CN1791467B - Ion generating element, ion generator, and electric device - Google Patents
Ion generating element, ion generator, and electric device Download PDFInfo
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- CN1791467B CN1791467B CN200480013304.6A CN200480013304A CN1791467B CN 1791467 B CN1791467 B CN 1791467B CN 200480013304 A CN200480013304 A CN 200480013304A CN 1791467 B CN1791467 B CN 1791467B
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Images
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- Disinfection, Sterilisation Or Deodorisation Of Air (AREA)
- Air Filters, Heat-Exchange Apparatuses, And Housings Of Air-Conditioning Units (AREA)
- Cold Air Circulating Systems And Constructional Details In Refrigerators (AREA)
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Abstract
An ion generating element (10) has at least one first discharger (12) for generating positive ions and at least one second discharger (13) for generating negative ions, both fitted or printed on a single dielectric member (11). The first and second dischargers (12) and (13) are each composed of a pair of a first or second discharging electrode (12a) or (13a), respectively, formed on the surface of the dielectric member (11) and a first or second induction electrode (12b) or (13b), respectively, buried in the dielectric member (11), and are arranged both on the same flat surface of the dielectric member (11) but separately from and independently of each other. This construction helps to alleviate the neutralization among the generated ions themselves, thus to effectively release both positive and negative ions, and thereby to enhance the ion generation efficiency.
Description
Technical field
Thereby the present invention relates to by in the space, emitting cation and anion can decompose ion generating device, the ion generating device of the bacterium that swims and fungi, harmful substance etc. and be equipped with this device in air electrical equipment.Have again, as the example corresponding, mainly can enumerate the air-conditioner that in enclosure space (in the room in the family housing, in the mansion, the ward of hospital and operating room, the car, in the aircraft, in the ship, in the warehouse, in the storehouse of freezer etc.), uses, dehumidifier, humidifier, air cleaner, freezer, fan-shaped heater, micro-wave oven, scrubbing-and-drying unit, dust catcher, sterilizing unit etc. with above-mentioned electrical equipment.
Background technology
Generally, in the few closed room of ventilations such as office and meeting room, when indoor number for a long time because the air pollutant of the smog of the carbon dioxide by breathe discharging, cigarette, dust etc. increases, have the anion that makes the people loosen effect and from air, reduce.Particularly, when the smog of cigarette exists, anion even reduce to common about 1/2~1/5.Therefore, for the anion in the auxiliary air, selling various ion generating devices on the market now.
But the existing ion generating device that utilizes electric discharge phenomena mainly is the device with the dc high voltage mode generating negative ions of negative potential, its objective is that demand is in the effect that makes people's effect.Therefore, in such ion generating device, although can be in air the supply anion, can not remove airborne planktonic bacteria etc. energetically.
About other ion generating device, the investigation result of the example of communique in the past knows that following method is arranged.
Open in the flat 4-90428 communique (below, be called patent documentation 1) the spy, told about in discharge lines or had on the discharge electrode of acute angle part and apply ac high voltage, anion is taken place or make the ion generator of anion and cation generation.But,, only recorded and narrated high alternating voltage unit about the method and apparatus that takes place.Application is an air-conditioner, has enumerated comfortableness, slackness to the people as effect.
Open in the flat 8-217412 communique (below, be called patent documentation 2) the spy, told about following corona discharger: the clamping insulator, constitute pair of electrodes with sparking electrode, induction electrode, possess the high voltage source that applies high voltagehigh frequency voltage at its two ends.Recorded and narrated at electrode two ends configuration diode as high voltage source, selected the power supply of negative potential or the power supply of positive potential, but, do not recorded and narrated about its handoff functionality by its direction.Have again,, recorded and narrated the corona discharge device of ozone generating-device and Charging system, ion generating device etc. as the application of present technique.In addition, enumerated the generation of ion as the effect of present technique.
The spy open flat 3-230499 communique (below, be called patent documentation 3) in, told about following such ion generating device: the grounded screen of the discharge electrode of needle-like and electric conductivity or ground loop are made a pair of electrode mode with two-dimensional expansion on the direction of crosscut clean air flow dispose a plurality of, the high voltage of the AC sine wave after applying negative bias on the discharge electrode that has, the high voltage of the AC sine wave after applying positive bias on the discharge electrode that has constitutes many groups discharge electrode of emitting cation and many groups discharge electrode of emitting anion.This ion generating device has the control module of adjusting bias voltage, adjusts the amount of cation, anion.Enumerate the electric equipment that removes of Clean room as application, understood its electrical effect that removes as effect sound.
Open in the flat 9-610 communique (below, be called patent documentation 4) the spy, told about the dust collect plant that applies voltage variable to the electrode of positive discharge, negative discharge.Electrode is ionization line and collecting plate, thereby is to make the structure of the charged control of dust of dust on collecting plate.Clearly having put down in writing application is the electric dust collecting means of air-conditioning equipment, carries out its inner sterilization by the ozone that takes place when discharging.
Utilize the ion generating electrodes of electric discharge phenomena to be divided into 2 classes substantially.It is just like shown in the patent documentation 1,3,4, is with metal wire or has the sheet metal of acute angle part and pin etc., and its opposite pole is the earth or sheet metal that uses above earth potential and net etc., and air plays the effect of insulator.Another kind of is to open 2003-47651 communique (below, be called patent documentation 5), spy as patent documentation 2 and spy described later to open 2002-319472 communique (below, be called patent documentation 6) described, is that the clamping solid dielectric has formed sparking electrode and induction electrode.As its feature and since the former with air as insulant, compare with the latter interelectrode distance need obtain wide, therefore, when discharge needed voltage must set highly.On the contrary, because in the middle of the latter is clamped in insulaion resistance height, insulator with high-k,, therefore, compares with the former and to apply voltage and can set lowly so interelectrode distance can be done narrowly (approaching).
About ion generating device, made the invention that relates to following ion generating device: as the effect of the dipolar ion of emitting cation, anion, by in air roughly isodose ground H as cation takes place
+(H
2O)
mWith O as anion
2 -(H
2O)
n(m, n are natural numbers), two ions surround airborne mycoplankton and virus around, the effect of the hydroxy (OH) by the free radical that generates this moment can make lose activity (for example, with reference to patent documentations 5,6) such as above-mentioned mycoplanktons.
Have again, about foregoing invention, by the present patent application people in the practical machine of practicability, the dielectric that the clamping pottery arranged is provided in sparking electrode the outside, induction electrode is provided in the ion generating device of inside structure and the air cleaner of this ion generating device has been installed and air conditioner etc.
In addition, effect as anion, we know it generally is to supply with anion in the too much space of cation in large quantities to becoming because of the electrical equipment in the family etc., when wishing to obtain the state of cation as in the forest of occurring in nature and anion balance or to try to achieve under the situation of loosening effect be effective.In patent documentation 1, also told about and loosened effect.
Summary of the invention
The objective of the invention is: cation and anion take place, swim aerial fungi and virus are lost activity, and be used for further improving its effect.Generally speaking, utilize the ion generator of electric discharge phenomena that ozone takes place when ion takes place all the time, in patent documentation 4, recorded and narrated the oxidability of utilizing ozone, carry out the sterilization in the equipment.General know that all concentration when ozone is influential to human body when high, concerning the present patent application people, one side make the generating capacity minimization of ozone simultaneously draw ionic weight again to greatest extent this is very difficult problem.
In addition, not patent documentation 3 as the apparatus of object but can carry in the small-sized ion generating device in the Household Electrical product, the present patent application people has proposed the ion generating device of records such as patent documentation 5,6, if use this ion generating device, cation, anion take place in equivalent amount ground substantially.
In order to reduce the neutralization of simultaneous cation, anion, generally be ion to be diffused in the space with fair wind by air-supply.But, by cation and anion take place simultaneously, the problem that the part of dipolar ion neutralization back is eliminated when also existing in generation.The ion generating device of recording and narrating in the patent documentation 3 has a plurality of discharge electrodes of two-dimensional expansion ground configuration on the direction of crosscut clean air flow.That is, wind flows through on the direction that pin extends.For miniaturization, security and energy-conservation, consider to reduce and apply voltage, the present patent application people mainly adopts the structure of utilizing sparking electrode that is arranged on the dielectric surface and the induction electrode that is embedded in above-mentioned dielectric inside to constitute pair of electrodes, in this case, on the direction of the wind described in the above-mentioned patent documentation 3, owing to be not suitable for the diffusion of ion, wind is parallel to dielectricly blows over outwardly.Carrying under the situation on the extensive stock at ion generator that will exploitation, is effectively though wind is limited on the desirable direction the direction of ion generator, and the situation that can not limit is also arranged because of the situation difference.
The present invention carries out in view of the above problems, and its purpose is: studied the strategy that the ion neutralization each other that suppresses to take place emits effectively and can further improve ion generating device, the ion generating device of ion luminous efficiency and be equipped with the electrical equipment of this device thereby provide.
Even matrix material is blown from any one direction of X-direction Y direction, in order to achieve the above object, the ion generating device that the present invention relates to has 1 installation separately at least or is printed on the 1st discharge part on 1 matrix material, that cation takes place and the 2nd discharge part of generating negative ions, 1st, the 2nd discharge part is all on the same plane of above-mentioned matrix material, and separates and be configured in (inclination) on its diagonal independently.Though electrode at this moment also can make the electrode of needle-like, basically, the present patent application people considers to form with sparking electrode that is provided with and the induction electrode that is embedded in dielectric inside the structure of pair of electrodes on dielectric surface.At this moment, even in order to be blown from any one direction of X-direction Y direction in the sparking electrode surface on the dielectric, also can prevent to neutralize at the discharge part of the opposite polarity of leeward from the ion that the discharge part of windward takes place, direction (X-axis or Y direction) with respect to air-supply, it is tilted configuration that the 1st discharge part and the 2nd discharge part are configured on the diagonal, to reduce its neutralization.
