JP2009135002A - Ion generation device, and electric equipment using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ion generation device high in ion generation efficiency. <P>SOLUTION: This ion generation device includes an ion generating element 9 including a discharge electrode 17 installed at a surface of a dielectric part 21, and an induction electrode 14 opposedly installed inside the dielectric part 21, and a boost transformer 8 having a primary winding 8a and a secondary winding 8b which are electromagnetically bonded mutually in reversed polarity. A high voltage side terminal of the secondary winding 8b is connected to the discharge electrode 17, and its referential voltage side terminal is connected to the induction electrode 14. Accordingly, the voltage of the discharge electrode 17 can be elevated easily. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an ion generator and an electric device using the same, and more particularly, an ion generator that releases positive ions and negative ions into a space and decomposes bacteria, fungi, harmful substances, etc. floating in the air. The present invention relates to an electric device using the.

Conventionally, ion generators that generate both positive ions and negative ions are known (see, for example, Patent Documents 1 and 2). The bipolar ions released into the air surround the airborne fungi and viruses in the air, and inactivate the airborne fungi and the like by the hydroxyl radical (.OH) generated at that time.
JP 2003-47651 A JP 2002-319472 A

  However, the conventional ion generator has a problem that the ion generation efficiency is low. As a method of increasing the ion generation amount of the ion generator, a method of increasing the discharge intensity or increasing the number of discharges can be considered. However, as shown in FIG. 13, even if the discharge intensity is increased or the number of discharges is increased, the effect of recombination of ions from a certain region around the discharge portion increases, and the ions hardly increase. The generated ozone and noise increase in proportion to the intensity and number of discharges.

  Therefore, a main object of the present invention is to provide an ion generator having high ion generation efficiency and an electric device using the same.

  An ion generating apparatus according to the present invention includes an ion generating element including a discharge electrode provided on a surface of a dielectric part and an induction electrode provided inside the dielectric part so as to face the discharge electrode, a discharge electrode, A voltage application circuit for generating an ion by applying an AC voltage between the dielectric electrodes. The voltage application circuit includes a step-up transformer having a primary winding and a secondary winding that are electromagnetically coupled to each other in opposite polarities, and a high-voltage side terminal of the secondary winding is connected to the discharge electrode, and the reference voltage side The terminal is connected to the dielectric electrode.

  Preferably, the step-up transformer includes a cylindrical bobbin. The primary winding is wound from one end side to the other end side of the outer peripheral surface of the bobbin, and the secondary winding is wound from the other end side to the one end side of the outer peripheral surface of the bobbin. The high-voltage side terminal of the primary winding is provided at the winding start end of the primary winding, and the high-voltage side terminal of the secondary winding is provided at the winding start end of the secondary winding. Yes.

  In another ion generator according to the present invention, each includes a discharge electrode provided on the surface of the dielectric portion and an induction electrode provided inside the dielectric portion so as to face the discharge electrode. And a second ion generation element, and a voltage application circuit for generating an ion by applying an alternating voltage between the discharge electrode and the dielectric electrode of each of the first and second ion generation elements. In this voltage application circuit, the cathode is connected to the discharge electrode of the first ion generating element, the anode is connected to the discharge electrode of the second ion generating element, and the anode is connected to the discharge electrode of the second ion generating element. A second diode element whose cathode receives a reference potential, and first and second step-up transformers each having a primary winding and a secondary winding electromagnetically coupled in opposite polarities to each other, The high voltage side terminal of the secondary winding of the first step-up transformer is connected to the discharge electrode of the first ion generating element, the reference voltage side terminal is connected to the dielectric electrode of the first ion generating element, The high voltage side terminal of the secondary winding of the step-up transformer is connected to the discharge electrode of the second ion generating element, and the reference voltage side terminal is connected to the dielectric electrode of the second ion generating element. And

  Preferably, each of the first and second step-up transformers includes a cylindrical bobbin. The primary winding of each of the first and second step-up transformers is wound from one end side of the outer peripheral surface of the bobbin toward the other end side, and the secondary winding is one from the other end side of the outer peripheral surface of the bobbin. It is wound toward the end side. The high-voltage side terminal of the primary winding is provided at the winding start end of the primary winding, and the high-voltage side terminal of the secondary winding is provided at the winding start end of the secondary winding. Yes.

  Preferably, the discharge electrodes of the first and second ion generating elements are provided apart from each other on the same surface of the same dielectric part, and the dielectric electrodes of the first and second ion generating elements are disposed inside the same dielectric. It is provided facing the discharge electrodes of the first and second ion generating elements.

  According to another aspect of the present invention, there is provided an electrical apparatus including the above-described ion generator and a sending unit that sends out ions generated by the ion generator into the air.

  The ion generator and the electrical apparatus according to the present invention include a voltage application circuit that generates an ion by applying an AC voltage between the discharge electrode and the dielectric electrode of the ion generation element. It includes a step-up transformer having a coupled primary winding and secondary winding, the high voltage side terminal of the secondary winding being connected to the discharge electrode, and the reference voltage side terminal being connected to the dielectric electrode. Therefore, the ground potential of the discharge electrode can be easily increased, and recombination of ions around the discharge portion can be suppressed. Therefore, even when the applied voltage and the number of discharges are increased, ions can be generated efficiently.

