JP4778289B2 - Static eliminator - Google Patents

Description

The present invention relates to a static eliminator .

2. Description of the Related Art Conventionally, there has been provided a static eliminator that neutralizes an object to be neutralized by spraying ions on the object to be neutralized (Patent Document 1).
This is provided with an ion generator having a discharge electrode and a blower in a housing provided with a blowout duct, and ionized air generated by applying a high voltage to the discharge electrode is sent out from the blowout duct by the blower. It is what I did.
Japanese Patent Laid-Open No. 2002-151293 (page 5-7, FIG. 1)

In the above structure, both the ion generator and the blower are housed in the housing, and these cannot be easily removed. For this reason, when either the ion generation unit or the blower fails, it is necessary to replace the entire static elimination device with a new one, and there is room for improvement in this respect.
The present invention was completed based on the above situation, and an object thereof is to provide a divided electrical location that can be replaced in units.

As means for achieving the above object, the invention of claim 1 is directed to an ion generator for generating ions by external power feeding, and an ion emission port for discharging ions generated by the ion generator to the outside. An ion generation unit comprising: a blower unit having a predetermined ventilation mode, wherein the ion generation unit discharges ions to the outside based on the predetermined ventilation mode, and the blower unit Is detachable from the ion generation unit, the ion generation unit includes an ion generation circuit for generating the ions, and the blower unit includes an electric circuit, and the ion generation unit or the One of the blower units has a power supply line that supplies power to the circuit from the power supply, and the power supply line On the other hand, the other unit is provided with a power receiving terminal. When the power feeding terminal and the power receiving terminal are energized, power is supplied from the one unit to the circuit of the other unit. The ion generating unit and the air blowing unit are characterized in that the combination of both units is combined in different numbers .

According to a second aspect of the present invention, there is provided an ion generation unit including an ion generation unit that generates ions by power supply from the outside, and an ion emission port for discharging ions generated by the ion generation unit to the outside. A blower unit having a blower mode, wherein the ion generation unit discharges ions to the outside based on the predetermined blower mode, and the blower unit is detachable from the ion generation unit And the ion generation unit includes an ion generation circuit for generating the ions, the air blowing unit includes an electric circuit, and one of the ion generation unit and the air blowing unit includes: A power supply line for supplying power to the circuit from the power supply and a power supply terminal connected to the power supply line are provided on the other side The unit power receiving terminal is provided,
When the power feeding terminal and the power receiving terminal are energized, electric power is supplied from the one unit to the circuit of the other unit, and the air blowing unit includes a plurality of types of air blowing units. The unit is characterized in that the shape of the attachment portion with respect to the ion generation unit is the same shape and can be selectively attached to the ion generation unit .

The invention of claim 3 is characterized in that , in the invention of claim 2 , the plurality of types of blower units include blower units having different blow modes.

According to a fourth aspect of the present invention, in the third aspect , the air blowing unit is provided with an air outlet hole facing the air discharge port, and the air taken in from the outside passes through the air outlet hole. The amount of air discharged to the outside from the ion discharge port by differentiating the shape of the air lead-out hole in the plurality of types of blower units in what is sent to the ion discharge port, Or it has the characteristics in the place where the ventilation unit from which discharge | release area mutually differs is included.

According to a fifth aspect of the present invention, the size of the opening of the ion emission port according to the third or fourth aspect of the invention is such that the size of the air outlet hole in at least one of the plurality of types of blower units. It is characterized by being formed larger than the opening.

A sixth aspect of the present invention is the method according to any one of the second to fifth aspects, wherein the ion generation unit includes units having different ion generation methods, and these ion generation methods are different from each other. The ion generating unit is characterized in that the shape of the attachment portion with respect to the air blowing unit is the same, and any ion generating unit can be attached to the air blowing unit.

A seventh aspect of the invention is characterized in that, in the third aspect of the invention, the air blowing mode includes a non-air blowing mode.

<Invention of Claims 1 and 2 >
According to the first and second aspects of the present invention, since each unit can be replaced, if any unit fails and becomes unusable, only the failed unit needs to be replaced. With such a configuration, it is possible to reduce the replacement cost compared to a configuration in which the entire apparatus is forced to be replaced when a failure occurs in any unit. There is also an advantage that the ion generating unit can be used alone.