Installing or printing under the conditional situation of area of matrix material of the 1st discharge part, the 2nd discharge part, when guaranteeing the insulation distance of the 1st discharge part and the 2nd discharge part, the configuration of considering (inclination) on the diagonal as described above is than situation of difficult.At this moment, adopt configuration and the structure of around the 1st discharge position that surrounds the generation cation or the 1st discharge position of a part with the 1st conducting position of voltage, the 2nd discharge part of generating negative ions also adopts same structure.Above-mentioned the 1st conducting position and the 2nd conducting position are disposed in opposed at grade, separation independently.From the 1st discharge position cation of emitting, before by the counter potential neutralization at the 2nd discharge position, the repulsion of the 1st conducting position of the same voltage by surrounding the 1st discharge position is emitted with wind.The 2nd discharge position too.With last identical,, be the structure of considering to constitute pair of electrodes basically with the induction electrode that is arranged on dielectric lip-deep sparking electrode and buries underground in dielectric inside though also can make needle-like as electrode at this moment.
In addition, ion generating device of the present invention is to have 1 installation separately at least or be printed on the 1st discharge part on 1 matrix material, that cation takes place and the 2nd discharge part of generating negative ions, 1st, the 2nd discharge part will be arranged on as dielectric lip-deep the 1st, the 2nd sparking electrode of above-mentioned matrix material and the 1st, the 2nd induction electrode that is embedded in above-mentioned dielectric inside respectively as a pair of and each self-forming, be separated from each other configuration independently on the same plane of above-mentioned matrix material.According to this structure, and with specified period cation takes place alternately with single ion generating device and compare the ion that can suppress to take place neutralization each other with the mode of anion.
In addition, when the mode that keeps at a certain distance away with the 1st sparking electrode and the 2nd sparking electrode when the 1st discharge part and the 2nd discharge part disposes, can prevent that between the 1st, the 2nd sparking electrode flashing (spark discharge) improves reliability, and can further suppress the ion neutralization each other that takes place.
Constituting in the structure of pair of electrodes with the induction electrode that is embedded in dielectric inside with being arranged on dielectric lip-deep sparking electrode, in order to reduce the generation of ozone, be applied to the voltage waveform of the 1st discharge part and the 2nd discharge part, it or not the such general AC sine wave of patent documentation 2,3, in ion generating device of the present invention, by applying ac pulse voltage, can either obtain stable ion and take place, ozone can be suppressed at low value again.Make ac pulse voltage is biased to positive voltage waveform generation cation by applying on the 1st discharge part, on the 2nd discharge part by applying the structure that identical voltage is biased to negative voltage waveform generating negative ions.
And then, above-mentioned voltage applying circuit constitutes by having: the 1st voltage application portion and converter section, can change by on the 1st discharge part of above-mentioned ion generating device, apply with ac pulse voltage be biased to cation takes place positive voltage waveform situation, with apply the situation that identical voltage is biased to a negative voltage waveform generating negative ions; And the 2nd voltage application portion, by on the 2nd discharge part of above-mentioned ion generating device, applying identical ac pulse voltage is biased to negative voltage waveform, make it generating negative ions; Thereby can select, change the situation of the ion that positive and negative two sides are taken place and the state of only emitting anion.According to the environment for use of ion generating device and situation, application target, can be automatically or the polarity kind of the ion that takes place of manual switch.When cation and anion take place, its objective is the fungi and the virus of swimming in air are lost activity, when generating negative ions, it is effective will becoming the situation that the state of obtaining ionic equilibrium or requirement loosen effect because of the too much states of formation cation such as electrical equipment in the family to hope.Realize these translation functions with an electrode, an ion generating device.
In addition, as in order to realize the strategy of above-mentioned handoff functionality with more cheap and less components number, above-mentioned voltage applying circuit constitutes by having: the 3rd voltage application portion and biasing switching part are biased to ac pulse voltage situation that positive voltage waveform makes it to take place cation, do not have to make it to take place the situation of cation and anion with the alternating voltage waveform of voltage bias with applying thereby can change by applying on the 1st discharge part of above-mentioned ion generating device; The 2nd voltage application portion makes it generating negative ions by applying be biased to negative voltage waveform with ac pulse voltage on the 2nd discharge part of above-mentioned ion generating device; Thereby can select, switch state that positive and negative two sides' of equivalent ion roughly takes place and a spot of cation take place and than the state of the anion of cation amount volume.Can be according to the environment for use of ion generating device and situation, application target, automatically or the polarity kind of the ion that takes place of manual switch.When cation that makes it to take place equivalent roughly and anion, its objective is swim aerial fungi and virus are lost activity, when making it volume ground generating negative ions, when hope will become the too much state of cation and become the state of obtaining ionic equilibrium because of the electrical equipment in the family etc. or require in the lax situation very effective.Realize these handoff functionalities with 1 ion generating device.
In addition, be applied to the ac pulse voltage on the 1st discharge part, can be to be the alternating voltage waveform that the voltage of the 1st induction electrode of benchmark begins from positive polarity with the 1st sparking electrode, being applied to the ac pulse voltage on the 2nd discharge part, can be to be the alternating voltage waveform that the voltage of the 2nd induction electrode of benchmark begins from negative polarity with the 2nd sparking electrode.In other words, be that the wave height value of the 1st ripple of voltage of the 1st induction electrode of benchmark raises in the positive polarity side with the 1st sparking electrode, be the wave height value of the 1st ripple of voltage of the 2nd induction electrode of benchmark raises in the negative polarity side with the 2nd sparking electrode.
In addition, above-mentioned voltage applying circuit has: the 1st diode, negative electrode are connected (=earthing potential: record and narrate at the embodiment item) with reference potential, anode is connected with the 2nd sparking electrode; And the 2nd diode, anode is connected with the said reference current potential, and negative electrode is connected with the 1st sparking electrode.As long as can switch whether the 2nd diode is connected with reference potential, thus, just can select to be applied to ac pulse voltage on the 2nd sparking electrode is biased to ac pulse voltage negative, that be applied on the 1st sparking electrode and just is being biased to or is not applying with not setovering the alternating voltage waveform.
In addition, above-mentioned voltage applying circuit can have: the 1st diode, and negative electrode is connected with reference potential, and anode is connected with the 2nd sparking electrode; The 2nd diode, when from the 1st discharge part generation cation, anode is connected with the said reference current potential, and negative electrode is connected with the 1st sparking electrode; And the 3rd diode, when from the 1st discharge part generating negative ions, negative electrode is connected with the said reference current potential, and anode is connected with the 1st sparking electrode.Thus, be applied to ac pulse voltage on the 2nd sparking electrode and can be biased to negatively, be applied to that ac pulse voltage on the 1st sparking electrode just can be biased to or negative.
In addition, above-mentioned voltage applying circuit has the primary coil that comprises driving side, at the 1st secondary coil that applies ac pulse voltage on the 1st discharge part and the 1st transformer that on the 2nd discharge part, applies the 2nd secondary coil of ac pulse voltage, when the 1st, the 2nd secondary coil of the 1st transformer is configured to the both sides of above-mentioned primary coil respectively, the distance between the 1st, the 2nd secondary coil can be guaranteed, influence can be alleviated in magnetic field that secondary coil takes place directly another secondary coil.
In addition, above-mentioned voltage applying circuit has: the 2nd transformer, the secondary coil that it comprises the primary coil of driving side and apply ac pulse voltage on the 1st discharge part; The 3rd transformer, the secondary coil that it comprises the primary coil of driving side and apply ac pulse voltage on the 2nd discharge part, when the secondary coil of the primary coil of the primary coil of the secondary coil that disposes the 2nd transformer successively, the 2nd transformer, the 3rd transformer, the 3rd transformer, the distance between the secondary coil of the secondary coil of the 2nd transformer and the 3rd transformer can be guaranteed, influence can be alleviated in magnetic field that a secondary coil takes place directly another secondary coil.
In addition, when the primary coil with the 2nd transformer is connected with the parallel connection of primary windings of the 3rd transformer, because the primary coil that is applied to the 2nd transformer equates with voltage on the primary coil of the 3rd transformer, so by the 2nd transformer is equated, can make the absolute value that is applied to the ac pulse voltage on the 1st discharge part and the 2nd discharge part to equate with the characteristic of the 3rd transformer.
In addition, when the primary coil with the primary coil of the 2nd transformer and the 3rd transformer is connected in series, because flowing through the primary coil of the 2nd transformer equates with the electric current of the primary coil of the 3rd transformer, so by the 2nd transformer is equated, can make the absolute value that is applied to the ac pulse voltage on the 1st discharge part and the 2nd discharge part to equate with the characteristic of the 3rd transformer.
In addition, when being connected fly-wheel diode (flywheel diode) respectively on the primary coil at the primary coil of the 2nd transformer and the 3rd transformer, because the voltage of being responded on the primary coil of the 2nd transformer by the electric current on the secondary coil that flows through the 2nd transformer causes mobile current reflux in the primary coil of the 2nd transformer and the fly-wheel diode that is attached thereto, the influence of the 3rd transformer is disappeared.In addition, similarly, because the voltage that the electric current of the secondary coil by flowing through the 3rd transformer is responded on the primary coil of the 3rd transformer and mobile current reflux are in the primary coil of the 3rd transformer and the fly-wheel diode that is attached thereto, so the influence of the 2nd transformer is also disappeared.Therefore, even produce load change etc. on a discharge part, this change also disappears to the influence that is applied to the voltage on another discharge part, can prevent from the change of the ionic weight of another discharge part generation.