[Embodiment 1]
1 is a circuit diagram showing a configuration of an ion generator according to Embodiment 1 of the present invention. In FIG. 1, the ion generator includes a voltage application circuit 2 connected to an AC power supply 1 and an ion generation element 9 driven by an output voltage of the voltage application circuit 2. AC power supply 1 is a commercial AC power supply, for example. In Japan, one of the two terminals of the outlet connected to the commercial AC power supply is grounded.

  The voltage application circuit 2 includes an input resistance element 3, a rectifier diode 4, a transformer driving switching element 5, a capacitor 6, a flywheel diode 7, and a step-up transformer 8. Input resistance element 3, rectifier diode 4, capacitor 6, and flywheel diode 7 are connected in series between output terminal 1a of AC power supply 1 and ground terminal 1b. The transformer driving switching element 5 is constituted by a gateless two-terminal thyristor, and is connected between the cathode of the rectifier diode 4 and the ground terminal 1b.

  Step-up transformer 8 includes a primary winding 8a and a secondary winding 8b that are electromagnetically coupled with opposite polarities. The high voltage side terminal (terminal with dots in FIG. 1) and the reference voltage side terminal of the primary winding 8a are connected to the anode and cathode of the flywheel diode 7, respectively. The high voltage side terminals (terminals with dots in FIG. 1) and the reference voltage side terminals of the secondary winding 8b are connected to the discharge electrode side terminals 9a and the dielectric electrode side terminals 9b of the ion generating element 9, respectively. .

  FIG. 2 is a cross-sectional view showing the configuration of the step-up transformer 8. In FIG. 2, the step-up transformer 8 includes a cylindrical bobbin 10, a core 11 inserted into the bobbin 10, and a primary winding 8a and a secondary winding 8b. On the outer peripheral surface of the bobbin 10, three ring-shaped convex portions 10a, 10b, and 10c are provided in order. The distance between the convex portions 10a and 10b is set smaller than the distance between the convex portions 10b and 10c.

  The primary winding 8a is wound around the outer peripheral surface of the bobbin 10 from the convex portion 10a side to the convex portion 10b side in a predetermined rotation direction, and the secondary winding 8b is directed from the convex portion 10c side to the convex portion 10b side. The bobbin 10 is wound around the outer peripheral surface in a predetermined rotational direction. Therefore, the primary winding 8a and the secondary winding 8b are wound in opposite directions and are electromagnetically coupled with opposite polarity. A terminal on the convex portion 10a side of the primary winding 8a is a high voltage side terminal THa (a terminal with a dot in FIG. 1), and a terminal on the convex portion 10b side is a reference voltage side terminal TLa. The terminal on the convex portion 10c side of the secondary winding 8b is a high voltage side terminal THb (the terminal with a dot in FIG. 1), and the terminal on the convex portion 10b side is a reference voltage side terminal TLb.

  FIG. 3 is a cross-sectional view showing the configuration of the ion generating element 9. In FIG. 3, the ion generating element 9 includes two stacked dielectric substrates 12 and 13. A dielectric electrode 14 and a connection terminal 15 are integrally formed on the surface of the dielectric substrate 12, a dielectric electrode side terminal 9b is formed on the back surface of the dielectric substrate 12, and the connection terminal 15 and the dielectric electrode side terminal 9b are dielectric. They are connected to each other through through holes 16 penetrating the body substrate 12. Therefore, the dielectric electrode side terminal 9b and the dielectric electrode 17 are electrically connected.

  Further, the discharge electrode 17 and the connection terminal 18 are integrally formed on the surface of the dielectric substrate 13, and the discharge electrode side terminal 9a is formed on the back surface of the dielectric substrate 12, and the connection terminal 18 and the discharge electrode side terminal 9a are formed. Are connected to each other through a through hole 19 penetrating the two dielectric substrates 12 and 13. Therefore, the discharge electrode side terminal 9a and the discharge electrode 17 are electrically connected. The dielectric electrode 14 and the discharge electrode 17 are arranged in parallel to face each other. The entire surface of the dielectric substrate 13 on which the discharge electrode 17 and the connection terminal 18 are formed is covered with a coating layer 20.

  The dielectric portion 21 which is a laminate of the dielectric substrates 12 and 13 is formed in, for example, a substantially rectangular parallelepiped shape having a length of 15 mm, a width of 37 mm, and a thickness of 0.45 mm. If an inorganic substance is selected as the material for the dielectric substrates 12 and 13, ceramics such as high-purity alumina, crystallized glass, forsterite, and steatite can be used. In addition, if an organic material is selected as the material for the dielectric substrates 12 and 13, a resin such as polyimide or glass epoxy having excellent oxidation resistance is preferable. However, in consideration of corrosion resistance, it is desirable to select an inorganic material as the material of the dielectric substrates 12 and 13, and further, it is preferable to mold using ceramic in consideration of moldability and ease of electrode formation described later. It is.

  In addition, since it is desirable that the insulation resistance between the discharge electrode 17 and the induction electrode 14 is uniform, the material of the dielectric substrates 12 and 13 is preferably as long as the density variation is small and the insulation rate is uniform. is there.

