20 is connected to the first ventilation path 50 from the blower unit 50. 2 is a flow path for discharging the gaseous medium blown through the two inlets 22 to the second outlet 21.

  Here, in the following description, the Z-axis direction of the three-dimensional axis that discharges the blown gas medium is referred to as the “channel axis direction”, and the side wall surface or the inner wall 41 surface on which the channel axis direction and the ion generator are disposed. The X-axis direction orthogonal to each other is referred to as a “wall surface horizontal axis direction”.

  A negative ion generator 15 is provided on the side wall of the first ventilation path 10 facing the inner wall 41 separating the first ventilation path 10 and the second ventilation path 20, and a positive ion is provided on the side wall of the second ventilation path 20 facing the inner wall 41. A generator 25 is provided. Further, these ion generators are disposed at the distance L1 from the discharge ports 11 and 21 in the flow path axis direction and at the center of the side wall in the wall surface horizontal axis direction.

  On the inner wall 41, for example, an electric field suppressing portion 45 made of a conductive member such as a metal plate is formed. And in order to make the electric field suppression part 45 equipotential, it is possible to electrically ground a part of the electric field suppression part 45 by the configuration of the electric field suppression part 45 and the peripheral members of the electric field suppression part 45. .

  Further, the electric field suppression unit 45 generates ions from at least the negative ion generator 15 or the positive ion generator 25 around the center of the inner wall 41 in the horizontal axis direction of the wall and the point that is the distance L1 from the discharge port in the axial direction of the flow path. It is formed so as to include a surface region having the same size as the region.

  The negative ion generator 15 includes a first negative ion generation element 15 a and a second negative ion generation element 15 b that generate negative ions, and a first drive element 18. Further, the first negative ion generating element 15a and the second negative ion generating element 15b are independently controlled to be turned on via the first driving element 18, and negative ions are generated by being turned off. Is configured to stop.

  Similarly, the positive ion generator 25 includes a first positive ion generation element 25 a and a second positive ion generation element 25 b that generate positive ions, and a second drive element 28. Further, positive ions are generated by controlling the first positive ion generating element 25a and the second positive ion generating element 25b independently through the second driving element 28, and generating positive ions by controlling the off. Is configured to stop.

  Here, each ion generating element has a series of ion generating processes including a process of generating a corona discharge by applying a high driving voltage between the needle electrode and the counter electrode. It is configured to start repeating in a predetermined cycle by being performed and to end by performing OFF control.

  Such ion generation element on / off control is performed by an ion generation controller 80 connected to the first drive element 18 and the second drive element 28.

  FIG. 3 shows the timing when each of the first negative ion generation element 15a, the second negative ion generation element 15b, the first positive ion generation element 25a, and the second positive ion generation element 25b transitions to an on state or an off state. Is shown.

  As shown in the figure, during the period ST1 in which the first negative ion generation element 15a and the first positive ion generation element 25a are in the ON state, the second negative ion generation element 15b and the second positive ion generation element 25b The state is off.

  Further, during the period ST2 in which the first negative ion generating element 15a and the first positive ion generating element 25a are in the off state, the second negative ion generating element 15b and the second positive ion generating element 25b are in the on state. ing.

  The state is repeatedly switched from ST1 to ST2 or from ST2 to ST1 in units of switching period T seconds.

  In this way, in the ion generation controller 80, the first drive element 18 and the second drive element 28 are used to alternately drive the ion generation elements disposed in the same ventilation path so as not to be turned on at the same time. To control. Here, for example, the on / off control of the first negative ion generating element 15a and the first positive ion generating element 25a disposed in different ventilation paths may not necessarily be synchronized.

  FIG. 4 shows a processing procedure of the ion generation controller 80 and will be described below.

  The ion generation controller 80 outputs a control signal for turning on the first negative ion generation element 15a and turning off the second negative ion generation element 15b to the first drive element 18 (S100). Then, a control signal for turning on the first positive ion generating element 25a and turning off the second positive ion generating element 25b is output to the second driving element 28 (S101).

  Subsequent to the above processing, the process waits until a predetermined switching period T seconds elapses (S102).

  Following the above processing, a control signal for turning off the first negative ion generating element 15a and turning on the second negative ion generating element 15b is output to the first driving element 18 (S103). Then, a control signal for turning off the first positive ion generating element 25a and turning on the second positive ion generating element 25b is output to the second driving element 28 (S104).

  Following the above process, the process waits until a predetermined switching period T seconds elapses (S105), and the process proceeds to S100 described above.