In the ion generating device that constitutes by said structure, be used on the sparking electrode of the 1st, the 2nd discharge part and induction electrode, applying the sparking electrode contact and the induction electrode contact of the voltage waveform of regulation, it is dielectric surface, be configured on the surface with the sparking electrode opposition side, so that the ion that does not hinder discharge and take place.This number of contacts the 1st, the 2nd adds up to 4, and its position relation adopts the contact of the 1st minimum sparking electrode of potential difference and the contact separation certain distance disposed adjacent of the 2nd sparking electrode, more can improve reliability.
Similarly, the configuration on matrix material of the 1st discharge part and the 2nd discharge part also is to adopt the 1st sparking electrode of potential difference minimum and the structure that the 2nd sparking electrode keeps at a certain distance away and disposes, and more can improve reliability.
In addition, electrical equipment of the present invention can constitute: be equipped with any one ion generating device that is made of said structure and will pass out to airborne unloading part (fan etc.) with the ion that this ion generating device takes place.By such structure, the function that the equipment that adds is original in the ion generating device that carries, can make airborne ionic weight or ionic equilibrium change, thereby make indoor environment become desirable atmosphere state.
In addition, by the electrical equipment that said structure constitutes, be H to take place as cation
+(H
2O)
m, O takes place as anion
2 -(H
2O)
n(m, n are natural numbers, mean to have a plurality of H
2The O molecule) structure.Like this, by H roughly takes place in air equally
+(H
2O)
mWith O
2 -(H
2O)
nThereby, make two ions attached on the airborne planktonic bacteria etc., the effect of the hydroxy (OH) by the free radical that generates at that time can make above-mentioned planktonic bacteria lose activity.
Description of drawings
Figure 1A~Fig. 1 H is the schematic diagram that expression ion of the present invention is independently emitted the infrastest example of mode.
Fig. 2 A, Fig. 2 B are the skeleton diagrams of the 1st embodiment of expression ion generating device of the present invention.
Fig. 3 is the skeleton diagram of the 2nd embodiment of expression ion generating device of the present invention.
Fig. 4 A, Fig. 4 B are the skeleton diagrams of the 3rd embodiment of expression ion generating device of the present invention.
Fig. 5 A~Fig. 5 G is the circuit diagram and the voltage oscillogram of an embodiment of expression voltage applying circuit.
Fig. 6 A~Fig. 6 D is the schematic diagram that expression ion of the present invention is independently emitted other infrastest examples of mode.
Fig. 7 is the schematic diagram of experimental result that expression ion of the present invention is independently emitted other infrastest examples of mode.
Fig. 8 is the skeleton diagram of the 5th embodiment of expression ion generating device of the present invention.
Fig. 9 is the skeleton diagram of the 6th embodiment of expression ion generating device of the present invention.
Figure 10 is the skeleton diagram of the 7th embodiment of expression ion generating device of the present invention.
Figure 11 is the skeleton diagram of the 8th embodiment of expression ion generating device of the present invention.
Figure 12 is the circuit diagram of other embodiments of expression voltage applying circuit.
Figure 13 is the circuit diagram of another other embodiments of expression voltage applying circuit.
Figure 14 A, Figure 14 B are the oscillograms of the operating voltage waveform of expression Figure 12, voltage applying circuit shown in Figure 13.
Figure 15 A, Figure 15 B are other the oscillograms of operating voltage waveform of expression Figure 12, voltage applying circuit shown in Figure 13.
Figure 16 A, Figure 16 B are other the oscillograms of operating voltage waveform of expression Figure 12, voltage applying circuit shown in Figure 13.
Figure 17 A, Figure 17 B are other the oscillograms of operating voltage waveform of expression Figure 12, voltage applying circuit shown in Figure 13.
Figure 18 A, Figure 18 B are other the oscillograms of operating voltage waveform of expression Figure 12, voltage applying circuit shown in Figure 13.
Figure 19 is the allocation plan of component configuration that the ion generating device of transformer shown in Figure 12 has been carried in expression.
Figure 20 is the allocation plan of component configuration that the ion generating device of transformer shown in Figure 13 has been carried in expression.
The specific embodiment
Neutralization takes place for the cation that suppresses to take place and anion and eliminates and the dipolar ion that will take place effectively is released in the space in ion generating device of the present invention near the electrode of ion generating device, not to adopt the mode that cation and anion alternately take place with specified period with single ion generating device, the structure that cation and anion also are released to indoor mode (below, be called ion and independently emit mode) independently of one another individually takes place but adopt with a plurality of ion generating devices.
Before the above-mentioned ion of employing is independently emitted mode, carry out following infrastest earlier.Have again, mode as the ion generating device that uses in this experiment, though can adopt the structure of needle electrode, here, consider with being arranged on the structure that dielectric lip-deep sparking electrode and the induction electrode that is embedded in dielectric inside constitute pair of electrodes.
Figure 1A~Fig. 1 H is the schematic diagram that expression ion of the present invention is independently emitted the infrastest example of mode.Figure 1A is the outside drawing of ion generating device, and Figure 1B is the profile of ion generating device, and Fig. 1 C is that the voltage between sparking electrode and the induction electrode applies waveform, and Fig. 1 D~Fig. 1 G is measuring condition figure, and Fig. 1 H is the configuration example of ion generating device.
At first, in current experiment, use the ion generating device 1 shown in Figure 1A, Figure 1B, utilization between its sparking electrode 0a and induction electrode 0b, apply ac pulse voltage (Fig. 1 C) thus with specified period alternately take place cation and anion situation (Fig. 1 D) thereby and use identical ion generating device 1 to apply ac pulse voltage is biased to the only situation of generating negative ions (not diagram) of negative waveform, measure the ion discharging amount respectively, what kind of difference checking has on separately.Consequently, be 50~60[% of the latter's anion detection limit at the former cation and the total detection limit of anion] about.
Then, be conceived to The above results, with 2 ion generating device 1a, 1b same as described above side by side, measure respectively cation, the total ion discharging amount of the situation of generating negative ions (Fig. 1 E~Fig. 1 G) only individually only take place.
Consequently, the total detection limit of cation that obtains under the condition determination of Fig. 1 E and anion becomes the value that the cation detection limit that obtains with the situation of using above-mentioned 2 ion generating devices individually to measure the ion discharging amount and the aggregate value of anion detection limit equate substantially.Hence one can see that, be not with specified period the mode of cation and anion to take place alternately with single ion generating device, but the ion generating device that adopts ion independently to emit mode is effective.
But, in Fig. 1 E, with being configured in side by side on the direction with from the air-supply quadrature of fan 2 of the 1st discharge part (ion generating device 1a) and the 2nd discharge part (ion generating device 1b), by the stream of the air on the ion generating device by on another ion generating device.
On the other hand, shown in Fig. 1 F, Fig. 1 G, from Fig. 1 E laying method is changed 90 degree, when make ion generating device 1a and ion generating device 1b be configured in side by side with the direction parallel from the air-supply of fan 2 on the time, confirm at the ionic weight of the discharge part generation that is positioned at windward and decay.When describing particularly, in Fig. 1 F, because the cation that the ion generating device 1a that is in the wind takes place is by on the ion generating device 1b of leeward, so this cation is neutralized the amount decay of cation by the negative potential of ion generating device 1b.Similarly, in Fig. 1 G, the decay of the anion of the ion generating device 1b of windward.Hence one can see that, even adopt ion independently to emit mode, and because of the configuration ion of discharge part can not be emitted effectively, the decay of the ion of folk prescription, the balance of emitting of cation and anion is collapsed.
Here, the measurement of ion is to utilize the double cylinder-shaped ion counter of Ge Dien (Gerdien) 3 to carry out results measured, obtains concentration [individual/cc] at measurement point as measured value.Owing to measured the size of the ion concentration that obtains at the same terms, identical measurement point, so in article, how much show the height of concentration with ionic weight.
Under the situation of ion generating device being carried at device interior, even in order to become by the equipment air-supply the sparking electrode surface on the dielectric from any one the direction air-supply of X-direction Y direction, can prevent that also the ion that the discharge part of being in the wind takes place is neutralized on the discharge part of the opposite polarity of leeward, direction X-axis or Y direction with respect to air-supply, preferably ion generating device 1a, 1b are configured on the diagonal, be tilted configuration, to reduce its neutralization (with reference to Fig. 1 H).But owing to be disadvantageous aspect area, under the situation of air supply direction decision, opposite hope is not configured on the diagonal.
In addition, carry out infrastest, the relation of distance and the dosis neutralisata of two ions that take place between the sparking electrode of the sparking electrode of this experimental study generation cation and the sparking electrode of generating negative ions.Fig. 6 A~Fig. 6 D is the schematic diagram that expression ion of the present invention is independently emitted other infrastests of mode.Fig. 6 A is the electrode allocation plan of the face side of membrane electrode, and Fig. 6 B is the electrode allocation plan of the rear side of membrane electrode, and Fig. 6 C is that the voltage between sparking electrode and the induction electrode applies waveform, and Fig. 6 D is condition determination figure.