  In addition, the shape of the dielectric portion 21 may be a shape other than a substantially rectangular parallelepiped shape (for example, a disc shape, an elliptical plate shape, a polygonal plate shape, etc.), and may be a cylindrical shape. In view of productivity, it is preferable to have a substantially rectangular parallelepiped shape (including a disc shape and a flat plate shape) as in the first embodiment.

  The discharge electrode 17 is formed integrally with the dielectric substrate 12 on the surface of the dielectric substrate 12. The material of the discharge electrode 17 can be used without particular limitation as long as it has conductivity, such as tungsten. However, it does not cause melting or deformation due to the discharge energy.

  The induction electrode 14 is provided in parallel with the discharge electrode 17 with the dielectric substrate 13 interposed therebetween. With this arrangement, the distance between the discharge electrode 17 and the induction electrode 13 (hereinafter referred to as the interelectrode distance) can be made constant, so that the insulation resistance between the electrodes 17 and 13 can be made uniform and the discharge can be made uniform. The state can be stabilized and positive ions and negative ions can be suitably generated. When the dielectric portion is cylindrical, the discharge electrode 17 is provided on the outer peripheral surface of the cylindrical dielectric portion, and the induction electrode 14 is provided coaxially with the discharge electrode 17 inside the dielectric portion. Thus, the distance between the electrodes can be made constant.

  As the material of the induction electrode 14, as in the case of the discharge electrode 17, any material can be used without particular limitation as long as it has conductivity, such as tungsten. However, it does not cause melting or deformation due to the discharge energy. It becomes a condition.

  Since the discharge electrode side terminal 9a is electrically connected to the discharge electrode 17, one end of a lead wire (such as a copper wire or an aluminum wire) is connected to the discharge electrode side terminal 9a, and the other end of the lead wire is connected to a step-up transformer. By connecting to the secondary winding 8b of 8, the discharge electrode 17 and the secondary winding 8b of the step-up transformer 8 can be electrically connected.

  Since the induction electrode side terminal 9b is electrically connected to the induction electrode 14, one end of a lead wire (such as a copper wire or an aluminum wire) is connected to the induction electrode side terminal 9b, and the other end of the lead wire is connected to the induction electrode side terminal 9b. By connecting to the secondary winding 8b of the step-up transformer 8, the induction electrode 14 and the secondary winding 8b of the step-up transformer 8 can be electrically connected.

  Further, it is desirable that the discharge electrode side terminal 9a and the induction electrode side terminal 9b are provided on the surface of the dielectric portion 21 other than the surface on which the discharge electrode 17 is provided. With such a configuration, unnecessary lead wires or the like are not provided on the upper surface of the dielectric portion 21, so the ion generator shown in FIG. 1 and a blower fan that sends out ions generated by the ion generator into the air. In an electric device equipped with (not shown), the air flow from the blower fan is less likely to be disturbed, and neutralization of positive ions and negative ions can be reduced. Therefore, in the ion generating element 9, the discharge electrode 17 is provided on the upper surface of the dielectric portion 21, and the discharge electrode side terminal 9 a and the induction electrode side terminal 9 b are provided on the lower surface of the dielectric portion 21.

  In the ion generating element 9, the discharge electrode 17 has an acute angle portion (not shown), and an electric field is concentrated at that portion to cause local discharge. Further, the discharge electrode 17 and the induction electrode 14 are similar in shape, and their sizes are substantially the same.

  Next, the operation of the ion generator shown in FIGS. 1 to 3 will be described. The capacitor 6 is charged via the input resistance element 3 and the rectifier diode 4 by the output voltage of the AC power supply 1. When the inter-terminal voltage of the capacitor 6 becomes equal to or higher than the specified voltage, the transformer driving switching element 5 is turned on, and the inter-terminal voltage of the capacitor 6 is applied to the primary winding 8 a of the step-up transformer 8. Immediately thereafter, the charge charged in the capacitor 6 is discharged through the primary side winding 8a and the transformer driving switching element 5, the voltage across the terminals of the capacitor 6 returns to zero, and the capacitor 6 is charged again. Charging / discharging is repeated in a cycle. When the transformer driving switching element 5 is turned on, the energy on the primary winding 8a side of the step-up transformer 8 is transmitted to the secondary winding 8b of the step-up transformer 8, and an impulse is generated between the terminals of the secondary winding 8b. A waveform alternating voltage is applied. As a result, discharge occurs between the discharge electrode 17 and the dielectric electrode 14 of the ion generating element 8, and ions are generated.

That is, when a discharge is generated between the discharge electrode 17 and the dielectric electrode 14, oxygen molecules or water molecules in the air are ionized by receiving energy from electrons generated by the discharge, and H ⁺ (H ₂ O) which is a positive ion. ions mainly composed of _m and negative ions O ₂ ⁻ (H ₂ O) _n are generated. When these ions are released into the space by a fan or the like, H ⁺ (H ₂ O) _m and O ₂ ⁻ (H ₂ O) _n adhere to the surface of the floating bacteria and chemically react with H, which is an active species. ₂ O ₂ or (.OH) is produced. Since H ₂ O ₂ or (.OH) exhibits very strong activity, they can surround and inactivate airborne bacteria in the air. Here, (.OH) is one kind of active species, and represents radical OH.

