JP4521471B1 - Ion generator for air conditioning duct - Google Patents

Abstract

In an ion generating apparatus provided in an air conditioning duct, provided with an operation display lamp, the light of the operation display lamp can be easily seen from the room by a simple means.
An ion generator parent device 2 and an ion generator child device 3 are spaced apart and arranged in two upper and lower stages, and a child device case 31 has a mounting portion for an operation display lamp 29 of the ion generator parent device 2. The reflecting plate 39 was attached to the position opposite to each other.
[Selection] Figure 1

Description

  The present invention relates to an ion generator that is installed near an air outlet in an air conditioning duct and supplies ions into a room.

  In recent years, due to the pursuit of energy saving, highly airtight and highly heat-insulated houses are increasing, and the demand for air-conditioning duct devices used in the highly airtight and highly heat-insulated houses has been increasing. Conventionally, in a hotel or office building, a central air conditioning system has been introduced in which air conditioned by air conditioning equipment installed in one place is air-conditioned in each room through an air conditioning duct piped from the air conditioner to each room. In such an air conditioning duct device and an air conditioning system using an air conditioning duct, an air outlet of an air conditioning duct is provided on an indoor wall or ceiling, and air conditioned from there is introduced into the room. .

  In such a system, an ion generating device that generates negative ions, said to have an effect of relaxing mind and body, is provided in the air conditioning duct, and the negative ions are sent into a room generated from the ion generating device. The thing is proposed (refer patent document 1). In this case, if the operation state of the ion generator can be visually recognized from the room, the effect of negative ions may be visually felt. Therefore, it is conceivable to provide an operation display lamp in the ion generator.

Japanese Patent Laying-Open No. 2002-277010 (FIG. 24)

  However, since the ion generator is installed in the air conditioning duct, there is a problem that the light of the operation display lamp becomes difficult to see from the room depending on the position of the air outlet and the viewing direction.

  In view of the above problems, an object of the present invention is to make it easy to visually recognize the light of the operation display lamp from the room with a simple means in the case where the operation display lamp is provided in the ion generator installed in the air conditioning duct. .

  In order to achieve the above object, the present invention provides an ion generator for an air conditioning duct installed in the vicinity of an air outlet inside an air conditioning duct, and a flat base case having an opening in a plane, and the inside of the opening of the parent case An ion generating element that generates positive ions and negative ions from a discharge surface that is attached to the opening and that faces the opening, a driving circuit that is housed in the case and drives the ion generating element, and an operation display lamp that displays an operation state An apparatus base unit, a flat-plate type slave unit case having an opening in a plane, an ion generating element that is attached inside the opening of the slave unit case and generates positive ions and negative ions from a discharge surface facing the opening; An ion generator slave connected to the drive circuit of the ion generator master and driving the ion generator by the drive circuit; and the ion The raw device main unit and the ion generation unit slave unit are arranged opposite to each other in two upper and lower stages, and the slave unit case has a reflecting plate at a position opposite to the mounting portion of the operation display lamp of the ion generation unit main unit. Is installed.

  According to this configuration, the light of the operation display lamp of the ion generator parent device is reflected by the reflector attached to the child device case of the ion generator child device located at a different height from the ion generator parent device. It becomes like this. For this reason, it becomes easy to visually recognize the light of the operation display lamp from the room. For example, even when the air outlet of the air conditioning duct is higher than the height of the person and the ion generator main unit is installed in the lower part of the air conditioning duct, It becomes easy to see visually.

  Further, if a light shielding plate capable of shielding the light of the operation display lamp is provided in the base unit case, the light of the operation display lamp can be shielded by the light shielding plate when the light of the operation display lamp becomes an obstacle. Is possible.

  According to the present invention, the light of the operation display lamp is reflected at a height different from that of the ion generator base unit by the reflecting plate attached to the handset case. For this reason, it becomes easy to visually recognize the light of the operation display lamp from the room. For example, even when the air outlet of the air conditioning duct is higher than the height of the person and the ion generator main unit is installed in the lower part of the air conditioning duct, It can be easily visually recognized.

The perspective view which shows the ion generator for air-conditioning ducts based on one Embodiment of this invention. Schematic front view showing the installation mode in the air conditioning duct of the same ion generator Schematic side view showing the installation mode in the air conditioning duct of the same ion generator Disassembled perspective view of ion generator main unit Perspective view of the main unit Disassembled perspective view of the ion generator slave unit paired with the master unit Disassembled perspective view of extension ion generator slave unit Perspective view of the extension ion generator slave unit The perspective view of the ion generator slave unit paired with the extension ion generator slave unit The perspective view which shows 2nd Embodiment of the coupling | bonding structure of an ion generator pair. Sectional drawing which shows 2nd Embodiment of the coupling | bonding structure of an ion generator pair. The perspective view which shows 3rd Embodiment of the coupling | bonding structure of an ion generator pair. Sectional drawing which shows 3rd Embodiment of the coupling | bonding structure of an ion generator pair The perspective view which shows 4th Embodiment of the coupling | bonding structure of an ion generator pair. Sectional drawing which shows 4th Embodiment of the coupling | bonding structure of an ion generator pair The perspective view which shows the stopper used for 4th Embodiment of the coupling | bonding structure of an ion generator pair.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a perspective view showing an ion generator for an air conditioning duct according to an embodiment of the present invention, FIG. 2 is a schematic front view showing an installation mode of the ion generator in the air conditioning duct, and FIG. It is a schematic side view showing the installation mode in an air-conditioning duct. The ion generator 1 for an air conditioning duct is installed in the vicinity of an air outlet 18a in an existing air conditioning duct 18 in a hotel guest room or the like.