In Fig. 6 A~Fig. 6 D, the 60th, thereby by in print copper on the Kapton and carry out the etching membrane electrode of 2 electrodes of each self-forming on the face of the face of face side, rear side respectively.As shown in Figure 6A, on the face of face side, between the sparking electrode of space, will be similar to sparking electrode 61a, the 62a that partly makes lattice-shaped in the rectangle apart from forming on the position of d, shown in Fig. 6 B, overleaf on the face of side, with the opposed position of sparking electrode 61a, 62a on form induction electrode 61b, the 62b of the approximate solid shape of rectangle.Have, in order to prevent in the end of sparking electrode 61a, 62a paradoxical discharge to take place, induction electrode 61b, 62b form littler than sparking electrode 61a, 62a in the inboard again.
In addition, be solder pad 63 with being arranged on the part that the black circle on each electrode represents, via being welded in the lead-in wire here etc., on each electrode, applying high voltage and make it discharge ion takes place.The ac pulse voltage of oscillation exchange decay waveform that will be shown in Fig. 6 C is biased to just after-applied between sparking electrode 61a, induction electrode 61b, identical ac pulse voltage is biased to negative after-applied between sparking electrode 62a, induction electrode 62b.Thus, from sparking electrode 61a cation takes place, from sparking electrode 62a generating negative ions.Have, the wave height value Vop of the 1st ripple of the ac pulse voltage that applies is about 3kV again.
And, make a plurality of membrane electrodes 60 that changed apart from d that make between sparking electrode, shown in Fig. 6 D, to each membrane electrode 60, membrane electrode 60 is placed between fan 2 and the ion counter 3, above-mentioned ac pulse voltage is biased to the positive and negative two ions ion concentration separately that just reaches negative waveform mensuration generation thereby apply.Measurement is to the situation that cation only takes place, only the situation of generating negative ions and the situation 3 class situations that positive and negative two ions take place are simultaneously carried out.Having, at this moment, is 25cm between ion generating device 60 and the ion counter 3 again, and the both is configured on the top position of test desk 4.5cm.
And Fig. 7 is the figure of its measurement result of expression.Have, the temperature during mensuration is that 27 ℃, humidity are 27% again.From this measurement result as can be known, if between sparking electrode apart from d more than or equal to 5mm, flashing (spark discharge) not between sparking electrode 61a, 62a then.In addition, making between sparking electrode apart from d is 8mm, and then cation, anion all are that ion number when a side the is taken place ion number when taking place simultaneously with two sides equates.Hence one can see that, under the condition of the membrane electrode that uses in this is measured, if make between sparking electrode apart from d more than or equal to 8mm the neutralization of positive and negative two ions that then can prevent.Though help preventing spark more apart from d is big more between sparking electrode, help preventing the neutralization of two ions, but because when distance increased, the size of ion generating device also increased, thus consideration so long as above-mentioned condition just get final product being set at about 8mm apart from d between sparking electrode.Have again, when making makes between sparking electrode sample apart from the variable in distance of d, the membrane electrode that uses in this mensuration is guaranteed between sparking electrode distance apart from d by etching, only on this part, remove the coat on coated electrode surface, be in the state that a part that makes sparking electrode end face opposite each other is exposed copper.Therefore, in the electrode of the reality of following record,, can infer and to make between sparking electrode value littler apart from d by the existence of coat.
Shown in Fig. 1 H, ion generating device 1a, 1b are configured on the diagonal, i.e. tilted configuration reduces the result of the above-mentioned infrastest of its neutralization according to hope, will make the 1st embodiment of its (being configured on the diagonal) imbody be shown in Fig. 2 A, Fig. 2 B.Fig. 2 A, Fig. 2 B are the summary construction diagrams of the 1st embodiment of expression ion generating device of the present invention, and Fig. 2 A, Fig. 2 B schematically show the plane and the side view of ion generating device respectively.
Shown in Fig. 2 A, Fig. 2 B, ion generating device of the present invention has: be equipped with the ion generating device 10 that the discharge part of ion takes place a plurality of (being 2 in the present embodiment); And the voltage applying circuit 20 that applies of the voltage that ion generating device 10 is stipulated.
In addition, owing to wish that the insulaion resistance between sparking electrode 12a, 13a and induction electrode 12b, the 13b is a homogeneous, so density is discrete few, the material of its insulation rate homogeneous is suitable more as the material of dielectric 11.
Have again, though the shape of dielectric 11 can be (discoideus and oval tabular, polygonal is tabular etc.) beyond the approximate rectangular shape, and then, also can be cylindric, but when considering productivity, preferably as present embodiment, make tabular (comprising discoideus and rectangular-shaped).
1st, the 2nd discharge part 12,13 is arranged in (inclination) on the diagonal with respect to the shape of the dielectric 11 of matrix material, makes mutually not side by side not in a straight line.When further carrying out functional expression, 1st, the 2nd discharge part 12,13 is arranged in: even if air stream is sent here from any one direction the ion generating device 10 of present embodiment, all make its orientation and this air flow quadrature, in other words, make by the stream of the air on the discharge part not by on another discharge part.By such structure, the ion of can applying in a flexible way is independently emitted the effect of mode, is suppressed at the ion decay that two discharge parts 12,13 take place, and carries out the good ion of balance effectively and emits.
Sparking electrode 12a, 13a are integrally formed with this top dielectric 11a on the surface of top dielectric 11a.As the material of sparking electrode 12a, 13a, for example as tungsten,, just can use, but its condition is the distortion that can not cause fusion etc. because of discharge so long as have the material of electric conductivity with being not particularly limited.
In addition, induction electrode 12b, 13b clamping upper dielectric 11a and sparking electrode 12a, 13a be arranged in parallel.Because by such configuration, can make sparking electrode 12a, 13a and induction electrode 12b, 13b distance (below, be called interelectrode distance) become necessarily, thereby so can make two interelectrode insulaion resistance homogenizations make discharge condition stable, cation and/or anion can take place suitably.Have, make under the columned situation at dielectric 11, sparking electrode 12a, 13a are arranged on the outer surface of cylinder, and by the axle shape induction electrode 12b, 13b are set, and above-mentioned interelectrode distance is become necessarily.
As the material of induction electrode 12b, 13b, same with sparking electrode 12a, 13a, for example as tungsten,, just can use, but its condition is the distortion that can not cause fusion etc. because of discharge so long as have the material of electric conductivity with being not particularly limited.
Sparking electrode contact 12c, 13c conduct with sparking electrode 12a, 13a via being arranged on splicing ear 12e, 13e and access path 12g, 13g on the same formation face (that is, the surface of top dielectric 11a) with sparking electrode 12a, 13a.Therefore, on sparking electrode contact 12c, 13c, connect an end of lead-in wire (copper cash and aluminum steel etc.),, sparking electrode 12a, 13a and voltage applying circuit 20 are conducted as long as the other end that will go between is connected with voltage applying circuit 20.
And then the surface that preferably sparking electrode contact 12c, 13c and induction electrode contact 12d, 13d all is arranged on dielectric 11 promptly is provided with on the face of sparking electrode 12a, 13a (below, be called the top of the dielectric 11) face in addition.Owing to,, can bring into play the effect that ion of the present invention is independently emitted mode to greatest extent so be difficult to confusion from the air stream of fan (not shown) so long as such structure does not just set unwanted lead-in wire etc. on dielectric 11.
Consider above situation, in the ion generating device 10 of present embodiment, sparking electrode contact 12c, 13c and induction electrode contact 12d, 13d all be arranged on the top relative face of dielectric 11 (below, be called the following of dielectric 11) on.
Have, in the ion generating device 10 of present embodiment, the 1st sparking electrode 12a, the 2nd sparking electrode 13a have acute angle part again, in this part electric field are concentrated, and become the structure that causes discharge partly.Certainly, as long as electric field is concentrated, the electrode figure in addition that also can use this figure to record and narrate.Below, Fig. 3, Fig. 4 A, Fig. 4 B processing too.
Fig. 3 is the general view of the 2nd embodiment of expression ion generating device of the present invention.It is identical with Fig. 2 B that the structure of profile can be thought.Fig. 3 is not configured in the 1st, the 2nd discharge position embodiment on the diagonal because of the restriction on the area with respect to the shape of matrix material 11.
The 1st sparking electrode 12a is categorized as the 1st discharge position 12j that electric field concentrated cause discharge, surrounds around it or the 1st conducting position 12k of a part and the above-mentioned 12e of splicing ear portion.These all are positioned on the same figure, and the voltage that applies equates.The 2nd sparking electrode 13a has the 2nd discharge position 13j, the 2nd conducting position 13k, the 13e of splicing ear portion too.
There is the 2nd discharge position 13j of negative potential in the 1st discharge position 12j at positive potential generation cation in its close vicinity.
Here, it is characterized in that: to causing the 1st, the 2nd discharge position 12j, 13j of discharge, configuration is surrounded around it or the 1st, the 2nd conducting position 12k, the 13k of a part.Like this, since with the 1st discharge position 12j with the 1st conducting position 12k of voltage surround the 1st discharge position 12j around or a part, so the cation that takes place from the 1st discharge position 12j is before arriving the 2nd discharge position 13j of opposite polarity negative potential, the repulsion of the 1st conducting position 12k by positive potential can relax the situation that arrives the 2nd discharge position 13j.For the 2nd discharge position 13k too.Have again, under the situation of the distance of air supply direction that the ion that takes place neutralizes hardly and the 1st sparking electrode 12a and the 2nd sparking electrode 13a, also can not be provided as the 1st conducting position 12k, the 2nd conducting position 13k of above-mentioned characteristic.