In addition, hydrogen peroxide H ₂ O ₂ or hydroxyl radical (.OH), which is an active species, oxidizes or decomposes harmful substances and converts chemical substances such as formaldehyde and ammonia into harmless substances such as carbon dioxide, water, and nitrogen. By converting it to a new material, it can be made substantially harmless.

  Therefore, as shown in FIG. 4, the ion generator and the blower fan 22 shown in FIG. 1 are mounted on an electrical device, and the blower fan 22 is driven to generate positive ions and negative ions generated by the ion generating element 9. Can be sent out. And by the action of these positive ions and negative ions, it is possible to inactivate mold and fungi in the air and suppress their growth.

  In addition, positive ions and negative ions have a function to inactivate viruses such as Coxsackie virus and polio virus, and can prevent contamination due to mixing of these viruses.

  FIG. 5 is a circuit diagram showing a comparative example of the first embodiment, which is compared with FIG. In FIG. 5, the ion generator differs from the ion generator of Embodiment 1 in that the voltage application circuit 2 is replaced with a voltage application circuit 23, and the voltage application circuit 23 is the same as that of the voltage application circuit 2. The step-up transformer 8 is replaced with the step-up transformer 24.

  Step-up transformer 24 includes a primary winding 24a and a secondary winding 24b that are electromagnetically coupled to each other with the same polarity. The high voltage side terminal (terminal with dots in FIG. 5) and the reference voltage side terminal of the primary winding 24a are connected to the anode and cathode of the flywheel diode 7, respectively. The high voltage side terminal (the terminal with dots in FIG. 5) and the reference voltage side terminal of the secondary winding 24b are connected to the dielectric electrode side terminal 9b and the discharge electrode side terminal 9a of the ion generating element 9, respectively. .

  FIG. 6 is a cross-sectional view showing the configuration of the step-up transformer 24. In FIG. 6, the step-up transformer 24 includes a cylindrical bobbin 10, the core 11 inserted into the bobbin 10, and a primary winding 24a and a secondary winding 24b. On the outer peripheral surface of the bobbin 10, three ring-shaped convex portions 10a, 10b, and 10c are provided in order. The distance between the convex portions 10a and 10b is set smaller than the distance between the convex portions 10b and 10c.

  The primary winding 24a is wound around the outer peripheral surface of the bobbin 10 from the convex portion 10a side to the convex portion 10b side in a predetermined rotation direction, and the secondary winding 24b is directed from the convex portion 10b side to the convex portion 10c side. The bobbin 10 is wound around the outer peripheral surface in a predetermined rotational direction. Therefore, the primary winding 24a and the secondary winding 24b are wound in the same direction and are electromagnetically coupled with the same polarity. A terminal on the convex portion 10a side of the primary winding 24a is a high voltage side terminal THa (a terminal with a dot in FIG. 5), and a terminal on the convex portion 10b side is a reference voltage side terminal TLa. A terminal on the convex portion 10b side of the secondary winding 24b is a high voltage side terminal THb (a terminal with a dot in FIG. 5), and a terminal on the convex portion 10c side is a reference voltage side terminal TLb. The other configuration and operation of this ion generator are the same as those of the ion generator of Embodiment 1, and therefore description thereof will not be repeated.

  7A to 7C show the voltage Vc between the discharge electrode 17 and the dielectric electrode 14, the voltage Vb between the dielectric electrode 14 and the ground terminal 1b, and the discharge in the ion generator according to the comparative example shown in FIG. It is a wave form diagram which shows voltage Va between the electrode 17 and the ground terminal 1b. 7D to 7F show the voltage Vc between the discharge electrode 17 and the dielectric electrode 14 and the voltage Vb between the dielectric electrode 14 and the ground terminal 1b in the ion generator of the present invention shown in FIG. FIG. 6 is a waveform diagram showing a voltage Va between the discharge electrode 17 and the ground terminal 1b.

  7A to 7F, when an AC voltage Vc is applied between the discharge electrode 17 and the dielectric electrode 14 of the ion generating element 9, discharge occurs, and the amplitude of the AC voltage gradually decreases. The maximum value of the amplitude of the AC voltage Vc is 4.24 kV in the comparative example and 4.25 V in the present invention, which is substantially the same in the comparative example and the present invention.

  However, the maximum value of the amplitude of the AC voltage Vb is 1.59 kV in the comparative example and 1.14 V in the present invention, and the present invention is smaller than the comparative example. Moreover, the maximum value of the amplitude of the AC voltage Va is 1.82 kV in the comparative example, and 2.29 kV in the present invention, and the present invention is larger than the comparative example. Therefore, it has been found that even when the same AC voltage Vc is applied between the discharge electrode 17 and the dielectric electrode 14 of the ion generating element 9, the present invention can apply a voltage Va considerably higher than that of the comparative example to the discharge electrode 17.