According to the first and second aspects of the present invention, when the power feeding terminal and the power receiving terminal are energized, power is supplied from the unit on one side to the circuit on the other unit. With such a configuration, it is not necessary to provide a dedicated power cable for each of both units.

Further , according to the invention of claim 1 , the units can be attached in different numbers. Such a configuration is effective when the number of combinations is increased and ions are sprayed over a wide range as compared with the case where only one unit is attached. In addition, if a part of the unit fails, it is only necessary to replace it, so the replacement cost is low.

Further , according to the invention of claim 2 , since various blower units can be selected according to the intended use, the merchantability is excellent.

<Invention of Claim 3 >
For example, a fan-driven type or a type in which compressed air is ejected from a nozzle is suitable as a blower mode. However, a fan-driven type is suitable for applications in which ions are widely blown out, and jets compressed air. Each thing has different characteristics, such as being suitable for spraying ions intensively at a specific location or for delivering ions far away. According to the invention of claim 8, since the above-described features of the air blowing modes that are different from each other can be selectively used, variations in usage are increased, and the merchantability is further enhanced.

<Invention of Claim 4 >
According to the invention of claim 4 , the plurality of types of air blowing units include those in which the shapes of the air outlet holes are different from each other. With such a configuration, the air discharge amount or the discharge area can be selected according to the intended use, so that the merchantability is enhanced.

<Invention of Claim 5 >
According to the invention of claim 5 , the opening area of the ion emission port provided in the ion generation unit is naturally a certain area. If the opening area of the ion discharge port is set to be small according to the type that sends compressed air (the opening of the air outlet hole is small), the fan blower type that has a relatively large opening area of the air outlet hole When an object is selected, it cannot be used, but as described above, if there is a certain amount of opening area, both types of blower units can be used together with a single ion generating unit without hindrance.

<Invention of Claims 6 and 7 >
If it is invention of Claim 6 and Claim 7 , since a variation will increase further in the combination of an ion generation unit and a ventilation unit, commerciality will increase further.

<Embodiment 1>
A first embodiment of the present invention will be described with reference to FIGS.
The code | symbol 20 shown in FIG. 1 is an ion generating unit, and the code | symbol 40 is a ventilation unit. In the following description, the front-rear direction will be described with the left front side in FIG. 1 as the front side and the right back side as the rear side.

The ion generation unit 20 includes four discharge needles 25 and a circuit board (not shown) in a horizontally elongated casing 21 that extends in the left-right direction. The casing 21 is provided with four through-holes 22 penetrating forward and backward through the casing 21 at substantially equal intervals from the left end shown in FIG. The circuit board is accommodated. Each through hole 22 has a horizontally long shape, and a discharge needle 25 protrudes laterally from the right inner wall of each through hole 22. Moreover, the exit part of these through-holes 22, ie, opening of casing front wall 21A, is made into ion discharge port 22A.
In addition, the housing | casing 21, the discharge needle 25, and the high voltage generation circuit 35 mentioned later correspond to the ion generation part of this invention.

  The rear wall 21B of the casing 21 has a flat planar shape, and a plurality of types of blower units 40 described below can be selectively attached thereto.

  The blower unit 40 is fed from a fan unit 50 having a built-in fan 53, an air jet unit 70 that takes in compressed air sent from a compressor (not shown) through the flow pipe R and discharges it from the tip of the nozzle 72, and air conditioning equipment. There are three types (ie, three types of blowing units) that send out air taken from the outside to the ion generation unit 20 such as a rectifying unit 90 that rectifies the air to be guided to each through hole 22. Is provided.

  The units 50, 70, 90 will be further described. The fan unit 50 is a so-called cross flow fan, and includes a casing 51 having a shape that follows the casing 21 of the ion generation unit 20, that is, a horizontally long casing 51 that extends to the left and right. . In the casing 51, a cylindrical fan (rotating body) 53 for air blowing is supported sideways, and is driven to rotate by receiving power from a motor 55. Further, four air outlet holes 52 are provided in the front wall 51A of the casing 51 of the fan unit 50 at a position facing the through hole 22 of the ion generation unit 20.