Fig. 4 A, Fig. 4 B are the general views of the 3rd embodiment of expression ion generating device of the present invention.It is identical with Fig. 2 B that the structure of profile can be thought.Ion generating device shown in Fig. 4 A, Fig. 4 B has the feature of above-mentioned the 2nd embodiment, and in addition, as mentioned above, the shape for the dielectric 11 of matrix material is configured on the diagonal.As mentioned above, though can be the electrode of needle-like, have recorded and narrated basically with being arranged on the situation that dielectric lip-deep sparking electrode and the induction electrode that is embedded in dielectric inside form pair of electrodes as the shape of electrode.
It is characterized in that as the 4th embodiment of the present invention: at above-mentioned Fig. 2 A, Fig. 2 B, Fig. 3, Fig. 4 A, in the ion generating device shown in Fig. 4 B, when considering the 1st sparking electrode 12a, the 1st induction electrode 12b, the 2nd sparking electrode 13a, the 2nd induction electrode 13b is during to the configuration of dielectric 11, though can guarantee the 1st at interval, the distance of the 2nd interelectrode insulation and adjacency, but consider to apply voltage, it is characterized in that: the distance that spaced apart the 1st sparking electrode 12a that can guarantee to make in these 2 interelectrode potential difference minimums and the 2nd sparking electrode 13a insulate and adjoining each other.In other words, constitute the distance of electrode insulation of the spaced apart combination that can guarantee the potential difference minimum and adjacency.Will be about potential difference and waveform in following record.
In addition, the electrode shape shown in Fig. 2 A, Fig. 3, Fig. 4 A, Fig. 4 B is an example, also can be the such electrode shape of Fig. 8~Figure 11.Fig. 8~Figure 11 is the general view of the 5th~the 8th embodiment of expression ion generating device of the present invention.In Fig. 8~Figure 11, on the part identical, mark prosign with Fig. 3, omit its explanation.In addition, the structure of profile also can think identical with Fig. 2 B.
Then, account for voltage applies the structure and the work of circuit 20.
Fig. 5 A, Fig. 5 B are the circuit diagrams of an embodiment of expression voltage applying circuit 20.At first, the voltage applying circuit shown in the key diagram 5A 20.Voltage applying circuit 20 shown in Fig. 5 A has as the primary side drive circuit: input power supply 201, input resistance 204, commutation diode 206, transformer drive with switch element 212, electric capacity 211, diode 207.At input power supply 201 is to exchange under the situation of source power supply, voltage by input power supply 201 gives electric capacity 211 chargings via input resistance 204, commutation diode 206, when becoming more than or equal to assigned voltage, transformer drives with switch element 212 conductings, applies voltage on the primary side coil 202a of transformer 202.Then, primary side coil 202a and the transformer of energy by transformer 202 that is charged on the electric capacity 211 drives with switch element 212 discharges, and the voltage of electric capacity 211 turns back to zero, charges once more, discharges and recharges repeatedly with cycle of regulation.Transformer drives with switch element 212 and just adopts no grid 2 end IGCTs (" Sidac " [product of new electric unit industry]) to be illustrated in the above description, but uses some different circuit, also can use IGCT (SCR).In addition, even be under the situation of dc source at input power supply 201, so long as can access the circuit with above-mentioned same work, just no matter be any circuit.That is, the primary side drive circuit as this circuit is not particularly limited, and gets final product so long as can access the circuit of same work.
Secondary-side circuitry as transformer 202, be equipped with 2 secondary coil 202b, 202c of transformer 202, these coils are connected with Fig. 2 A, Fig. 2 B, Fig. 3, Fig. 4 A, any one the 1st sparking electrode 12a, the 1st induction electrode 12b of Fig. 4 B, Fig. 8~Figure 11, the 2nd sparking electrode 13a, the 2nd induction electrode 13b respectively.Transformer by primary-side circuitry drives with switch element 212 conductings, and the energy of primary side is delivered to secondary coil 202b, the 202c of transformer, pulsing shape voltage.The secondary coil 202b that not only connects transformer 202 on the 1st sparking electrode 12a, but also the negative electrode of connection diode 209, the anode of diode 209 is connected via resistance 205 ground connection or with one-sided (reference potential) of input power supply 201.When input power supply 201 is when exchanging source power supply, because the folk prescription ground connection of input AC source power supply in Japan, so can access identical functions if the electrical equipment etc. that does not have a ground terminal and input power supply 201 one-sided is connected.Even socket inserts on the contrary, only overlapping 100V is identical with ground connection.In addition, resistance 205 is to protect usefulness, does not also influence work even without this resistance (short circuit).In addition, on the 2nd sparking electrode 13a, not only connect the secondary coil 202c of transformer, but also connect the anode of diode 208, the negative electrode of diode 208 is connected via resistance 205 ground connection or with input the one-sided of power supply 201.
Then, the voltage applying circuit 20 of other structures shown in the key diagram 5B.The explanation of the primary-side circuitry of transformer 202 and above-mentioned same.Secondary-side circuitry as transformer 202, the secondary coil of transformer 202 is equipped with 2 202b, 202c, and these coils are connected with Fig. 2 A, Fig. 2 B, Fig. 3, Fig. 4 A, any one the 1st sparking electrode 12a, the 1st induction electrode 12b of Fig. 4 B, Fig. 8~Figure 11, the 2nd sparking electrode 13a, the 2nd induction electrode 13b respectively.On the 1st sparking electrode 12a, the secondary coil 202b that not only connects transformer 202, but also connect the negative electrode of diode 209 and the anode of diode 210, the anode of diode 209 is connected with 1 selection terminal 203a of transfer relay 203, and the negative electrode of diode 210 is connected with another selection terminal 203b of transfer relay 203 in addition.The public terminal 203c of transfer relay 203 is connected via resistance 205 ground connection or with input the one-sided of power supply 201.
Then, the operating voltage waveform is described.On the two ends of secondary coil 202b, the 202c of transformer 202, apply the impulse waveform of the such alternating voltage of Fig. 5 C.The diode 209 that is connected with secondary coil 202b, 202c and the direction of diode 208 are reverse as mentioned above, with the voltage of the 1st sparking electrode 12a, the 1st induction electrode 12b, the 2nd sparking electrode 13a, the 2nd induction electrode 13b with ground terminal, according to circumstances with the one-sided (reference potential: the waveform when a side that connects diode 208,209) be the benchmark observation of input power supply 201, shown in Fig. 5 D, Fig. 5 E, Fig. 5 F, Fig. 5 G, the waveform of Fig. 5 C becomes and is biased to positive and negative waveform respectively.
Under the situation of Fig. 5 A illustrated embodiment, the 1st sparking electrode 12a, the 1st induction electrode 12b are with ground terminal, according to circumstances to import the one-sided (reference potential: be that the current potential that benchmark is observed just all is a side that connects diode 208,209) of power supply 201, the anion that takes place neutralizes on sparking electrode 12a, repels and emits cation.In addition, the 2nd sparking electrode 13a, the 2nd induction electrode 13b are with ground terminal, according to circumstances to import the one-sided (reference potential: be that the current potential that benchmark is observed all is negative a side that connects diode 208,209), emit anion of power supply 201.
In addition, under the situation of Fig. 5 B illustrated embodiment, when transfer relay 203 is positioned at selection terminal 203a one side, the 1st sparking electrode 12a, the 1st induction electrode 12b are with ground terminal, according to circumstances to import the one-sided (reference potential: be that the current potential that benchmark is observed just all is a side that connects diode 208,209), cation takes place of power supply 201.In addition, be positioned at when selecting terminal 203b one side at transfer relay 203, with ground terminal, according to circumstances with input power supply 201 one-sided (reference potential: be that the current potential of benchmark observation all is negative a side that connects diode 208,209), generating negative ions.The 2nd sparking electrode 13a, the 2nd induction electrode 13b with ground terminal, according to circumstances with input power supply 201 one-sided (reference potential: be that the current potential of benchmark observation all is negative a side that connects diode 208,209), generating negative ions.
As cation is H
+(H
2O)
m, be O as anion
2 -(H
2O)
n(m, n are natural numbers, mean to have a plurality of H
2The O molecule).
Like this, when the selection terminal of transfer relay 203 was positioned at 203a one side, the ion that takes place from the 1st discharge part 12 became cation, with the anion that takes place from the 2nd discharge part 13, the ion of positive and negative roughly equivalent amount had taken place.By in air, roughly emitting H with amount
+(H
2O)
mWith O
2 -(H
2O)
n, these ions surround airborne mycoplankton or virus around, the effect of the hydroxy (OH) by the free radical that generates this moment can be deactivated.
Tell about above-mentioned record in detail.By apply alternating voltage between the electrode that constitutes the 1st, the 2nd discharge part 12,13, airborne oxygen and even moisture are accepted energy by ionization, produce ionization, generate with H
+(H
2O)
m(m be natural number) arbitrarily and O
2 -(H
2O)
n(n be natural number) arbitrarily is the ion of main body these ions to be released in the space by fan etc.These H
+(H
2O)
mAnd O
2 -(H
2O)
nOn the surface attached to the bacterium that swims, generate H behind the chemical reaction as free radical
2O
2Perhaps (OH).Because H
2O
2Perhaps (OH) shows extremely strong activity, thus, can surround airborne planktonic bacteria it is lost activity., (OH) be a kind of free radical here, expression atomic group OH.