  As shown in FIGS. 1 to 3, an ion generator 1 for an air conditioning duct includes an ion generator parent device (hereinafter simply referred to as “parent device”) 2 and an ion generator child device connected to the parent device 2. (Hereinafter, simply referred to as a slave unit) 3, 4, a slave unit 5 connected to the slave unit 3, a slave unit 4 'connected to the slave unit 4, and a slave unit 5' connected to the slave unit 5 Consists of.

  The air-conditioning duct ion generator 1 includes four pairs of ion generators that are spaced apart and face each other in two upper and lower stages (base unit 2-slave unit 3, slave unit 4-slave unit 5, slave unit 4′-slave unit 5 ') Are arranged side by side in a direction orthogonal to the flow direction of the air conditioning duct 18. These ion generator pairs are connected by a pair of slide columns 10 and 10 whose lengths can be adjusted vertically, so that the height of the upper ion generator can be adjusted with respect to the lower ion generator. Yes.

<Master unit 2>
4 and 5 are an exploded perspective view and a perspective view of the ion generator main unit. The structure of the main | base station 2 is demonstrated based on FIG. 4, FIG. The base unit 2 accommodates a circuit board 25 having an ion generating element 24 and a drive circuit (not shown) printed on a surface thereof in a resin case 21 having a flat plate shape and a substantially rectangular shape forming an outer frame. Yes. The case 21 includes a bottomless box type upper case 22 and a plate-like lower case 23.

  A screw hole 231 is provided in the lower case 23 so as to correspond to a plurality of bosses (not shown) formed at appropriate positions inside the upper case 22. Since the lower case 23 is fixed in a state of being fitted inside the bottom edge of the upper case 22, the lower case 23 does not appear on the outside unless the base unit 1 is viewed from below. One surface of the double-sided tape R is attached to the lower surface of the lower case 23.

  A rectangular pocket 221 is formed on the upper surface side of the upper case 22. An ion generating element 24 having a shape corresponding to the cavity is attached to the pocket 221. Three hooks 221 a that engage with the upper surface of the ion generating element 24 are provided along the rear edge of the opening of the pocket 221. On the upper surface of the upper case 22, a pair of column bases 222, 222 are integrally projected at both ends in the longitudinal direction with the pocket 221 interposed therebetween. A bullet-shaped groove 222a for fitting the slide columns 10 and 10 is recessed in the column support 222.

  A reset button 26 and an operation button 27 are provided on the upper surface 22 a of the upper case 22. The reset button 26 and the operation button 27 operate a tact switch (not shown) provided at a corresponding position on the circuit board 25. By pressing and holding the reset button 26 (for example, for 3 seconds or more), the (false) operation of the ion generating element 25 can be reset and returned to the initial state. Can be turned on and off.

  Terminal windows 224 </ b> A to 224 </ b> D through which terminals for connecting the connectors are exposed are opened on the front surface 22 b of the upper case 22 (the front surface in FIGS. 4 and 5). In particular, the terminal window 224 </ b> D is a window that is located substantially at the center of the front edge of the opening of the pocket 221 and has no upper frame. The terminal window 224D is formed wide, and a hook 221b having elasticity is extended from a part of the lower frame. The hook 221 b can be inserted into the pocket 221 by being elastically deformed forward when the ion generating element 24 is mounted. If the hook 221b is elastically returned to its original position after the insertion, the hook 221a is engaged with the upper surface of the ion generating element 24, so that the ion generating element 24 can be securely fixed. The ion generating element 24 can be removed from the pocket 221 by the same operation. That is, the ion generating element 24 can be easily replaced with a new one when the life of the ion generating element 24 is deteriorated.

  In the upper case 22, a slope area 22 c having a downward slope is formed in front of the reset button 26 and the operation button 27. In the slope area 22c, a through hole 223 and a light shielding plate 227 are provided. The light shielding plate 227 is pivotally supported by a rotation shaft 227a, and can be shielded by shielding the LED 29 by covering the through hole 223 if manually rotated as necessary. For example, the light from the LED 29 may be obstructive by a person. In such a case, the light from the LED 29 may be shielded by the light shielding plate 227.

  At the lower edge of the front surface 22b of the upper case 22, a tongue piece 225 for guiding the cable that protrudes forward extends in the entire longitudinal direction. A hook-shaped hook 226 is provided at an appropriate position on the front end edge of the tongue piece 225. The hook 226 fixes a cable guided on the tongue piece 225 so as not to be twisted. By the tongue piece 225 and the hook 226, there is no possibility that the cable is cut or the connector is disconnected due to the air flow flowing through the air conditioning duct 18, and the safety of the ion generator 1 is improved.

  On the surface of the ion generating element 24, a positive ion generating unit 241 that generates a positive ion in the air by discharging by applying a positive voltage, and a negative ion that generates a negative ion in the air by discharging by applying a negative voltage. And a generating portion 242.

A positive voltage is applied to the positive ion generator 241, and water molecules in the air are electrically decomposed in the plasma region due to discharge, and mainly hydrogen ions H ⁺ are generated. Then, water molecules in the air agglomerate around the generated hydrogen ions, and stable cluster positive ions H ⁺ (H ₂ O) _m are formed.

A negative voltage is applied to the negative ion generation part 242, and oxygen molecules in the air are electrically decomposed in a plasma region due to discharge, and mainly oxygen ions O ₂ ⁻ are generated. The water molecules in the air are agglomerated around the generated oxygen ions, stable charge is negative cluster ions H ⁺ (H ₂ O) _m are formed. Here, m and n are arbitrary integers.

  In the present specification, the term “plus ion” means a positive cluster ion, and the term “minus ion” means a negative cluster ion. The generation of positive and negative cluster ions has been confirmed by time-of-flight mass spectrometry.