  As with the fan unit 50, the air ejection unit 70 includes a casing 71 having a shape that follows the casing 21 of the ion generation unit 20, that is, a horizontally long casing 71 that extends to the left and right. A flow pipe R is connected to the right side surface of the casing 71, and the other end of the flow pipe R is connected to a compressor (not shown). Further, four nozzles 72 are provided on the front wall of the casing 71 so as to protrude forward. From these four nozzles 72, compressed air delivered from the compressor is ejected.

  The rectifying unit 90 includes four duct portions 92 arranged on the left and right sides, and as a whole, has a shape that follows the casing 21 of the ion generation unit 20, that is, a horizontally long shape that extends to the left and right. Since the rectifying unit 90 is not mounted with electrical components, the total length is shorter than that of the fan unit 50 and the air ejection unit 70. Note that an example of use of the rectifying unit 90 (an example of rectifying the air flow of the air conditioning equipment and blowing it to the ion generation unit) will be described in detail in a later use example.

  The front walls 51A, 71A, 91A of the fan unit 50, the air ejection unit 70, and the rectifying unit 90 are all flat planar shapes (here, they are planar shapes, but the shapes are not limited thereto). This is a mounting surface for mounting the ion generating unit 20.

  Next, the mounting structure of the ion generation unit 20 and the blower unit (fan unit, air ejection unit, rectification unit) 40 will be described in detail. A screw insertion hole 31 (31a) is formed in the casing 21 of the ion generation unit 20. To 31f) are provided, specifically, at the four corners of the casing 21 and above and below the center in the width direction and slightly to the right (on the left side of the circuit housing portion 23). On the other hand, on the front walls 51A and 71A of the casings 51 and 71 of the fan unit 50 and the air ejection unit 70, screw holes 41 (41a to 41a to 41a to 41a) are respectively provided at positions facing the screw insertion holes 31 (31a to 31f) of the ion generation unit 20. 41f) is formed.

As a result, while either one of the fan unit 50 or the air ejection unit 70 is addressed to the rear surface wall 21B of the ion generation unit 20, 6 points of screw tightening are performed from that state. Either 50 or the air ejection unit 70 can be fixed. And, for example, when the fan unit 50 is mounted on the ion generation unit 20, in order to replace it with the air ejection unit 70, the screws 20 are unscrewed to separate the units 20, 50, and then Once again, the air ejection unit 70 may be screwed while facing the ion generation unit 20.
In addition, the peripheral part (where the screw insertion hole 31 is provided) of the rear wall 21B of the casing 21 corresponds to the attachment part of the present invention ( Claim 6 ), and the front walls 51A, 71A, The peripheral edge portion 91A (where the screw hole 41 is provided) corresponds to the attachment portion of the present invention ( Claim 2 ).

  Screw holes 41a to 41d are formed at the four corners of the front wall 91A of the rectifying unit 90 at positions facing the screw insertion holes 31a to 31d of the ion generation unit 20, respectively. Therefore, the rectifying unit 90 can be attached to the ion generation unit 20 in place of the fan unit 50 and the air ejection unit 70 by screwing in the manner described above.

  In FIG. 2, the opening width of the through hole 22 (the width of the ion emission port 22 </ b> A) and the opening width of the air outlet hole 52 of each blower unit 40 are compared. Reference numeral 71 denotes a casing 71 of the air ejection unit 70, reference numeral 51 denotes the casing 51 of the fan unit 50, and reference numeral 21 denotes the casing 21 of the ion generation unit 20.

  As shown in the figure, in this embodiment, the opening width of the through hole 22 formed in the ion generation unit 20 is set to be large in advance. Specifically, the F dimension in the figure is larger than the G dimension and the H dimension. If the opening width of the through hole 22 is set to be small in accordance with the size of the air outlet hole of the nozzle 72 of the air ejection unit 70, the air flow is reduced when the fan unit 50 is attached to the ion generation unit 20. However, as described above, if the opening width of the through hole 22 is set large in advance, either the fan unit 50 or the air ejection unit 70 is attached to the ion generation unit 20. Can be used without any trouble.

  The above configuration corresponds to “the size of the opening of the ion emission port is larger than the opening of the air outlet hole in at least one of the plurality of types of blowing units” of the present invention. It is the structure to do.