Negative ions carries out chemical reaction at the cell surface of planktonic bacteria like that suc as formula shown in (1)~formula (3), generates the hydrogen peroxide H as free radical
2O
2Perhaps hydroxy (OH).Here, in formula (1)~formula (3), m, m ', n, n ' are any natural numbers.Thus, destroy planktonic bacteria by the decomposition of free radical.Therefore, airborne planktonic bacteria is lost activity and be removed.
H
+(H
2O)
m+O
2 -(H
2O)
n→·OH+1/2O
2+(m+n)H
2O…(1)
H
+(H
2O)
m+H
+(H
2O)
m’+O
2 -(H
2O)
n+O
2 -(H
2O)
n’→2·OH+O
2+(m+m’+n+n’)H
2O…(2)
H
+(H
2O)
m+H
+(H
2O)
m’+O
2 -(H
2O)
n+O
2 -(H
2O)
n’→H
2O
2+O
2+(m+m’+n+n’)H
2O…(3)
By above mechanism,, can access the effect of deactivating of the bacterium that swims etc. by emitting above-mentioned negative ions.
In addition, above-mentioned formula (1)~formula (3) is even because aerial harmful substance surface also can generate same effect, so as the hydrogen peroxide H of free radical
2O
2Perhaps hydroxy (OH) oxidation or decomposing harmful substances, by chemical substances such as formaldehyde and ammonia being converted to carbon dioxide and harmless material such as water, nitrogen, can be innoxious in fact.
Therefore, by driving Air Blast fan, cation and the anion that is taken place by ion generating device 1 can be passed out to outside the main body.And, by the effect of these cations and anion, airborne mould and bacterium is lost activity, can suppress its propagation.
In addition, in cation and anion, make the also deactivated effects of virus type such as Coxsackie virus, poliovirus, can prevent the pollution that causes because of sneaking into of these viruses.
In addition, confirm that also cation and anion have the effect of the molecule that is decomposed into the stink reason, can use the deodorizing in space.
In addition, when the selection terminal of transfer relay 203 was positioned at 203b one side, the ion that takes place from the 1st discharge part 12 became anion, together became from both sides' electrode generating negative ions all with the anion that takes place from the 2nd discharge part 13.Thereby become because of the electrical equipment in the family etc. in the too much space of cation a large amount of when supplying with anion hope and obtaining cation such in the natural forest and anion poised state or try to achieve under the situation of loosening effect, very effective.
In addition, because voltage applying circuit 20 can apply the alternating voltage waveform that begins from positive polarity between the 1st sparking electrode 12a shown in any one of Fig. 2 A, Fig. 2 B, Fig. 3, Fig. 4 A, Fig. 4 B, Fig. 8~Figure 11 and the 1st induction electrode 12b, applying the alternating voltage waveform that begins from negative polarity between the 2nd sparking electrode 13a and the 2nd induction electrode 13b gets final product, so beyond structure shown in Fig. 5 A, Fig. 5 B, for example, can adopt Figure 12, structure shown in Figure 13.
Figure 12 is the structure that the circuit than Fig. 5 B more cheap and component number has reduced.For convenience of description, mark prosign on the part identical with the embodiment shown in Fig. 5 B, voltage applying circuit 20 shown in Figure 12 has as the primary side drive circuit: input power supply 201, input impedance 204, commutation diode 206, transformer drive with switch element 212, electric capacity 211, fly-wheel diode 213.At input power supply 201 is to exchange under the situation of source power supply, by the input power supply 201 voltage via input resistance 204, commutation diode 206, to electric capacity 211 chargings, if become more than or equal to assigned voltage, then transformer drives with switch element 212 conductings, applies voltage on the primary side coil 202a of transformer 202.Then, the energy that is charged to electric capacity 211 drives with the primary side coil 202a discharge of switch element 212 with transformer 202 by transformer, and the voltage of electric capacity 211 turns back to zero, and charging discharges and recharges repeatedly with specified period once more.
Secondary-side circuitry as transformer 202, be equipped with 2 secondary coil 202b, 202c of transformer 202, these coils are connected with Fig. 2 A, Fig. 2 B, Fig. 3, Fig. 4 A, any one the 1st sparking electrode 12a, the 1st induction electrode 12b of Fig. 4 B, Fig. 8~Figure 11, the 2nd sparking electrode 13a, the 2nd induction electrode 13b respectively.Transformer by primary-side circuitry drives with switch element 212 conductings, and the energy of primary side is delivered to secondary coil 202b, the 202c of transformer, pulsing shape voltage.Have, each secondary coil and each electrode connect in the polarity of the polarity of the voltage that applies between the 1st sparking electrode 12a and the 1st induction electrode 12b and the voltage that applies between the 2nd sparking electrode 13a and the 2nd induction electrode 13b opposite again.
In addition, on the 1st sparking electrode 12a, not only connect the secondary coil 202b of transformer 202, and connect the negative electrode of diode 209, the anode of diode 209 via relay 214 ground connection or with one-sided (the line AC2: reference potential) be connected of input power supply 201.When input power supply 201 is when exchanging source power supply because the folk prescription ground connection of input AC source power supply in Japan, so do not have ground terminal electrical equipment etc. as long as with import power supply 201 one-sided just the connection can access identical functions.In addition, on the 2nd sparking electrode 13a, not only connect the secondary coil 202c of transformer 202, but also connect the anode of diode 208, the minus earth of diode 208 or be connected with one-sided (the line AC2) of input power supply 201.
Then, the operating voltage waveform is described.On the two ends of secondary coil 202b, the 202c of transformer 202, apply the impulse waveform of alternating voltage.Shown in Figure 14 A, at this moment, with the 1st sparking electrode 12a is that the voltage waveform of the 1st induction electrode 12b that observes of benchmark becomes the alternating voltage waveform that begins from positive polarity, as shown in Figure 14B, be that the voltage waveform of the 2nd induction electrode 13b that observes of benchmark becomes the alternating voltage waveform that begins from negative polarity with the 2nd sparking electrode 13a.
In addition, because secondary coil 202c is connected with line AC2 (according to circumstances being ground terminal) by the diode 208 of positive direction, with line AC2 is that the voltage waveform of the 2nd sparking electrode 13a that observes of benchmark is shown in Figure 15 A, in addition, the voltage waveform of the 2nd induction electrode 13b is shown in Figure 15 B, and the waveform of Figure 14 B becomes and is biased to negative waveform.Therefore, from the 2nd discharge part 13 generating negative ions.As anion is O
2 -(H
2O)
n(n is a natural number, means to have a plurality of H
2The O molecule).
On the other hand, because when relay 214 conductings, secondary coil 202b is connected with line AC2 by reciprocal diode 209, with line AC2 is that the voltage waveform of the 1st sparking electrode 12a that observes of benchmark is shown in Figure 16 A, in addition, the voltage waveform of the 1st induction electrode 12b is shown in Figure 16 B, and the waveform of Figure 14 A becomes and is biased to positive waveform.Therefore, take place and the anion that takes place at the 2nd discharge part 13 cation of same quantity roughly from the 1st discharge part 12.As cation is H
+(H
2O)
m(m is a natural number, means to have a plurality of H
2The O molecule).
In addition, Figure 17 A changes the figure that time shaft comes the waveform shown in presentation graphs 14A or Figure 14 B, and Figure 17 B changes the figure that time shaft comes the waveform shown in presentation graphs 16A or Figure 16 B.The voltage waveform that is applied on each electrode becomes the impulse waveform that decays in the short like this time, this is because the electric oscillation decay that the electrostatic capacitance of the inductance of transformer and resistance, electrode causes and the effect of fly-wheel diode 213 cause.Promptly, make the electric current that circulates by the voltage of on primary coil 202a, responding at the electric current that circulates on secondary coil 202b, the 202c, drive with switch element 212 by primary coil 202a, fly-wheel diode 213, transformer and reflux, thereby the voltage fluctuation that takes place on secondary coil 202b, 202c is decayed hastily.
In addition, Figure 18 A is that expression is the oscillogram of voltage waveform of the 1st sparking electrode 12a, the 2nd sparking electrode 13a of benchmark observation with line AC2 when relay 214 conductings, and is identical with Figure 15 A, Figure 16 A.Figure 18 B is that expression is the oscillogram of voltage waveform of the 1st sparking electrode 12a, the 2nd sparking electrode 13a of benchmark observation with line AC2 when relay 214 disconnects.When relay 214 conductings, shown in Figure 18 A, the voltage waveform of the 1st sparking electrode 12a that represents with line L1 is biased to positive side, and the voltage waveform of the 2nd sparking electrode 13a that represents with line L2 is biased to minus side.And when relay 214 disconnected, shown in Figure 18 B, the voltage waveform of the 2nd sparking electrode 13a that represents with line L2 was biased to not variation of minus side, and the voltage waveform of the 1st sparking electrode 12a that represents with line L1 is not changed to the alternation waveform with being biased.This is because when relay 214 disconnections, secondary coil 202b becomes floating state, the 1st ripple be bear, the 2nd ripple is the waveform of alternation later on, emits cation and anion two sides thus on a small quantity.
Therefore, when relay 214 disconnected, a spot of cation and the anion and a large amount of anion that takes place from the 2nd discharge part 13 that take place from the 1st discharge part 12 were as all cation and a large amount of anion states of becoming the anion affluence with trace.On the other hand, when relay 214 conductings, utilize, become the state of the ion that positive and negative roughly isodose takes place from the 1st discharge part 12 cation that takes place and the anion that takes place from the 2nd discharge part 13.