  In the present invention, as shown in FIG. 2, the distance between the high voltage side terminal THb at the start of the secondary winding 8b of the step-up transformer 8 and the primary winding 8a is large, and the coupling capacitance between them is large. The value is relatively small. On the other hand, in the comparative example, as shown in FIG. 5, the distance between the high voltage side terminal THb at the start of the secondary winding 24b of the step-up transformer 24 and the primary winding 24a is small, and those The coupling capacitance value between them is relatively large. The voltage Va of the discharge electrode 17 of the present invention is higher than the voltage Va of the discharge electrode 17 of the comparative example because the coupling capacitance between the high voltage side terminal THb of the secondary winding 8b of the step-up transformer 8 and the primary winding 8a. This is presumably because the value is smaller than the coupling capacitance value between the high voltage side terminal THb of the secondary winding 24b of the step-up transformer 24 and the primary winding 24a. When the coupling capacitance value is small, the load capacitance value (the sum of the coupling capacitance value and the capacitance value between the electrodes 14 and 17 of the ion generating element 9) of the secondary winding 8b of the step-up transformer 8 becomes small, and the output of the step-up transformer 8 The voltage increases.

  FIG. 8 is a diagram showing the relationship between the discharge intensity (or the number of discharges) of the ion generating element 9 and the amount of generated ions. Note that the discharge intensity of the ion generating element 9 increases in accordance with the AC voltage Vc between the discharge electrode 17 and the dielectric electrode 14 of the ion generating element 9. In FIG. 8, when the discharge intensity (or the number of discharges) of the ion generating element 9 is increased, the ion generation amount is saturated at a relatively low level of the discharge intensity (or the number of discharges) in the comparative example. I found it difficult. If conditions such as the number of discharges are the same, the higher the voltage Va of the discharge electrode 17, the higher the ion emission efficiency. Therefore, when the discharge intensity is increased, the ion generation amount of the present invention is the ion generation amount of the comparative example. It becomes harder to saturate than.

  Therefore, according to the ion generator of the first embodiment, it is possible to easily increase the ground potential of the discharge electrode 17, and prevent reduction in ion emission efficiency due to recombination of ions around the discharge part, Even when the applied voltage and the number of discharges are increased, ions can be efficiently discharged.

[Embodiment 2]
FIG. 9 is a circuit diagram showing a configuration of an ion generating apparatus according to Embodiment 2 of the present invention, and is a diagram to be compared with FIG. In FIG. 9, the ion generator differs from the ion generator of FIG. 1 in that the voltage application circuit 2 is replaced with a voltage application circuit 30 and an ion generation element 35 is added.

  The voltage application circuit 30 is obtained by adding a flywheel diode 31, a step-up transformer 32, and diodes 33 and 34 to the voltage application circuit 2. The anode of the flywheel diode 31 is connected to the cathode of the rectifier diode 4 via the capacitor 6, and the cathode of the flywheel diode 31 is connected to the anode of the flywheel diode 7.

  The step-up transformer 32 has the same configuration as the step-up transformer 8 and includes a primary winding 32a and a secondary winding 32b that are electromagnetically coupled to each other in opposite polarities. The high voltage side terminal (terminal with dots in FIG. 9) and the reference voltage side terminal of the primary winding 32a are connected to the cathode and anode of the flywheel diode 31, respectively. The high voltage side terminal (terminal with dots in FIG. 9) and the reference voltage side terminal of the secondary winding 32b are connected to the discharge electrode side terminal 35a and the dielectric electrode side terminal 35b of the ion generating element 35, respectively. . The polarity of the voltage applied between the discharge electrode side terminal 35a and the dielectric electrode side terminal 35b of the ion generating element 35 is the voltage applied between the discharge electrode side terminal 9a and the dielectric electrode side terminal 9b of the ion generating element 9. The polarity is reversed.

  The anode of the diode 33 is connected to the discharge electrode side terminal 9a of the ion generating element 9, and the cathode thereof is connected to the ground terminal 1b. The anode of the diode 34 is connected to the ground terminal 1 b, and the cathode thereof is connected to the discharge electrode side terminal 35 a of the ion generating element 35.

  As shown in FIG. 10, the ion generating element 35 is provided in the same dielectric portion 21 as the ion generating element 9. That is, the ion generating element 35 includes a dielectric electrode 36 and a connection terminal 37 formed on the surface of the dielectric substrate 12. The dielectric electrode 36 and the connection terminal 37 are electrically connected. The connection terminal 37 is connected to a dielectric electrode side terminal 35 b formed on the back surface of the dielectric substrate 12 through a through hole 38 penetrating the dielectric substrate 12. Therefore, the dielectric electrode side terminal 35b and the dielectric electrode 36 are electrically connected.

  The ion generating element 35 includes a discharge electrode 39 and a connection terminal 40 formed on the surface of the dielectric substrate 13. The connection terminal 40 is connected to a discharge electrode side terminal 35 a formed on the back surface of the dielectric substrate 12 through a through hole 41 penetrating the dielectric substrates 12 and 13. Therefore, the discharge electrode side terminal 35a and the discharge electrode 39 are electrically connected. The dielectric electrode 36 and the discharge electrode 39 are disposed to face each other. The entire surface of the dielectric substrate 13 on which the discharge electrodes 17 and 39 and the connection terminals 18 and 40 are formed is covered with the coating layer 20.