  Thus, in the ion generator 1 according to the first embodiment, the flow between the surface region where the negative ion generator 15 generates negative ions and the surface region where the positive ion generator 25 generates positive ions. The road space is divided into a negative ion generator 15 side and a positive ion generator 25 side by an electric field suppression unit 45 formed on the inner wall 41. From this, in the ion generator 1, the mutual interference of the electric field which the negative ion generator 15 and the positive ion generator 25 generate | occur | produce can be suppressed, and high concentration ion can be generated.

  Here, each of the negative ion generator 15 and the positive ion generator 25 has two ion generation elements. However, the ion generation controller 80 performs a process of driving these two ion generation elements alternately so that they are not turned on at the same time. From this, in the ion generator 1, the mutual interference of the electric field between ion generating elements is also suppressed, and the ion generating ability of each ion generating element can be fully exhibited.

[Second Embodiment]
FIG. 5 shows a schematic configuration of the ion generator 2 according to the second embodiment, and the configuration of the ion generator 2 will be described with reference to FIG. Note that the same reference numerals are assigned to the same components as those described above. Therefore, description of these components is omitted.

  The ion generator 2 is different from the ion generator 1 described above only in that each ion generator is composed of two ion generating elements that generate ions of different polarities. .

  As shown in FIG. 5, a first positive / negative ion generator 16 is disposed on the side wall on the first ventilation path 10 side. A second positive / negative ion generator 26 is disposed on the side wall of the second ventilation path 20.

  The first positive / negative ion generator 16 includes a first negative ion generating element 16 a that generates negative ions, a first positive ion generating element 16 b that generates positive ions, and a first driving element 19. Further, the first negative ion generating element 16a and the first positive ion generating element 16b are independently generated by controlling the on state via the first driving element 19, and the generation of ions is stopped by controlling the off state. It is configured to

  Similarly, the second positive / negative ion generator 26 includes a second positive ion generation element 26 a that generates positive ions, a second negative ion generation element 26 b that generates negative ions, and a second drive element 29. Furthermore, the second positive ion generation element 26a and the second negative ion generation element 26b are independently controlled to be turned on by the second drive element 29, and the generation of ions is stopped by being turned off. It is configured to

  Such ion generation element on / off control is performed by an ion generation controller 81 connected to the first drive element 19 and the second drive element 29.

  FIG. 6 shows the timing when each of the first negative ion generating element 16a, the first positive ion generating element 16b, the second positive ion generating element 26a, and the second negative ion generating element 26b transitions to the on state or the off state. Show.

  As shown in this figure, during the period ST3 in which the first negative ion generating element 16a and the second positive ion generating element 26a are in the ON state, the first positive ion generating element 16b and the second negative ion generating element 26b The state is off.

  Further, during the period ST4 in which the first negative ion generating element 16a and the second positive ion generating element 26a are in the off state, the first positive ion generating element 16b and the second negative ion generating element 26b are in the on state. ing.

  Then, the state is repeatedly switched from ST3 to ST4 or from ST4 to ST3 in units of switching period T seconds.

  In this way, in the ion generation controller 81, the first drive element 19 and the second drive element 29 are used to alternately drive the ion generation elements arranged in the same ventilation path so as not to be turned on at the same time. To control.

  FIG. 7 shows a processing procedure of the ion generation controller 81, which will be described below.

  The ion generation controller 81 outputs a control signal for turning on the first negative ion generation element 16a and turning off the first positive ion generation element 16b to the first drive element 19 (S200). Then, a control signal for turning on the second positive ion generating element 26a and turning off the second negative ion generating element 26b is output to the second driving element 29 (S201).

  Subsequent to the above processing, the process waits until a predetermined switching period T seconds elapses (S202).

  Following the above processing, a control signal for turning off the first negative ion generating element 16a and turning on the first positive ion generating element 16b is output to the first driving element 19 (S203). Then, a control signal for turning off the second positive ion generating element 26a and turning on the second negative ion generating element 26b is output to the second driving element 29 (S204).

  Following the above process, the process waits until a predetermined switching period T seconds elapses (S205), and the process proceeds to S200 described above.

  Thus, in the ion generator 2 which concerns on 2nd Embodiment, between the surface area | region where the 1st positive / negative ion generator 16 generates ion, and the surface area | region where the 2nd positive / negative ion generator 26 generates ion. Is divided into a first positive / negative ion generator 16 side and a second positive / negative ion generator 26 side by an electric field suppressing portion 45 formed on the inner wall 41. From this, in the ion generator 2, the mutual interference of the electric field which the 1st positive / negative ion generator 16 and the 2nd positive / negative ion generator 26 generate | occur | produce can be suppressed, and high concentration ion can be generated.

  Here, the first positive / negative ion generator 16 and the second positive / negative ion generator 26 each have two ion generating elements. However, the ion generation controller 81 performs a process of alternately driving these two ion generation elements so that they are not turned on at the same time. From this, in the ion generator 2, the mutual interference of the electric field between the ion generating elements is also suppressed, and the ion generating ability of each ion generating element can be sufficiently exhibited.