Therefore, by conducting/disconnection relay 214, can switch following two kinds of situations: by in air, roughly emitting to equivalent amount H
+(H
2O)
mWith O
2 -(H
2O)
n, these ions surround airborne mycoplankton and virus around, the situation of the state that the effect of the hydroxy (OH) by the free radical that generates this moment is sought to deactivate; And becoming a large amount of anions of supplying with in the too much space of cation because of the electrical equipment in the family etc., hope obtains in natural forest during the state of the ionic equilibrium of cation and anion or seek to loosen the situation of effect.
In addition, the such coil configuration of transformer 202 usefulness Figure 19 shown in Figure 12 constitutes.Figure 19 is the allocation plan of component configuration that the ion generating device of transformer shown in Figure 12 202 has been carried in expression.220 is electrode surface boards, the 221st of each electrode (not having diagram) of formation discharge usefulness in Figure 19, the electrode frame of fixed electrode panel part 220, the 222nd, moulding material, the 223rd, the substrate, the 224th of installation circuit block in stationary transformer 202, connector that input and output are used and the circuit-component carrying portion of carrying other circuit blocks.
Figure 13 is the circuit diagram of another other embodiments of expression voltage applying circuit 20.For convenience of description, on the part identical, mark prosign, omit its explanation with embodiment shown in Figure 12.Voltage applying circuit shown in Figure 13 20 is with the difference of voltage applying circuit 20 shown in Figure 12: uses 2 transformers 215,216 and be connected 2 fly-wheel diodes 217,218 on separately the primary coil, to replace 1 transformer 202 and fly-wheel diode 213 this point.In addition, the transformer as the primary side drive circuit drives with the place-exchange of switch element 212 with electric capacity 211.
At input power supply 201 is to exchange under the situation of source power supply, by the input power supply 201 voltage via input resistance 204, commutation diode 206, fly-wheel diode 217,218, give electric capacity 211 chargings, when becoming more than or equal to assigned voltage, transformer drives with switch element 212 conductings, and voltage is applied on the series circuit of primary side coil 216a of the primary side coil 215a of transformer 215 and transformer 216.Then, the energy of charging drives the series circuit discharge of the primary side coil 216a of primary side coil 215a with switch element 212, transformer 215, transformer 216 by transformer on electric capacity 211, the voltage of electric capacity 211 turns back to zero, and charging once more is with the specified period repeated charge.
In addition, on the 1st sparking electrode 12a, not only connect the secondary coil 215b of transformer 215, and connect the negative electrode of diode 209, the anode of diode 209 is connected via relay 214 ground connection or with one-sided (the line AC2) of input power supply 201.In addition, on the 2nd sparking electrode 13a, not only connect the secondary coil 216b of transformer 216, and connect the anode of diode 208, the minus earth of diode 208 or be connected with one-sided (the line AC2) of input power supply 201.
Because the operating voltage waveform of the voltage applying circuit shown in Figure 13 20 of this spline structure is identical with the operating voltage waveform (Figure 14 A~Figure 17 A, Figure 14 B~Figure 17 B) of voltage applying circuit 20 shown in Figure 12, its explanation of Therefore, omited.Voltage applying circuit 20 shown in Figure 13 is characterised in that: at transformer 215 that applies voltage between the 1st sparking electrode 12a and the 1st induction electrode 12b and the transformer 216 that applies voltage between the 2nd sparking electrode 13a and the 2nd induction electrode 13b is independently, and on the primary coil of separately transformer fly-wheel diode 217,218 is set respectively.
Like this, because the electric current of responding on primary coil 215a by the electric current that flows through in secondary coil 215b that voltage flow through only refluxes in primary coil 215a and fly-wheel diode 217, transformer 216 is not influenced.In addition, similarly, owing to the electric current of responding on primary coil 216a by the electric current that flows through at secondary coil 216b that voltage flow through only refluxes in primary coil 216a and fly-wheel diode 218, so to not influence of transformer 215.Therefore, even produce load change etc. on a discharge part, this change disappears to the influence that is applied to the voltage on another discharge part, can prevent the ionic weight change that takes place from another discharge part.
Have, voltage applying circuit 20 shown in Figure 13 is connected in series the primary coil 215a of transformer 215 and the primary coil 216a of transformer 216, also the circuit that these formations can be connected in parallel again.
In addition, the such coil configuration of transformer 215,216 usefulness Figure 20 shown in Figure 13 constitutes.Figure 20 is the allocation plan of component configuration that the ion generating device of transformer shown in Figure 13 215,216 has been carried in expression.For convenience of description, on the part identical, mark prosign with Figure 19.In Figure 20, the 220th, form the electrode surface board, the 221st of each electrode (not have diagram) of discharge usefulness, the electrode frame of fixed electrode panel part 220, the 222nd is installed the substrate, the 224th of circuit block, the connector that the lift-launch input and output are used and the circuit-component carrying portion of other circuit blocks in the time of moulding material, the 223rd, stationary transformer 215,216.
Transformer 215,216 is configured to arrange with the order of secondary coil 216b, primary coil 216a, primary coil 215a, secondary coil 215b.When the magnetic field that transformer 215,216 like this during configuration, can be guaranteed the distance between secondary coil 216b, the 215b, can alleviate on a secondary coil, to take place directly to the influence of another secondary coil.Therefore, can alleviate by mutual influence of magnetic field and make the variation in voltage that on each secondary coil, takes place, can prevent to change from the ion generating capacity of the ion generating device that has been applied in the voltage that produces from each secondary coil.
Have, Figure 12, transformer shown in Figure 13 drive with switch element 212 the no grid 2 terminal IGCTs of employing (" Sidac " [product of new electric unit industry]) are described in the above description, but are to use some different circuit, also can use IGCT (SCR) again.In addition, even the situation of input power supply 201 dc sources, so long as can obtain circuit with above-mentioned same work, no matter any circuit all can.That is, as the primary side drive circuit of this circuit, not the special circuit that limits, get final product so long as can access the circuit of same work.
Have again, ion generating device of the invention described above or ion generating device can carry in electrical equipments such as air-conditioner, dehumidifier, humidifier, air cleaner, freezer, fan-shaped heater, micro-wave oven, scrubbing-and-drying unit, dust catcher, sterilizing unit.If such electrical equipment, the original function of the equipment that adds changes airborne ionic weight and ionic equilibrium with the ion generating device that carries, and can make indoor environment become desirable atmosphere state.
In addition, in the above-described embodiment, understand that for example the single ion generating device that apparatus has the discharge part of a plurality of generation ions to form cation and anion individually takes place and is released to indoor structure independently of one another, structure of the present invention is not to only limit to this structure, can be cation and anion individually to take place and be released to indoor structure independently of one another with a plurality of ion generating devices yet.
Ion generating device of the present invention, ion generating device are mainly used in the various electrical equipments such as the air-conditioner that uses in enclosure space (in the room in the family housing, in the mansion, the ward of hospital and operating room, the car, in the aircraft, in the ship, in the warehouse, in the storehouse of freezer etc.), dehumidifier, humidifier, air cleaner, freezer, fan-shaped heater, micro-wave oven, scrubbing-and-drying unit, dust catcher, sterilizing unit.
Claims (24)
1. ion generating device, thus have by applying the ion generating device and the voltage applying circuit that is connected with described ion generating device that high voltage discharges and cation and anion take place, it is characterized in that:
Ion generating device has at least: 1 is arranged on the 1st discharge part and the 2nd discharge part that ion takes place on the same matrix material and respectively independently separately,
Above-mentioned the 1st discharge part and above-mentioned the 2nd discharge part all are positioned on the same plane of above-mentioned matrix material, and separate configuration independently respectively.
2. ion generating device as claimed in claim 1 is characterized in that:
Above-mentioned the 1st, the 2nd discharge part will be arranged on as dielectric lip-deep the 1st, the 2nd sparking electrode of above-mentioned matrix material and be embedded in the 1st, the 2nd induction electrode of above-mentioned dielectric inside respectively as a pair of and each self-forming.
3. ion generating device as claimed in claim 1 is characterized in that:
Above-mentioned the 1st discharge part and the 2nd discharge part are on the plane of above-mentioned matrix material, and separation is configured on its diagonal independently.
4. ion generating device as claimed in claim 1 is characterized in that:
Above-mentioned the 1st discharge part has: produce the 1st discharge position of discharge and surround the 1st discharge position around or a part with 1st conducting position of the 1st discharge position with voltage,
Above-mentioned the 2nd discharge part has: produce the 2nd discharge position of discharge and surround the 2nd discharge position around or a part with 2nd conducting position of the 2nd discharge position with voltage,
Above-mentioned the 1st, the 2nd discharge part and separates and is configured to the 1st conducting position independently and the 2nd conducting position is opposed all on the same plane of above-mentioned matrix material.
5. ion generating device as claimed in claim 2 is characterized in that:
Above-mentioned the 1st discharge part has: produce the 1st discharge position of discharge and surround the 1st discharge position around or a part with 1st conducting position of the 1st discharge position with voltage,
Above-mentioned the 2nd discharge part has: produce the 2nd discharge position of discharge and surround the 2nd discharge position around or a part with 2nd conducting position of the 2nd discharge position with voltage,
Above-mentioned the 1st, the 2nd discharge part and separates and is configured to the 1st conducting position independently and the 2nd conducting position is opposed all on the same plane of above-mentioned matrix material.
6. as claim 1 any one described ion generating device, it is characterized in that to claim 4:
Thereby above-mentioned voltage applying circuit is biased to positive voltage waveform with ac pulse voltage and makes it that cation take place by applying on above-mentioned the 1st discharge part, thereby above-mentioned ac pulse voltage is biased to negative voltage waveform makes its generating negative ions by applying on the 2nd discharge part.