When positive ions and negative ions are released into the air at the same time, they aggregate on the surface of microorganisms floating in the air and surround them. And, momentarily, positive ions and negative ions combine to aggregate [• OH] (hydroxyl radical) and H ₂ O ₂ (hydrogen peroxide), which are highly oxidative species, on the surface of microorganisms. It is produced and decomposes the protein on the surface of the microorganism by chemical reaction to suppress its action. In addition, it has also been found that the hydroxyl radicals and hydrogen peroxide generated as described above have an action of decomposing odorous components in the air. Accordingly, by generating positive ions and negative ions and discharging them from the air outlet 18a of the air conditioning duct 18, it is possible to inactivate viruses floating in the room, kill bacteria and molds, or remove odors. it can.

  On one side surface in the longitudinal direction of the ion generating element 24, an input terminal 243 having a connector insertion port is provided. The input terminal 243 is located in a terminal window 224D provided in the upper case 22, and the connector insertion port faces the outside of the case 21 through the terminal window 224D. One of the connectors 61 and 61 at both ends of the cable 6 for connecting the circuit board 25 (drive circuit) and the ion generating element 24 is fitted to the output terminal 243.

  The circuit board 25 is mounted with four chip-type terminals 28 </ b> A to 28 </ b> C and an LED (operation display lamp) 29. The three terminals are one input terminal 28A and three output terminals 28B, 28C, 28D. The input terminal 28A and the output terminal 28C are located in a terminal window 224A provided in the upper case 22, the output terminal 28C is located in a terminal window 224B provided in the upper case 22, and the output terminal 28D is provided in the upper case 22. The terminal insertion port of each terminal faces the outside of the case 21 through the terminal windows 224A to 224C. A screw hole 251 is formed in the circuit board 25 so as to correspond to a plurality of bosses (not shown) formed at appropriate positions inside the upper case 22. The circuit board 25 is fixed to the lower end of a boss (not shown) of the upper case 22 by fastening with the lower case 23 using screws B.

  A connector 152 attached to the end of the output side cable 151 of the AC / DC adapter 15 is fitted to the input terminal 28A. The other of the connectors 61, 61 at both ends of the cable 6 for connecting the circuit board 25 (drive circuit) and the ion generating element 24 is fitted to the output terminal 28B. One of the connectors 71 and 71 at both ends of the cable 7 for connection with the child device 3 paired with the parent device 2 is fitted to the output terminal 28C. At the input terminal 243 of the ion generating element 24, the connector 481 at the end of the cable 48 extending from the slave unit 4 is fitted to the output terminal 28D when the slave unit 4 is added.

  The operation of base unit 2 will be described. The (DC) power input to the input terminal 28A is input to a drive circuit (not shown) formed on the circuit board 25 and the LED 29. The output of the drive circuit (not shown) is input to the ion generating element 25 via the cable 6. As a result, the ion generating element 25 is driven, and positive ions and negative ions are generated in the air according to the above principle. At the same time, the LED 29 is turned on. The operation of the ion generating element 25 is controlled by a drive circuit (not shown) based on the operation of the reset button 26 and the operation button 27.

  The output of the drive circuit (not shown) of the master unit 2 is input from the output terminals 28B and 28C to the slave units 3 and 4 via cables, and further via the slave units 3 and 4 to the slave unit 4 ′, Then, the data is inputted to 5 'and further inputted to the slaves 4' 'and 5' 'via the slaves 4' and 5 '.

<Slave unit 3 paired with base unit 2>
FIG. 6 is a perspective view of the ion generator slave unit 3 paired with the master unit 2. The structure of the subunit | mobile_unit 3 is demonstrated based on FIG. The subunit | mobile_unit 3 is an ion generator arrange | positioned facing the upper direction of the main | base station 2, as shown in FIG. 1, FIG. Therefore, it is necessary to make the longitudinal dimension of the case 31 of the child device 3 equal to that of the parent device 2. In this case, considering the mold cost, it is desirable that the cases 21 and 31 of the parent device 2 and the child device 3 be a common case that is resin-molded from the same die. However, since the slave unit 3 does not require a reset button, an operation button, or a through-hole and does not require a terminal window, it is necessary to conceal them with a protective tape T to distinguish it from the master unit 2. good. The subunit | mobile_unit 3 is opposingly arranged by aligning front-back, left-right, and the upper direction of the main | base station 2 with the attitude | position which reversed the up-down and left-right of the main | base station 2 represented by FIG.

  The subunit | mobile_unit 3 is a subordinate ion generator which drives the ion generating element 35 based on the input of the electric power from the drive circuit of the main | base station 2. FIG. Accordingly, a drive circuit is not formed on the circuit board (not shown) of the slave unit 3, and no tact switch or LED is mounted.

  The configuration of the ion generating element 34 is the same as that described above. On one side surface in the longitudinal direction of the ion generating element 34, an input terminal 343 having a connector insertion port is provided. The input terminal 343 is located in a terminal window 324D provided in the case 31 (lower case 32), and the connector insertion port faces the outside of the case 51 through the terminal window 523B.

  A chip-type input terminal 38A and output terminals 38B and 38C are mounted on a circuit board (not shown). The input terminal 38A is located in a terminal window 324A provided in the case 31, the output terminal 38B is located in a terminal window 324B provided in the case 31, and the output terminal 38C is located in a terminal window 324C provided in the case 31. The connector insertion port of each terminal faces the outside of the case 31 through the terminal windows 324A to 324C.

  A connector 571 at the end of a cable 57 extending from the circuit board 55 is fitted into the input terminal 343 of the ion generating element 34. The other of the connectors 71 and 71 at both ends of the cable 7 for connection to the parent device 2 is fitted to the input terminal 38A. The other of the connectors 81, 81 at both ends of the cable 8 for connecting the circuit board and the ion generating element 34 is fitted to the output terminal 38B. A connector 581 at the end of the cable 58 extending from the circuit board of the slave unit 5 is fitted to the output terminal 38C when the slave unit 5 is added.