[Third Embodiment]
FIG. 8 shows a schematic configuration of the ion generator 3 according to the third embodiment, and the configuration of the ion generator 3 will be described with reference to FIG. Note that the same reference numerals are assigned to the same components as those described above. Therefore, description of these components is omitted.

  Further, the ion generator 3 is different from the above-described ion generator 1 in the arrangement of the ion generators.

  Here, in the following description, the Z-axis direction of the three-dimensional axis that discharges the blown gas medium is defined as the “channel axis direction”, and the channel axis direction is orthogonal to the side wall surface on which the ion generator is disposed. The axial direction is referred to as “side wall surface horizontal axis direction”, and the X axis direction orthogonal to the flow path axis direction on the inner wall 41 surface is referred to as “inner wall surface horizontal axis direction”.

  As shown in FIG. 8, the ion generator 3 according to the third embodiment is provided on the side of the first ventilation path 10 on the side wall orthogonal to the inner wall 41 that separates the first ventilation path 10 and the second ventilation path 20. A negative ion generator 15 is provided. And the positive ion generator 25 is arrange | positioned by the 2nd ventilation path 20 side of the side wall in which the negative ion generator 15 is arrange | positioned. Further, the negative ion generator 15 and the positive ion generator 25 are arranged on the side wall surface at a point that is a distance L2 from the discharge port in the flow path axis direction.

  On the inner wall 41, for example, an electric field suppressing portion 46 made of a conductive member such as a metal plate is formed. And in order to make the electric field suppression part 46 equipotential, it is possible to electrically ground a part of the electric field suppression part 46 by the configuration of the electric field suppression part 46 and the peripheral members of the electric field suppression part 46. .

  Furthermore, the flow path axial direction of the electric field suppressing unit 46 is a distance from the discharge point in the direction of the flow axis and the center of the arrangement point of the negative ion generator 15 and the positive ion generator 25 in the horizontal direction of the side wall surface. Centering on the point which is L2, it forms so that the line segment area | region of the same size as the flow-path axial direction of the negative ion generator 15 or the positive ion generator 25 may fully be included.

  Further, it is most preferable that the horizontal direction of the inner wall surface of the electric field suppressing unit 46 extends from the arrangement side wall where the ion generator is disposed to the facing side wall facing the arrangement side surface. However, mutual interference of the electric field in the vicinity of the facing side wall is unlikely to occur, and therefore, it is not necessary to reach the facing side wall.

  Thus, in the ion generator 3 according to the third embodiment, the ions between the surface region where the negative ion generator 15 generates negative ions and the surface region where the positive ion generator 25 generates positive ions. The flow path space starting from the side wall surface where the generator is disposed is divided into the negative ion generator 15 side and the positive ion generator 25 side by an electric field suppressing portion 46 formed on the inner wall 41.

  From this, it becomes possible to suppress the mutual interference of the electric field which the negative ion generator 15 and the positive ion generator 25 generate | occur | produce, and to generate high concentration ion.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

1, 2, 3 Ion generator 10 First ventilation path 11 First outlet 12 First inlet 15 Negative ion generator 15a First negative ion generator 15b Second negative ion generator 16 First positive / negative ion generator 16a First negative ion generating element 16b First positive ion generating elements 18, 19 First driving element 20 Second ventilation path 21 Second outlet 22 Second inlet 25 Positive ion generator 25a First positive ion generating element 25b Second Positive ion generating element 26 Second positive / negative ion generator 26a Second positive ion generating element 26b Second negative ion generating element 28, 29 Second drive element 40 Duct 41 Inner wall 45, 46 Electric field suppression unit 50 Blower unit 51 Blower 55 Inlet 80, 81 ion generation controller

Claims (3)

An ion generator having a duct that forms a flow path of a gaseous medium, and a first ion generator and a second ion generator formed in the duct ,
The duct has an inner wall that separates the flow path of the gaseous medium into a first ventilation path and a second ventilation path,
The first ion generator is disposed in the first ventilation path, and the second ion generator is disposed in the second ventilation path, separated from the inner wall,
On the inner wall, an electric field suppression unit that suppresses an electric field of the first ion generator and the second ion generator is formed,
The electric field reduction unit, Rutotomoni is composed of a conductive member for the equipotential electric field suppressing portion of a different material as the duct, at least the first ion generator or said second ion generator of the ion An ion generator characterized by being formed so as to include a surface area having the same size as the generation area .   The ion generator according to claim 1, wherein the equipotential potential is a ground potential. The first ion generator has a plurality of ion generating elements for generating ions,
Wherein the plurality of ion generating element, an ion generating apparatus according to claim 1 or 2, characterized in that it is alternately driven.