  Further, the ion generating elements 9 and 35 are formed symmetrically with respect to a plane passing through the centers of the dielectric substrates 12 and 13 and perpendicular to the dielectric substrates 12 and 13. That is, the dielectric electrode side terminals 9b and 35b are disposed adjacent to each other, and the discharge electrode side terminals 9a and 35a are disposed on both sides of the dielectric electrode side terminals 9b and 35b. Therefore, the distance between the discharge electrode side terminals 9a and 35a can be increased, and the coupling capacitance value between them can be reduced.

  Next, the operation of the ion generator shown in FIGS. 9 and 10 will be described. The capacitor 6 is charged via the input resistance element 3 and the rectifier diode 4 by the output voltage of the AC power supply 1. When the inter-terminal voltage of the capacitor 6 becomes equal to or higher than the specified voltage, the transformer driving switching element 5 is turned on, and the inter-terminal voltage of the capacitor 6 is applied to the primary windings 8a and 32a of the step-up transformers 8 and 32. The Immediately after that, the electric charge charged in the capacitor 6 is discharged through the primary side windings 8a and 32a and the switching element 5 for driving the transformer, the voltage between the terminals of the capacitor 6 returns to zero, and the capacitor 6 is charged again. The charging / discharging is repeated at a specified cycle. When the transformer driving switching element 5 is turned on, the energy on the primary windings 8a, 32a side of the step-up transformers 8, 32 is transmitted to the secondary windings 8b, 32b of the step-up transformers 8, 32, and the secondary An alternating voltage having an impulse waveform is applied between the terminals of the windings 8b and 32b. As a result, discharge occurs between the discharge electrode and the dielectric electrode of the ion generating elements 8 and 32, and ions are generated.

  The discharge electrode 39 of the ion generating element 35 is connected not only to the high voltage side terminal THb of the secondary winding 32 b of the step-up transformer 32 but also to the cathode of the diode 34. Therefore, the voltage Va between the discharge electrode 39 and the ground terminal 1b and the voltage Vb between the induction electrode 36 and the ground terminal 1b are applied to the high voltage side terminal THb and the reference voltage side terminal TLb of the secondary winding 32b, respectively. A voltage obtained by adding a positive DC bias voltage to an AC voltage having an impulse waveform. Accordingly, negative ions generated by the ion generating element 35 are neutralized on the discharge electrode 39, and positive ions are repelled and discharged by the discharge electrode 39.

  The discharge electrode 17 of the ion generating element 9 is connected not only to the high voltage side terminal THb of the secondary winding 8 b of the step-up transformer 8 but also to the anode of the diode 33. Therefore, the voltage between the discharge electrode 17 and the ground terminal 1b and the voltage between the induction electrode 14 and the ground terminal 1b are impulses applied to the high voltage side terminal THb and the reference voltage side terminal TLb of the secondary winding 8b, respectively. This is a voltage obtained by adding a negative DC bias voltage to the waveform AC voltage. Accordingly, positive ions generated in the ion generating element 9 are neutralized on the discharge electrode 17, and negative ions are repelled and discharged by the discharge electrode 17.

  Further, the discharge electrodes 17 and 39 and the induction electrodes 14 and 36 are similar to each other and have substantially the same size. Further, the insulation resistance value between the discharge electrode 17 and the induction electrode 14 and the insulation resistance value between the discharge electrode 39 and the induction electrode 36 are substantially the same. Therefore, if voltages having substantially the same absolute value are applied between the discharge electrode 17 and the induction electrode 14 and between the discharge electrode 39 and the induction electrode 36, substantially the same amount of positive ions and negative ions are generated in the ion generating element. 35,9.

Note that positive ions include H ⁺ (H ₂ O) _m , and negative ions include O ₂ ⁻ (H ₂ O) _n . Here, each of m and n is a natural number, (H ₂ O) _m means that m H ₂ O molecules are attached to H ⁺ , and (H ₂ O) _n is O ₂ ⁻ to H _2. It means that there are n ₂ O molecules. Thus, both positive and negative ions are individually released, and the effect of releasing both H ⁺ (H ₂ O) _m and O ₂ ⁻ (H ₂ O) _{n in} the air is as described above. .

  FIG. 11 is a circuit diagram showing a comparative example of the second embodiment, which is compared with FIG. In FIG. 11, the ion generator differs from the ion generator of Embodiment 2 in that the voltage application circuit 30 is replaced with a voltage application circuit 40. The step-up transformers 8 and 32 are replaced with the step-up transformers 24 and 41.

  The configuration of the step-up transformer 24 is as described in FIG. 6, and the step-up transformer 41 has the same configuration as the step-up transformer 24. Step-up transformer 24 includes a primary winding 24a and a secondary winding 24b that are electromagnetically coupled to each other with the same polarity. The high voltage side terminal (terminal with dots in FIG. 11) and the reference voltage side terminal of the primary winding 24a are connected to the anode and cathode of the flywheel diode 7, respectively. The high voltage side terminal (terminal with dots in FIG. 11) and the reference voltage side terminal of the secondary winding 24b are connected to the dielectric electrode side terminal 9b and the discharge electrode side terminal 9a of the ion generating element 9, respectively. .