  The (DC) power input to the input terminal 38A is input to the ion generating element 34. Thereby, the ion generating element 34 is driven, and positive ions and negative ions are generated in the air according to the above principle. The operation of the ion generating element 34 is collectively controlled by a drive circuit (not shown) based on the operation of the reset button 26 and the operation button 27 of the parent device 2.

  A reflection plate 39 is attached to the case 31 of the child device 3 at a position facing the LED 29 of the parent device 2 in the vertical direction so that the light from the LED 29 is reflected so that it can be easily seen from the room. Here, if the reflecting plate 39 is made of a mirror, the light of the operation display lamp can be clearly reflected. Further, if the reflecting plate 39 is made of a metal such as stainless steel, the cost can be reduced. Further, if the reflecting plate 39 is made of a convex mirror, it can be reflected in a wider range. Furthermore, if the reflecting plate 39 is movable, the reflecting plate 39 can be moved to a position where the reflectivity is optimal, so that the light from the reflecting plate 39 can be reflected efficiently.

  The operation of the slave unit 3 will be described. The electric power input via the cable 7 from the drive circuit (not shown) of the base unit 2 is input to the ion generating element 35 via the cable 8. Thereby, the ion generating element 35 is driven, and positive ions and negative ions are generated in the air according to the above principle. The operation of the ion generating element 35 is collectively controlled on the parent device 2 side by a drive circuit (not shown) based on the operation of the reset button 26 and the operation button 27 of the parent device 2.

<Extension handset 4>
5 and 6 are an exploded perspective view and a perspective view of the extension ion generator slave unit. The structure of the subunit | mobile_unit 4 is demonstrated based on FIG. 5, FIG. As shown in FIG. 1, the slave unit 4 is added to the side of the master unit 2 and is a secondary ion that drives the ion generating element 44 based on power input from a drive circuit (not shown) of the master unit 2. Generator. Therefore, a drive circuit is not formed on the circuit board 45 of the slave unit 4, and no tact switch or LED is mounted. Since neither a reset switch nor an operation switch is required, the longitudinal dimension of the case 41 of the child device 4 is set shorter than the cases of the parent device 2 and the child device 3. The slave units 4 ′ and 4 ″ have the same structure as the slave unit 4.

  The subunit | mobile_unit 4 accommodates the circuit board 45 in which the ion generating element 44 and the drive circuit (not shown) were printed on the surface in the resin-made case 41 of the flat type which makes an outer frame, and a planar shape is substantially rectangular. Yes. The case 41 includes a bottomless box type upper case 42 and a plate-like lower case 43.

  A screw hole 431 is formed in the lower case 43 so as to correspond to a plurality of bosses (not shown) formed at appropriate positions inside the upper case 22. Since the lower case 43 is fixed in a state of being fitted inside the bottom edge of the upper case 42, the lower case 43 does not appear on the outside unless the child device 4 is viewed from below. One surface of the double-sided tape R is attached to the lower surface of the lower case 43.

  A rectangular pocket 421 is formed on the upper surface side of the upper case 42. An ion generating element 44 having a shape corresponding to the cavity is attached to the pocket 421. Three hooks 421 a that engage with the upper surface of the ion generating element 44 are provided along the rear edge of the opening of the pocket 421. On the upper surface of the upper case 42, a pair of column bases 422 and 422 are integrally projected at both ends in the longitudinal direction across the pocket 421. A bullet-shaped groove 432a for fitting the slide columns 10 and 10 is recessed in the column support 422.

  Terminal windows 423A, 423B, and 423C for exposing the connector insertion ports of the terminals and through holes 424A and 424B for passing the cables are opened on the front surface 42b (the front surface in FIG. 5) of the upper case 42. . The terminal window 423B is a window that is located substantially at the center of the front edge of the opening of the pocket 221 and has no upper frame. The terminal window 423B is formed wide, and a hook 421b having elasticity is extended from a part of the lower frame. Since the terminal window 423C in FIG. 7 is unnecessary (dummy) in the slave unit 3, it is preferable to conceal it with the protective tape T as shown in FIG. The hook 421b can be inserted into the pocket 421 by being elastically deformed forward when the ion generating element 44 is mounted. If the hook 421b is elastically returned to the original position after the insertion, the ion generating element 44 can be securely fixed because the hook 421a is engaged with the upper surface of the ion generating element 24 together with the hook 421a.

  At the lower edge of the front surface 42b of the upper case 42, a cable guide tongue 425 that projects forward extends in the entire longitudinal direction. A hook-shaped hook portion 426 is provided at an appropriate position on the front end portion of the tongue piece 425. The hook 426 fixes a cable guided on the tongue piece 425 so as not to be twisted. By the tongue piece 225 and the hook 226, there is no possibility that the cable is cut or the connector is disconnected due to the air flow flowing through the air conditioning duct 18, and the safety of the ion generator 1 is improved.

  The configuration of the ion generating element 44 is the same as that described above. On one side surface in the longitudinal direction of the ion generating element 44, an input terminal 443 having a connector insertion port is provided. The input terminal 443 is located in a terminal window 423B provided in the upper case 42, and the connector insertion port faces the outside of the case 41 through the terminal window 423B.

  A chip-type output terminal 46 is mounted on the circuit board 45 and the ends of the two cables 47 and 48 are soldered. The output terminal 46 is located in a terminal window 423A provided in the upper case 42, and a connector insertion port faces the outside of the case 41 through the terminal window 423A. The cables 47 and 48 are drawn out of the case 41 through the through holes 424A and 424B provided in the upper case 42.

  A connector 471 at the end of the cable 47 extending from the circuit board 45 is fitted into the input terminal 443 of the ion generating element 44. The connector 481 at the end of the cable 48 extending from the circuit board 45 is fitted to the output terminal 28D (see FIG. 5) of the parent device 2. A connector 481 at the end of the cable 48 extending from the circuit board of the follower 4 ′ is fitted to the output terminal 46 on the circuit board 45 when the additional slave 4 ′ is added.