  3 is an enlarged view of the portion A in FIG. 2. The discharge needle 25 includes a seat portion 26 on the proximal end side. The outer wall of the seat portion 26 is provided with a protruding edge 26A that protrudes laterally. On the other hand, the housing 21 is provided with a housing recess 24 for housing the seat 26, and both upper and lower wall surfaces thereof are provided with fitting grooves 24A for fitting the protruding edges 26A without any gaps. The discharge needle 25 is fixed to the housing 21 by fitting the seat 26 in the housing recess 24 while fitting the projecting edge 26A into the fitting groove 24A. On the contrary, the projecting edge 26A and the fitting groove Each discharge needle 25 can be removed singly by releasing the fitting by 24A and removing the seat portion 26 from the housing recess 24.

  FIG. 4 is a block diagram showing the electrical configuration of the ion generation unit 20 and the fan unit 50, and FIG. 6 is a cross-sectional view of the ion generation unit and the fan unit. The ion generation unit 20 is supplied with power through the power supply line L1 connected to the power supply and the power supply line L1, and a high voltage generation circuit (corresponding to the ion generation circuit of the present invention) 35 that alternately generates positive and negative high voltages. Is provided. Four discharge needles 25 are connected to the output terminal of the high voltage generation circuit 35 through a common output line L2. When a high voltage is generated by the high voltage generation circuit 35 and applied to each discharge needle 25, Corona occurs in each discharge needle 25 and ions are generated. That is, a positive high voltage is applied from the high voltage generation circuit 35 to the discharge needle 25 to generate positive ions, and a negative high voltage is applied to generate negative ions. .

  The fan unit 50 is provided with a drive circuit (corresponding to the electric circuit of the present invention) 65 for driving the motor 55. The fan unit 50 is provided with a power receiving terminal 66 connected to the drive circuit 65. On the other hand, the previous ion generation unit 20 is provided with a power supply terminal 36, and the power reception terminal 66 and the power supply terminal 36 can be electrically connected. Thus, when both terminals 36 and 66 are energized, power is supplied from the power supply to the drive circuit 65 of the fan unit 50 through the power supply line L1 of the ion generation unit 20. With such a configuration, it is not necessary to provide the fan unit 50 with a dedicated power cable.

  When the fan 53 is driven, air is taken into the casing 51, that is, the fan chamber, from the air intake 56 provided on the rear surface of the casing 51, and the taken-in air is led out to the air on the front wall 51A. It is sent to the through hole 22 of the ion generation unit 20 through the hole 52 (see FIG. 5). Thereby, the ion produced | generated by the discharge needle 25 protruded in the through-hole 22 will be sent out below illustration from 22 A of ion discharge ports with the sent-out air. The fan unit 50 is suitable for an application that emits ions over a relatively wide range.

  The power receiving terminal 66 and the power feeding terminal 36 may be provided anywhere in the casings 21 and 51 as long as they can be electrically connected. In this embodiment, however, the power feeding terminal 36 generates ions. While being provided on the rear wall 21B of the unit 20, the power supply terminal 36 is provided on the front wall 51A of the fan unit 50, and the both terminals 36 and 66 are arranged to face each other. Thereby, when both units 20 and 50 are fixed by screwing, both terminals 36 and 66 are naturally electrically connected.

  FIG. 6 is a block diagram showing an electrical configuration of the ion generation unit 20 and the air ejection unit 70. Since the electrical configuration of the ion generation unit 20 is the same as in the case of FIG. The air ejection unit 70 includes an indicator lamp 81 and a drive electric circuit 85 that turns on the indicator lamp 81. The electric circuit 85 is connected to a power receiving terminal 86. When the power feeding terminal 36 of the ion generating unit 20 is electrically connected to the power receiving terminal 86, the electric circuit 85 is connected to the power source through the power line L 1 of the ion generating unit 20. Power is supplied. The indicator lamp 81 is lit when the ion generation unit 20 and the air ejection unit 70 are correctly connected.

  In addition, the fan unit 50 is suitable for a case where ions are sprayed over a wide range as an application, but the air ejection unit is suitable for spraying ions intensively at a specific location or for delivering ions to a distant place. Yes.

  Thus, according to the present embodiment, the ion generation unit 20 and the air blowing unit 40 are fixed by screws and can be easily removed, so when any unit fails and becomes unusable. Only the failed unit needs to be replaced.