  Step-up transformer 41 includes a primary winding 41a and a secondary winding 41b that are electromagnetically coupled to each other with the same polarity. The high voltage side terminal (terminal with dots in FIG. 11) and the reference voltage side terminal of the primary winding 41a are connected to the anode and cathode of the flywheel diode 31, respectively. The high voltage side terminal (terminal with dots in FIG. 11) and the reference voltage side terminal of the secondary winding 41b are connected to the dielectric electrode side terminal 35b and the discharge electrode side terminal 35a of the ion generating element 35, respectively. . Since the other configuration and operation of this ion generator are the same as those of the ion generator of Embodiment 2, the description thereof will not be repeated.

  12A to 12C show the voltage Vc between the discharge electrode 39 and the dielectric electrode 36 of the ion generating element 35 and the voltage between the dielectric electrode 36 and the ground terminal 1b in the ion generator according to the comparative example shown in FIG. It is a wave form diagram which shows the voltage Va between the voltage Vb and the discharge electrode 39 and the ground terminal 1b. 12D to 12F show the voltage Vc between the discharge electrode 39 and the dielectric electrode 36 and the voltage Vb between the dielectric electrode 36 and the ground terminal 1b in the ion generator of the present invention shown in FIG. FIG. 6 is a waveform diagram showing a voltage Va between the discharge electrode 39 and the ground terminal 1b.

  12A to 12F, when an AC voltage Vc is applied between the discharge electrode 39 and the dielectric electrode 36 of the ion generating element 35, discharge occurs, and the amplitude of the AC voltage Vc gradually decreases. The maximum value of the amplitude of the AC voltage Vc is 4.65 kV in the comparative example and 4.48 V in the present invention, which is substantially the same in the comparative example and the present invention.

  However, the maximum value of the amplitude of the AC voltage Vb is 3.21 kV in the comparative example and 1.11 V in the present invention, and the present invention is smaller than the comparative example. Further, the maximum value of the amplitude of the AC voltage Va is 1.30 kV in the comparative example and 2.85 kV in the present invention, and the present invention is larger than the comparative example. Therefore, it has been found that even when the same AC voltage Vc is applied between the discharge electrode 39 and the dielectric electrode 36 of the ion generating element 35, the present invention can apply a voltage Va that is considerably larger than that of the comparative example to the discharge electrode 39.

  As described in the first embodiment, the voltage Va of the discharge electrode 39 according to the present invention is higher than the voltage Va of the discharge electrode 39 of the comparative example because the secondary winding 32b of the step-up transformer 32 has a higher voltage side. This is because the coupling capacitance value between the terminal THb and the primary winding 32a is smaller than the coupling capacitance value between the high voltage side terminal THb of the secondary winding 41b of the step-up transformer 41 and the primary winding 41a.

  Further, the relationship between the discharge intensity (or the number of discharges) of the ion generating elements 9 and 35 and the amount of ion generation is shown in FIG. 8 by increasing the discharge intensity (or the number of discharges) of the ion generating elements 9 and 35. As a result, it was found that in the comparative example, the ion generation amount is saturated at a relatively low level of discharge intensity (or the number of discharges), but in the present invention, it is difficult to saturate. For example, the ion generation amount of the ion generator of the present invention shown in FIG. 9 is 20 to 30% higher than the ion generation amount of the ion generator of the comparative example shown in FIG. If the conditions such as the number of discharges are the same, the higher the voltage Va of the discharge electrodes 17 and 39, the higher the ion emission efficiency. Therefore, when the discharge intensity is increased, the ion generation amount of the present invention is that of the comparative example. It becomes harder to saturate than the amount generated.

  Therefore, according to the ion generator of the second embodiment, it is possible to easily increase the ground potential of the discharge electrodes 17 and 39, and to prevent the reduction of ion emission efficiency due to recombination of ions around the discharge part. Even when the applied voltage and the number of discharges are increased, ions can be efficiently released.

  In the second embodiment, the primary windings 8a and 32a of the step-up transformers 8 and 32 are connected in series, but a circuit configuration in which the primary windings 8a and 32a are connected in parallel is also possible.

  In the first and second embodiments, a gateless two-terminal thyristor is used as the transformer driving switching element 5, but a thyristor (SCR) may be used by using a slightly different circuit.

  The configuration of the primary side drive circuit of the step-up transformers 8 and 32 is not particularly limited as long as the circuit can obtain the same operation. For example, a DC power supply may be used instead of the AC power supply 1, and the output voltage of the DC power supply may be converted into an AC voltage and applied to the primary windings 8a and 32a of the step-up transformers 8 and 32.

  Further, the above-described ion generator according to the present invention is mounted on an electrical device such as an air conditioner, a dehumidifier, a humidifier, an air cleaner, a refrigerator, a fan heater, a microwave oven, a washing dryer, a vacuum cleaner, and a sterilizer. Is possible.