  The operation of the slave unit 4 will be described. Electric power input via a cable 48 from a drive circuit (not shown) of the master unit 2 is input to the ion generating element 44 via a cable 47. As a result, the ion generating element 44 is driven, and positive ions and negative ions are generated in the air according to the principle described above. The operation of the ion generating element 45 is collectively controlled on the parent device 2 side by a drive circuit (not shown) based on the operation of the reset button 26 and the operation button 27 of the parent device 2.

<Extension handset 5 paired with handset 4>
FIG. 9 is a perspective view of the ion generator slave unit 5 paired with the slave unit 4. The structure of the subunit | mobile_unit 5 is demonstrated based on FIG. As shown in FIG. 1, the slave unit 3 is an ion generator that is added to the side of the slave unit 3 that is paired with the master unit 2, and is disposed above the slave unit 4. Therefore, it is necessary to make the longitudinal dimension of the case 51 of the child device 5 equal to that of the child device 4. In this case, considering the mold cost, it is desirable that the cases 41 and 51 of the slave units 4 and 5 be a common case that is resin-molded from the same mold. The subunit | mobile_unit 5 is opposingly arranged by aligning front-back, left-right, and the upper direction of the subunit | mobile_unit 4 with the attitude | position which reversed the up-down and left-right of the subunit | mobile_unit 4 represented by FIG. The slave units 5 ′ and 5 ″ that make a pair with each of the slave units 4 ′ and 4 ″ have the same structure as the slave unit 5.

  The subunit | mobile_unit 5 is a subordinate ion generator which drives the ion generating element 54 based on the electric power input via the subunit | mobile_unit 3 from the drive circuit (not shown) of the main | base station 2. FIG. Accordingly, a drive circuit is not formed on the circuit board (not shown) of the slave unit 5, and no tact switch or LED is mounted.

  The configuration of the ion generating element 54 is the same as that described above. On one side surface in the longitudinal direction of the ion generating element 54, an input terminal 543 having a connector insertion port is provided. The input terminal 543 is positioned in a terminal window 523B provided in the case 51 (lower case 52), and the connector insertion port faces the outside of the case 51 through the terminal window 523B.

  A chip-type output terminal 56 is mounted on a circuit board (not shown), and the ends of the two cables 57 and 58 are soldered. The output terminal 56 is located in a terminal window 523A provided in the upper case 52, and a connector insertion port faces the outside of the case 51 through the terminal window 523A. The cables 57 and 58 are drawn out of the case 51 through slits 524A and 524B provided in the upper case 52. Since half of the terminal window 523C on the right side in FIG. 9 is unnecessary (dummy) in the handset 5, it is preferable to conceal it with a protective tape T as shown in FIG.

  A connector 571 at the end of a cable 57 extending from the circuit board 55 is fitted into the input terminal 543 of the ion generating element 54. A connector 581 at the end of the cable 58 extending from the circuit board 55 is fitted into the output terminal 38 </ b> C of the slave unit 3. The output terminal 56 is fitted with the connector 581 at the end of the cable 58 extending from the circuit board of the slave unit 5 ′ when the additional slave unit 5 ′ is added.

  The operation of the slave unit 5 will be described. The electric power input via the cable 58 from the drive circuit (not shown) of the parent device 2 via the child device 3 is input to the ion generating element 54 via the cable 57. Thereby, the ion generating element 54 is driven, and positive ions and negative ions are generated in the air according to the above principle. The operation of the ion generating element 54 is collectively controlled on the parent device 2 side by a drive circuit (not shown) based on the operation of the reset button 26 and the operation button 27 of the parent device 2.

<First Embodiment of Bonding Structure of Ion Generator Pair>
1st Embodiment of the coupling | bonding structure of an ion generator pair is described using FIGS. The ion generating device pair of the parent device 2 and the child device 3 and the ion generating device pair of the child device 4 (4 ′) (4 ″) and the child device 5 (5 ′) (5 ″) are a pair of slide columns 10. 10, the upper ion generator can be adjusted in height by the slide columns 10 and 10 with respect to the lower ion generator. Hereinafter, the coupling structure will be described by taking an ion generator pair of the parent device 2 and the child device 3 as an example. Since the connection structure of the slave unit 4 (4 ′) (4 ″) and the slave unit 5 (5 ′) (5 ″) is the same as that, description thereof will be omitted.

  As shown in FIG. 1, when the base unit 2 and the handset 3 are vertically opposed to each other, the column bases 222 and 322 provided in the case 21 of the base unit 2 and the case 31 of the handset 3 face each other vertically. It becomes like this. In this state, the upper end portion and the lower end portion of the slide column 10 are fitted into bullet-shaped grooves 222 a and 322 a provided on the column receiving bases 222 and 322. As a result, the master unit 2 and the slave unit 3 are combined.

  The slide column 10 includes a stator 101 that is fitted to the pair of left and right column holders 222 and 222 of the master unit 2, and a slider 102 that is fitted to the pair of left and right column holders 322 and 322 of the slave unit 3. It comprises a bolt 103 and a nut 104 for fixing the child 101 and the slider 102.

  The grooves 222a provided in the pair of left and right pillar holders 222, 222 of the base unit 2 are a bullet type facing backward on the right side and a bullet type facing forward on the left side, and have a relationship of reversing forward and backward. On the other hand, the grooves 322a provided in the pair of left and right column holders 322 and 322 of the slave unit 3 have a reverse relationship with the master unit 2, and are formed in a bullet shape with the right side facing forward and a bullet shape with the left side facing backward. .