  With such a configuration, it is possible to reduce the replacement cost as compared with a configuration in which replacement of the entire apparatus is forced when a failure occurs in any unit. Moreover, if it is the said structure, there also exists an advantage that the ion generation unit 20 can be used alone. In addition, since the air blowing units 40 having different air blowing features can be selectively attached, it is possible to cope with various usages and excellent in merchantability.

<Usage example>
A usage example of the rectifying unit 90 and a rectifying action will be described with reference to FIGS. In this use example, a neutralization device comprising an ion generation unit 20 and a rectification unit 90 is arranged vertically below an air conditioning facility, and ions are used as an object to be neutralized using a downflow that is sent downward from the air conditioning facility. It sprays on (refer FIG. 7).

8 is a cross-sectional view taken along line BB in FIG. 7, and FIG. 9 is a cross-sectional view taken along line CC in FIG.
As shown in both figures, the internal space of the rectifying unit 90 is partitioned into four duct portions 92 that are respectively continuous with the through holes 22 of the ion generation unit 20, but the partition walls 95 that partition these duct portions 82, and the peripheral wall The upper end portion of 91 has a streamline shape, that is, a shape in which the plate width gradually increases from above to below (air flow direction).

  As shown in FIG. 10, if the rectifying unit 90 is not provided and the downflow sent from the air conditioning equipment is directly taken into the ion generation unit 20, the upper end portion (D portion in FIG. 10) of the ion generation unit 20. Part of the downflow is blown directly and turbulence occurs. However, if the rectifying unit 90 having the above-described configuration is provided, the downflow can be smoothly guided into the duct portion 92 and thus into the through hole 22 of the ion generation unit 20 connected thereto, thereby suppressing the occurrence of turbulence. (Rectifying action). Further, in this case, in order to enhance the rectification effect, the opening width of the duct portion 92 and the opening width of the through hole 22 are made equal to each other so that there is no step at the mating portion where both the portions 22 and 92 face each other. Considered.

<Embodiment 2>
Next, Embodiment 2 will be described with reference to FIGS.
The rectifying unit 90 in the first embodiment includes four duct portions 92 that penetrate therethrough, and the upper ends of the partition walls 95 and the like that define the duct portions 92 are streamlined. However, the rectifying unit 97 in the second embodiment has an outer shape itself. Is a streamline shape, and air is not blown directly into the ion emission port 22A of the ion generation unit 20 in a non-air blowing mode. FIG. 12 shows a cross-sectional view of the state in which the rectifying unit 97 is mounted on the ion generation unit 20. As shown in the figure, the downflow from the air conditioning equipment is rectified by the outer wall portion of the rectifying unit 97, and a curtain made of air is formed around the ion generating unit 20. As a result, ions generated by applying a high voltage to the discharge needle 25 are sprayed on the object to be discharged without spreading around. The rectifying unit 97 has a hollow shape in order to reduce the weight of the rectifying unit 97.

<Embodiment 3>
Next, Embodiment 3 (corresponding to claim 4 ) will be described with reference to FIG.
The third embodiment is an example in which the fan unit 50 is provided with three types having different opening shapes of the air outlet holes 52. Reference numeral 51 denotes a casing of the fan unit 50, and the width (E dimension) of the air outlet hole 52 is increased in order from the top. As described above, if a plurality of types of fan units 50 having different shapes of the air outlet holes 52 are provided in advance, and these units are selectively attached to the ion generation unit 20 according to the application, the feed sent from the fan 53 is performed. The air volume, the blowing width, etc. can be changed according to the application, and the merchantability is enhanced.

<Embodiment 4>
A fourth embodiment will be described with reference to FIGS.
The thing of this embodiment is a thing of the structure which covers the whole rear surface wall 21B of the ion generation unit 20 with the coating | coated board 100. FIG. The cover plate 100 has a flat plate shape and is provided with screw holes 41 a to 41 d at four corners, and is attached to the ion generation unit 20 by screwing the four corners similarly to the rectifying unit 90. In this embodiment, ions are released from the ion discharge port 22A using repulsive force between ions, regardless of external air blowing, and the rear wall 21B of the ion generation unit 20 is blocked by the covering plate 100. The electrical repulsion between ions can be enhanced, and ions can be prevented from being released from the opening opposite to the ion emission port 22A.