  This electrical apparatus may be equipped with a sending means (for example, the blower fan 22 in FIG. 4) that sends both positive ions and negative ions generated by the ion generator into the air. In such an electric device, in addition to the original function of the device, the action of positive ions and negative ions released from the installed ion generator inactivates molds and fungi in the air to suppress their growth. The indoor environment can be brought into a desired atmosphere state.

  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.

It is a circuit diagram which shows the structure of the ion generator by Embodiment 1 of this invention. It is sectional drawing which shows the structure of the step-up transformer shown in FIG. It is sectional drawing which shows the structure of the ion generating element shown in FIG. It is a block diagram which shows the principal part of the electric equipment carrying the ion generator shown in FIG. FIG. 3 is a circuit diagram showing a comparative example of the first embodiment. FIG. 6 is a cross-sectional view illustrating a configuration of the step-up transformer illustrated in FIG. 5. FIG. 6 is a diagram for explaining an effect of the first embodiment. FIG. 10 is another diagram for explaining the effect of the first embodiment. It is a circuit diagram which shows the structure of the ion generator by Embodiment 2 of this invention. It is sectional drawing which shows the structure of the ion generating element shown in FIG. FIG. 6 is a circuit diagram showing a comparative example of the second embodiment. FIG. 10 is a diagram for explaining an effect of the second embodiment. It is a figure for demonstrating the problem of the conventional ion generator.

Explanation of symbols

  1 AC power supply, 1a output terminal, 1b ground terminal, 2, 23, 30, 40 voltage application circuit, 3 input resistance element, 4 rectifier diode, 5 transformer driving switching element, 6 capacitor, 7 flywheel diode, 8, 24 , 32, 41 Step-up transformer, 8a, 24a, 32a, 41a Primary winding, 8b, 24b, 32b, 41b Secondary winding, 9, 35 Ion generating element, 9a, 35a Discharge electrode side terminal, 9b, 35b Induction Electrode side terminal, 10 bobbin, 10a, 10b, 10c convex part, 11 core, TH high voltage side terminal, TL reference voltage side terminal, 12, 13 dielectric substrate, 14, 36 dielectric electrode, 15, 18, 37, 40 Connection terminal, 16, 19, 38, 41 Through hole, 17, 39 Discharge electrode, 20 Coating layer, 21 Dielectric part, 22 Blower fan.

Claims (6)

An ion generating element including a discharge electrode provided on a surface of the dielectric part and an induction electrode provided inside the dielectric part so as to face the discharge electrode;
A voltage application circuit for generating ions by applying an alternating voltage between the discharge electrode and the dielectric electrode;
The voltage application circuit includes a step-up transformer having a primary winding and a secondary winding electromagnetically coupled to each other in opposite polarities,
The ion generator according to claim 1, wherein a high voltage side terminal of the secondary winding is connected to the discharge electrode, and a reference voltage side terminal thereof is connected to the dielectric electrode. The step-up transformer includes a cylindrical bobbin,
The primary winding is wound from one end side to the other end side of the outer peripheral surface of the bobbin, and the secondary winding is wound from the other end side to the one end side of the outer peripheral surface of the bobbin. And
The high voltage side terminal of the primary winding is provided at the end of the primary winding, and the high voltage side terminal of the secondary winding is provided at the start of the secondary winding. The ion generator according to claim 1, wherein the ion generator is provided. First and second ion generating elements each including a discharge electrode provided on the surface of the dielectric portion and an induction electrode provided inside the dielectric portion so as to face the discharge electrode;
A voltage application circuit that generates an ion by applying an alternating voltage between the discharge electrode and the dielectric electrode of each of the first and second ion generating elements,
The voltage application circuit includes:
A first diode element having a cathode connected to the discharge electrode of the first ion generating element and an anode receiving a reference potential;
A second diode element having an anode connected to the discharge electrode of the second ion generating element and a cathode receiving the reference potential;
Each including first and second step-up transformers having primary and secondary windings electromagnetically coupled in opposite polarities to each other;
The high voltage side terminal of the secondary winding of the first step-up transformer is connected to the discharge electrode of the first ion generating element, and the reference voltage side terminal thereof is the dielectric electrode of the first ion generating element. Connected to
A high voltage side terminal of the secondary winding of the second step-up transformer is connected to the discharge electrode of the second ion generating element, and a reference voltage side terminal thereof is the dielectric electrode of the second ion generating element. It is connected to the ion generator. Each of the first and second step-up transformers includes a cylindrical bobbin,
The primary winding of each of the first and second step-up transformers is wound from one end side to the other end side of the outer peripheral surface of the bobbin, and the secondary winding is the outer peripheral surface of the bobbin. It is wound from the other end side toward the one end side,
The high voltage side terminal of the primary winding is provided at the end of the primary winding, and the high voltage side terminal of the secondary winding is provided at the start of the secondary winding. The ion generator according to claim 3, wherein the ion generator is provided. The discharge electrodes of the first and second ion generating elements are provided separately on the same surface of the same dielectric portion;
The dielectric electrode of the first and second ion generating elements is provided inside the same dielectric so as to face the discharge electrode of the first and second ion generating elements. The ion generator of Claim 3 or Claim 4. An ion generator according to any one of claims 1 to 5,
An electric device comprising: a sending means for sending ions generated by the ion generator into the air.

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