  The groove shapes of the column base 222 of the master unit 2 and the column base 322 of the slave unit 3 are held at both the upper end (upper end fitting portion 102a) and the lower end (lower end fitting portion 101a) of the slide column 10. The shape can be. For this reason, the case shape of the main | base station 2 and the subunit | mobile_unit 3 can be made completely the same. Thereby, a metal mold | die can be made shared and the drastic cost reduction effect can be anticipated.

  The stator 101 and the slide 102 of the slide column 10 are resin molded products (pieces) having a mirror image relationship with each other. Hereinafter, the slide column 10 fitted to the column bases 222 and 322 on the right side will be described as an example. The slide column 10 fitted to the left column bases 222 and 322 is the same if the orientation is reversed back and forth, and thus the description thereof is omitted.

  The stator 101 has a shape in which a sickle-shaped portion 101b is left on the left side and the right half is hung on the front end and the upper end except for the lower end fitting portion 101a having a shape corresponding to the rearward bullet-shaped groove 222a. A vertically long slot 101c passes through the side surface of the sickle-shaped portion 101b.

  The slider 102 has a shape in which the left half is hung on the front end and the upper end while the sickle portion 102b is left on the right side except for the upper end fitting portion 102a having a shape corresponding to the forward bullet-shaped groove 322a. A round hole 102c penetrates the lower portion of the side surface of the sickle-shaped portion 102b.

  The stator 101 and the slide 102 are combined in a state in which the sickle-shaped portions 101b and 102b are slid together. Since the cross-sectional shape of the combined slide column 10 is streamlined (oval type), it is necessary to prevent the air volume from being reduced as much as possible and to prevent the air-conditioning duct from being hindered in its original cooling capacity. Can do.

  The bolt 103 is inserted into the round hole 102c and the long hole 101c, and the nut 104 is fitted to the tip. In this way, the stator 101 and the slide 102 are fastened. If the fitting between the bolt 103 and the nut 104 is loosened, the fastening of the stator 101 and the slide 102 is released, and the slide 102 slides relative to the stator 101 within a range in which the bolt 103 can move in the long hole 101c. It becomes possible. Thereby, the height position of the subunit | mobile_unit 3 can be varied within the range according to the height dimension of the air-conditioning duct 18. FIG.

<Second Embodiment of Bonding Structure of Ion Generator Pair>
A second embodiment of the ion generator pair coupling structure will be described with reference to FIGS. The slide column 11 includes a stator 111 that is fitted to the pair of left and right column holders 222 and 222 of the master unit 2, and a slider 112 that is fitted to the pair of left and right column holders 322 and 322 of the slave unit 3. It comprises a screw 113 for fixing the child 111 and the slide 112.

  The elliptical circumferential groove 222b provided in the pair of left and right pillar holders 222, 222 of the base unit 2 is an elliptical linear groove, and has a shape common to the left and right pillar holders. The elliptical grooves 322b provided in the pair of left and right column holders 322 and 322 of the slave unit 3 have the same shape as the master unit 2.

  The groove shapes of the column base 222 of the main unit 2 and the column base 322 of the slave unit 3 are held at both the upper end (upper end fitting portion 112a) and the lower end (lower end fitting portion 111a) of the slide column 11. The shape can be. For this reason, the case shape of the main | base station 2 and the subunit | mobile_unit 2 can be made completely the same. Thereby, a metal mold | die can be made shared and the drastic cost reduction effect can be anticipated.

  The stator 111 and the slide 112 of the slide column 11 are resin molded products (pieces) in a nested relationship. Hereinafter, the slide column 11 fitted to the column bases 222 and 322 on the right side will be described as an example. The slide column 11 fitted to the left column pedestals 222 and 322 is the same if the orientation is reversed back and forth, and thus the description thereof is omitted.

  The stator 111 is an elliptic cylinder that is fitted to the outer edge of the oval circumferential groove 222b, and a fitting portion 111a is formed at the lower end. A vertically long slot 111b passes through one of the side surfaces intersecting with the minor axis of the ellipse.

  The slider 112 is an oval cylinder fitted to the outer edge of the oval circumferential groove 322a, and the fitting portion 112a is formed at the upper end. A screw hole 112b passes through one lower portion of the side surface that intersects the minor axis of the ellipse.

  The stator 111 and the slide 112 are combined in a state where the outer surface of the slide 112 is slid onto the inner surface of the cavity of the stator 111. Since the cross-sectional outer shape of the combined slide pillars 11 is streamlined (elliptical), consideration is given to prevent the air volume from being lowered as much as possible and not to hinder the cooling capacity, which is the original purpose of the air conditioning duct 18. be able to.

  The screw 113 is inserted into the long hole 111b and then screwed into the screw hole 112b. In this way, the stator 111 and the slide 112 are fastened. When the screw 113 is removed from the screw hole 112b, the fastening of the stator 111 and the slide 112 is released, and the slide 112 can slide with respect to the stator 111 within a range in which the screw 113 can move in the long hole 111b. . Thereby, the height position of the subunit | mobile_unit 3 can be varied within the range according to the height dimension of the air-conditioning duct 18. FIG.

<Third embodiment of coupling structure of ion generator pair>
A third embodiment of a coupling structure of an ion generator pair will be described with reference to FIGS. The slide column 12 includes a stator 121 fitted to the pair of left and right column holders 222, 222 of the master unit 2, and a slider 122 fitted to the pair of left and right column holders 322, 322 of the slave unit 3. It comprises a screw 123 for fixing the child 121 and the slide 122.

  The elliptical grooves 222c provided in the pair of left and right column bases 222, 222 of the base unit 2 have a shape common to the left and right column bases. The elliptical grooves 322c provided in the pair of left and right column holders 322 and 322 of the slave unit 3 have the same shape as the master unit 2.

  The groove shapes of the column base 222 of the master unit 2 and the column base 322 of the slave unit 3 are held at both the upper end (upper end fitting portion 122a) and the lower end (lower end fitting portion 121a) of the slide column 12. The shape can be. For this reason, the case shape of the main | base station 2 and the subunit | mobile_unit 2 can be made completely the same. Thereby, a metal mold | die can be made shared and the drastic cost reduction effect can be anticipated.