7. as claim 1 any one described ion generating device, it is characterized in that to claim 4:
Above-mentioned voltage applying circuit has:
The 1st voltage application portion and switching part, can switch following two kinds of situations: thereby ac pulse voltage is biased to positive voltage waveform makes it situation of cation take place and apply thereby above-mentioned ac pulse voltage is biased to the situation that negative voltage makes its generating negative ions by on the 1st discharge part of above-mentioned ion generating device, applying; And
The 2nd voltage application portion is biased to negative voltage waveform by applying with ac pulse voltage, thereby makes its generating negative ions on the 2nd discharge part of above-mentioned ion generating device,
Can switch the situation of situation that cation and anion roughly take place equally and a generating negative ions.
8. as claim 1 any one described ion generating device, it is characterized in that to claim 4:
Above-mentioned voltage applying circuit has:
The 3rd voltage application portion and biasing switching part, can switch following two kinds of situations: thereby thereby ac pulse voltage is biased to positive voltage waveform makes its situation that cation takes place and make it that situation of cation, anion take place by on the 1st discharge part of above-mentioned ion generating device, applying by the voltage waveform that applies not above-mentioned ac pulse voltage biasing; And
The 2nd voltage application portion, thus above-mentioned ac pulse voltage is biased to negative voltage waveform makes its generating negative ions by on the 2nd discharge part of above-mentioned ion generating device, applying,
The situation that can switch cation that equivalent roughly takes place and anion with a spot of cation takes place and than the situation of the anion of cation amount volume.
9. ion generating device as claimed in claim 6 is characterized in that:
Being applied to ac pulse voltage on the 1st discharge part and being with the 1st sparking electrode is the alternating voltage waveform that the voltage of the 1st induction electrode of benchmark begins from positive polarity,
Being applied to ac pulse voltage on the 2nd discharge part and being with the 2nd sparking electrode is the alternating voltage waveform that the voltage of the 2nd induction electrode of benchmark begins from negative polarity.
10. ion generating device as claimed in claim 7 is characterized in that:
Being applied to ac pulse voltage on the 1st discharge part and being with the 1st sparking electrode is the alternating voltage waveform that the voltage of the 1st induction electrode of benchmark begins from positive polarity,
Being applied to ac pulse voltage on the 2nd discharge part and being with the 2nd sparking electrode is the alternating voltage waveform that the voltage of the 2nd induction electrode of benchmark begins from negative polarity.
11. ion generating device as claimed in claim 8 is characterized in that:
Being applied to ac pulse voltage on the 1st discharge part and being with the 1st sparking electrode is the alternating voltage waveform that the voltage of the 1st induction electrode of benchmark begins from positive polarity,
Being applied to ac pulse voltage on the 2nd discharge part and being with the 2nd sparking electrode is the alternating voltage waveform that the voltage of the 2nd induction electrode of benchmark begins from negative polarity.
12. ion generating device as claimed in claim 6 is characterized in that:
Above-mentioned voltage applying circuit has:
The 1st diode, negative electrode are connected on the reference potential, and anode is connected on the 2nd sparking electrode; And
The 2nd diode, when from the 1st discharge part generation cation, anode is connected on the said reference current potential, and negative electrode is connected on the 1st sparking electrode.
13. ion generating device as claimed in claim 7 is characterized in that:
Above-mentioned voltage applying circuit has:
The 1st diode, negative electrode are connected on the reference potential, and anode is connected on the 2nd sparking electrode;
The 2nd diode, when from the 1st discharge part generation cation, anode is connected on the said reference current potential, and negative electrode is connected on the 1st sparking electrode; And
The 3rd diode, when from the 1st discharge part generating negative ions, negative electrode is connected on the said reference current potential, and anode is connected on the 1st sparking electrode.
14. ion generating device as claimed in claim 6 is characterized in that:
Above-mentioned voltage applying circuit has: transformer, and it comprises the primary coil of driving side, at the 1st secondary coil that applies ac pulse voltage on the 1st discharge part and the 2nd secondary coil that applies ac pulse voltage on the 2nd discharge part,
The the 1st, the 2nd secondary coil of above-mentioned transformer is configured in the both sides of above-mentioned primary coil respectively.
15. ion generating device as claimed in claim 6 is characterized in that:
Above-mentioned voltage applying circuit has:
The 1st transformer, the secondary coil that it comprises the primary coil of driving side and apply ac pulse voltage on the 1st discharge part; And
The 2nd transformer, the secondary coil that it comprises the primary coil of driving side and apply ac pulse voltage on the 2nd discharge part,
Dispose the secondary coil of the 1st transformer, the primary coil of the 1st transformer, the primary coil of the 2nd transformer and the secondary coil of the 2nd transformer successively in the mode of guaranteeing the distance between the 1st transformer and the 2nd transformer.
16. ion generating device as claimed in claim 15 is characterized in that:
The primary coil of the 1st transformer is connected with the parallel connection of primary windings of the 2nd transformer.
17. ion generating device as claimed in claim 15 is characterized in that:
The primary coil of the primary coil of the 1st transformer and the 2nd transformer is connected in series.
18. ion generating device as claimed in claim 17 is characterized in that:
Be connected with fly-wheel diode on the primary coil of the primary coil of the 1st transformer and the 2nd transformer respectively.
19. an electrical equipment is characterized in that:
Be equipped with the described ion generating device of claim 6 and will pass out to airborne unloading part and form with the ion that this ion generating device takes place.
20. an electrical equipment is characterized in that:
Be equipped with the described ion generating device of claim 7 and will pass out to airborne unloading part and form with the ion that this ion generating device takes place.
21. an electrical equipment is characterized in that:
Be equipped with the described ion generating device of claim 8 and will pass out to airborne unloading part and form with the ion that this ion generating device takes place.
22. electrical equipment as claimed in claim 19 is characterized in that:
Above-mentioned cation is H
+(H
2O)
m, above-mentioned anion is O
2 -(H
2O)
n, wherein m, n are natural numbers.
23. electrical equipment as claimed in claim 20 is characterized in that:
Above-mentioned cation is H
+(H
2O)
m, above-mentioned anion is O
2 -(H
2O)
n, wherein m, n are natural numbers.
24. electrical equipment as claimed in claim 21 is characterized in that:
Above-mentioned cation is H
+(H
2O)
m, above-mentioned anion is O
2 -(H
2O)
n, wherein m, n are natural numbers.
Applications Claiming Priority (5)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP137098/2003 | 2003-05-15 | ||
| JP2003137098 | 2003-05-15 | ||
| JP74600/2004 | 2004-03-16 | ||
| JP2004074600A JP4063784B2 (en) | 2003-05-15 | 2004-03-16 | Ion generator, ion generator |
| PCT/JP2004/006588 WO2004102755A2 (en) | 2003-05-15 | 2004-05-10 | Ion generating element, ion generator, and electric device |
Related Child Applications (2)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN 200910160486 Division CN101621181B (en) | 2003-05-15 | 2004-05-10 | Ion generating element, ion generator, and electric device |
| CN 200910160487 Division CN101621182B (en) | 2003-05-15 | 2004-05-10 | Ion generating element, ion generator, and electric device |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN1791467A CN1791467A (en) | 2006-06-21 |
| CN1791467B true CN1791467B (en) | 2010-11-03 |
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| CN 200910160487 Expired - Fee Related CN101621182B (en) | 2003-05-15 | 2004-05-10 | Ion generating element, ion generator, and electric device |
| CN200480013304.6A Expired - Fee Related CN1791467B (en) | 2003-05-15 | 2004-05-10 | Ion generating element, ion generator, and electric device |
| CN 200910160486 Expired - Fee Related CN101621181B (en) | 2003-05-15 | 2004-05-10 | Ion generating element, ion generator, and electric device |
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|---|---|
| JP (14) | JP4218903B2 (en) |
| CN (3) | CN101621182B (en) |
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Also Published As
| Publication number | Publication date |
|---|---|
| JP4218903B2 (en) | 2009-02-04 |
| JP2012104490A (en) | 2012-05-31 |
| CN101621181A (en) | 2010-01-06 |
| JP2009059704A (en) | 2009-03-19 |
| JP4945009B2 (en) | 2012-06-06 |
| JP4750165B2 (en) | 2011-08-17 |
| JP2012196466A (en) | 2012-10-18 |
| JP2009059706A (en) | 2009-03-19 |
| JP2016010706A (en) | 2016-01-21 |
| JP2012129209A (en) | 2012-07-05 |
| JP2007305606A (en) | 2007-11-22 |
| CN101621181B (en) | 2012-09-12 |
| JP5097303B2 (en) | 2012-12-12 |
| JP5097304B2 (en) | 2012-12-12 |
| JP2009054591A (en) | 2009-03-12 |
| ES2367992T3 (en) | 2011-11-11 |
| CN1791467A (en) | 2006-06-21 |
| JP2011222538A (en) | 2011-11-04 |
| CN101621182B (en) | 2012-07-18 |
| JP2012196467A (en) | 2012-10-18 |
| JP2014167917A (en) | 2014-09-11 |
| JP2012074399A (en) | 2012-04-12 |
| CN101621182A (en) | 2010-01-06 |
| JP4751434B2 (en) | 2011-08-17 |
| JP2012161678A (en) | 2012-08-30 |
| JP4945008B2 (en) | 2012-06-06 |
| JP4856684B2 (en) | 2012-01-18 |
| JP2013176569A (en) | 2013-09-09 |
| JP4945003B2 (en) | 2012-06-06 |
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