  The stator 121 and the slide 122 of the slide column 12 are resin molded products (pieces) in a nested relationship. Hereinafter, the slide column 12 fitted to the column bases 222 and 322 on the right side will be described as an example. The slide column 12 fitted to the left column pedestals 222 and 322 is the same if the orientation is reversed back and forth, and thus the description thereof is omitted.

  The stator 121 is an elliptic cylinder fitted into the elliptical groove 222c, and a fitting part 121a is formed at the lower end. A vertically long slot 121b passes through one of the side surfaces intersecting with the minor axis of the ellipse.

  The slider 122 is an elliptic cylinder having a two-stage structure with different diameters that is fitted into the elliptical groove 322c, and a large-diameter fitting part 122a is formed at the upper end. A screw hole 122b passes through one lower portion of the side surface that intersects the minor axis of the ellipse of the slider 122.

  The stator 121 and the slide 122 are combined in a state where the outer surface of the slide 122 is slid onto the inner surface of the cavity of the stator 121. Since the outer shape of the cross section of the combined slide column 12 is streamlined (elliptical), consideration is given to prevent a reduction in the air volume as much as possible and not to hinder the cooling capacity, which is the original purpose of the air conditioning duct 18. be able to.

  The screw 114 is inserted into the long hole 121b and then screwed into the screw hole 122b. In this way, the stator 121 and the slide 122 are fastened. When the screw 114 is removed from the screw hole 112b, the fastening of the stator 121 and the slide 122 is released, and the slide 122 can be slid with respect to the stator 121 within a range in which the screw 114 can move in the long hole 121b. . Thereby, the height position of the subunit | mobile_unit 3 can be varied within the range according to the height dimension of the air-conditioning duct 18. FIG.

<Fourth Embodiment of Bonding Structure of Ion Generator Pair>
4th Embodiment of the coupling | bonding structure of an ion generator pair is described based on FIGS. The slide column 13 includes a stator 131 fitted to the pair of left and right column bases 222 and 222 of the base unit 2, and a slide 132 fitted to the pair of left and right column bases 322 and 322 of the handset 3. A stopper 133 and a leaf spring 134 for fixing the child 131 and the slider 132, and a compression spring 135 for urging the slider 132 upward.

  Grooves 222d provided in the pair of left and right pillar holders 222, 222 of the base unit 2 are oval-shaped moats surrounding the C-shaped foundation, and the grooves are symmetrical with each other in the left and right pillar holders 222, 222. There is. Grooves 322d provided in the pair of left and right column holders 322 and 322 of the slave unit 3 have the same shape as the master unit 2.

  The groove shapes of the column base 222 of the main unit 2 and the column base 322 of the slave unit 3 are held at both the upper end (upper end fitting portion 132a) and the lower end (lower end fitting portion 131a) of the slide column 10. The shape can be. For this reason, the case shape of the main | base station 2 and the subunit | mobile_unit 2 can be made completely the same. Thereby, a metal mold | die can be made shared and the drastic cost reduction effect can be anticipated.

  The stator 131 and the slide 132 of the slide column 13 are resin molded products (pieces) in a nested relationship. Hereinafter, the slide column 13 fitted to the column bases 222 and 322 on the right side will be described as an example. The slide column 13 fitted to the left column pedestals 222 and 322 is the same if the orientation is reversed back and forth, and thus the description thereof is omitted.

  The stator 131 is an elliptic cylinder that is fitted to the outer edge of the groove 222d, and a fitting portion 131a is formed at the lower end. A vertically long slit 131b passes through one upper end of the side surface that intersects the minor axis of the ellipse.

  The slider 132 is a substantially oval cylinder fitted to the inner edge of the groove 322a, the upper end portion is formed with a fitting portion 132a fitted to the inner edge of the groove 322a, and the lower end portion is pressed against the compression spring 135. A portion 132b is formed. A recess 132d extending in the vertical direction and recessed in a rectangle is formed on one of the side surfaces intersecting with the minor axis of the ellipse, and the cross section of the slider 132 is substantially C-shaped. A longitudinally long slot 132c passes through both sides of the ellipse that intersect the minor axis, and enters the recess 132d.

  The stator 131 and the slide 132 are combined in a state where the outer surface of the slide 132 is slid onto the inner surface of the cavity of the stator 131. Since the outer shape of the cross section of the combined slide column 13 is streamlined (elliptical), it is possible to prevent a reduction in the air volume as much as possible and not to hinder the cooling capacity and the like that is the original purpose of the air conditioning duct 18. Can do.

  The stopper 133 is a rivet having a locking portion 133a at the tip. The locking portion 133a has an elliptic cylinder shape having a short diameter that is about the same as the width of the slit 131b and the long hole 132b and a long diameter larger than the width. The stopper 133 is inserted through the slit 131b and the long hole 132c, and is then twisted by approximately 90 ° so as not to come out of the long hole 132c. Then, the end surface of the locking portion 133a is pushed by the elastic piece of the leaf spring 134, and the locking portion 133a is pressed against the wall surface around the long hole 132c on the opposite surface. As a result, the stopper 133 is locked, and the slider 132 is fixed to the fixing stop 131.

  The leaf spring 134 has a hairpin shape and is hooked on the upper end of the fixing stop 131. The elastic piece of the leaf spring 134 is positioned in the recess 132 d of the slide 132 and urges the slide 132 to the left via the stopper 133.

  The compression spring 135 is dropped into the cavity of the stator 131 in a state where the stator 131 is fitted to the column base 222. The compression spring 135 is positioned between the column base 222 and the slide 132 and urges the slide 132 upward.

  As shown in FIG. 15A, when the stopper 133 is pushed with a finger against the urging of the leaf spring 134, the stopper 133 is unlocked, and the slide 132 has the stopper 133 in the elongated hole 132c. It can slide with respect to the stator 131 within a movable range. At the same time, as shown in FIG. 15B, the slide 132 is urged upward by the compression spring 135, and the length of the slide column 13 is automatically extended. When the finger is released from the stopper 133, the force of the leaf spring 134 works and the slide 132 becomes non-slidable again. Thereby, according to the height dimension of the air-conditioning duct 18, the height position of the subunit | mobile_unit 3 can be varied within the range. In the present embodiment, there is a convenience that this is possible with one push of the stopper 133.

<Installation in the air conditioning duct>
The ion generating apparatus 1 for an air conditioning duct completes the assembly of each ion generating device pair and the wiring between the ion generating device pairs in advance before being carried into the air conditioning duct 18. The length of the slide column that connects between the ion generator pairs is the shortest.

  And the diffuser 19 attached to the blower outlet 18a of the air-conditioning duct 18 is removed, and the main | base station 2-subunit | mobile_unit 3, the subunit | mobile_unit 4-subunit | mobile_unit 5, the subunit | mobile_unit 4 '-subunit | mobile_unit 5', the subunit | mobile_unit 4 from the outlet 18a. Four ion generating device pairs of “-slave 5” are carried into the air conditioning duct 18 and arranged side by side in a direction orthogonal to the flow direction. The number of ion generator pairs is an example, and the number of pairs is adjusted by the lateral width of the air conditioning duct 18.

  At this time, the ion generators 2, 4, 4 ′, 4 ″ in the lower stage peel off the film on the lower surface of the double-sided tape R attached to the bottom surface of the case, and the air conditioning duct 18 with a constant interval between the ion generator pairs. Adhere to the inner surface of the lower wall. The upper ion generators 3, 5, 5 ′, and 5 ″ are in a state where the length of the slide column is extended in accordance with the height dimension of the air conditioning duct 18 and the upper surface of the case is pressed against the inner surface of the upper wall of the air conditioning duct 18. Fixed. When the diffuser 19 is attached to the blower outlet 18a, positioning can be performed by causing the tongue piece protruding toward the front side of the master unit case and the slave unit case to abut the rear end of the diffuser 19.

  As described above, the ion generating apparatus 1 for an air conditioning duct is divided into the master unit 2 having a drive circuit and the slave units 3, 4, 4 ', 5, 5' having no drive circuit, and the degree of freedom in arrangement is improved. I am trying. Therefore, the ion generator can be carried in from the outlet of the air conditioning duct 18 and can be easily installed in the existing air conditioning duct. Further, a desired ion generation amount can be ensured without increasing the number of AC power sources. Furthermore, even when the interior is important, such as in a hotel room, the ion generator is not visible from the room, and the aesthetics are not impaired.

  When the ion generating apparatus 1 for an air conditioning duct installed as described above is operated, the light of the LED 29 is reflected at a height different from that of the main unit 2 by the reflection plate 39 attached to the case of the sub unit 3 along with the generation of ions. The For this reason, it becomes easy to visually recognize the light of the LED 29 from the room. For example, even when the air outlet 18a of the air conditioning duct 18 is at a position higher than the height of the person and the master unit 2 is installed below the air conditioning duct 18, the operation state of the ion generator 1 for the air conditioning duct is changed. It can be easily confirmed from the room.

  As mentioned above, although embodiment of this invention was described, it cannot be overemphasized that the technical idea of this invention is not limited to said embodiment.

  The present invention can be used for an ion generator installed in an air conditioning duct.

DESCRIPTION OF SYMBOLS 1 Ion generator for air-conditioning ducts 2 Ion generator parent machine 21 Parent machine case 3, 4, 4 ', 4 ", 5, 5', 5" Ion generator child machine 31 Ion generator child machine 3 child Machine case 41 Ion generator slave unit case of slave unit 4, 4 ', 4 "51 Ion generator slave unit case of slave unit 5, 5', 5" 222, 322, 422, 522 Holding part)
225, 325, 425, 525 tongue 226, 326, 426, 526 hook 222a, 322a, 422a, 522a groove (column holding part)
222b, 222c, 222d Other embodiment of groove (holding portion)
28A, 38A, 46 Input terminal 28B, 28C, 28D, 38B, 38C, 56 Output terminal 24, 34, 44, 54 Ion generating element 243, 343, 443, 543 Input terminal 29 LED (operation display lamp)
39 Reflecting plate 227 Shielding plate 6, 7, 8, 47, 48, 57, 58 Cable 61, 71, 81, 471, 481, 571, 581 Connector 10 Slide column 11, 12, 13 Other embodiment of slide column

Claims (2)

In the ion generator for air conditioning ducts installed near the air outlet inside the air conditioning duct,
A flat-type base unit case having an opening in a plane, a base unit ion generating element attached inside the opening of the base unit case and generating positive ions and negative ions from a discharge surface facing the opening, accommodated in the case A driving circuit for driving the ion generating element, an ion generating device main unit having an operation display lamp for displaying an operation state;
A flat-type slave unit case having an opening in a plane, a slave unit ion generating element that is attached to the inside of the opening of the slave unit case and generates positive ions and negative ions from a discharge surface facing the opening. An ion generator slave connected to the drive circuit of the device master and driving the slave ion generating element by the drive circuit;
The ion generator master unit and the ion generator slave unit are arranged opposite to each other in two upper and lower stages, and the slave unit case is disposed at a position opposite to the mounting portion of the operation display lamp of the ion generator master unit. An ion generator for an air conditioning duct, wherein a reflector is attached.   The ion generator for an air-conditioning duct according to claim 1, wherein a light shielding plate capable of shielding light from the operation display lamp is provided in the base unit case.

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