<Embodiment 5>
A fifth embodiment will be described with reference to FIGS. 16 to 18.
The fifth embodiment is an example in which an ion generation unit 130 and a fan unit 140 are added to the configuration of FIG. 4 described in the first embodiment.

First, although it is an ion generating unit, the added left unit is a subunit 130 that does not have a high voltage generating circuit. The subunit 130 has a high voltage lead-in line L3, and four discharge needles 25 are connected to the high voltage lead-in line L3. Further, connector 1 31 is provided at the distal end of the high voltage lead line L3.

On the other hand, the right side of the ion generating unit with high voltage generating circuit 35 (hereinafter, referred to as the main unit) to the end of the output line L2 of 110, the mating connector 1 11 is provided for the connector 131 provided in the sub-unit 130 ing. Therefore, when these connectors 111 and 131 are fitted to each other, the output line L2 of the main unit 110 and the high voltage lead-in line L3 of the subunit 130 are energized, and the main unit 110 is connected to each discharge needle 25 of the subunit 130. The high voltage generated in the high voltage generation circuit 35 is applied. With such a configuration, it is not necessary to provide a dedicated high voltage generation circuit 35 in the subunit 130, so that the circuit configuration of the subunit 130 becomes extremely simple.

  On the other hand, although it is a fan unit, the circuit configuration of the added left unit 140 is basically the same as the circuit configuration of the right unit 120 and is provided with a dedicated drive circuit 65. Then, power is supplied from the power source to the added fan unit 140 via the power relay line L4 provided in the right fan unit 120.

  FIG. 17 is an enlarged view showing a state before fitting both connectors 111 and 131 (G portion enlarged portion in FIG. 16), and FIG. 18 is an enlarged view showing a state where both connectors 111 and 131 are fitted. is there. As shown in both figures, the connectors 111 and 131 are disposed opposite to each other on the left side surface 110A of the main unit 110 and the right side surface 130A of the sub-unit 130. Thus, both the connectors 110A and 130A are fitted to each other.

Then, the right side surface 130A of the sub-unit 130, an annular Shirurin grayed 1 35 surrounding the entire circumference of the connector 131 is provided. When the left side surface 130 of the sub unit 131 is abutted against the right side surface of the main unit 110 and the units 110 and 130 are fixed to each other by a fixing method (not shown), the seal ring 135 seals the two without gaps. Thereby, it is possible to prevent dust or water droplets from entering the connectors 111 and 131 through between the side surfaces 110A and 130A.

<Embodiment 6>
A sixth embodiment will be described with reference to FIG. In the fifth embodiment, an example in which a fan unit and an ion generation unit are respectively added is shown. However, in the sixth embodiment, the expansion pattern is changed. In this embodiment, three ion generations are performed in one fan unit 200. Units 210 are mounted side by side. In this way, in order to enable both units 200 and 210 to be mounted in combinations other than single units (different numbers), the unit mounting structure may be made common in advance. In this embodiment, the fan unit 200 is used. Since each ion generating unit 210 is fixed by a screw, the screw mounting pitch (the J dimension interval in FIG. 19) is determined in advance as a standard pitch.

  Thus, if the unit can be attached even in combinations other than singular ones, it is effective for spraying ions over a wide range. In addition, if a part of the unit fails, it is only necessary to replace it, so the replacement cost is low.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention, and further, within the scope not departing from the gist of the invention other than the following. Various modifications can be made.

  (1) In the above-described embodiments, ions are generated using the discharge needle 25, but the ion generation unit 20 may be any unit that can generate ions, and uses the discharge needle 25. It may be other than. For example, there is a type that generates a corona discharge by applying a high voltage between opposing electrodes to generate ions.

  (2) In the above-described embodiment, the ion generation unit 20 has exemplified a so-called AC type as an ion generation method. That is, positive and negative ions were alternately generated by alternately applying positive and negative high voltages to one discharge needle 25. However, the ion generation unit 20 may have a so-called DC type, that is, a configuration in which a positive discharge needle and a high voltage generation circuit, and a negative discharge electrode and a high voltage generation circuit are provided exclusively for each.

  (3) In the sixth embodiment, the example in which the three ion generation units 210 are mounted side by side in the left and right direction on one fan unit 200 has been shown, but the combination of the units is not limited to this. As shown in FIG. 20, a plurality of ion generation units 210 can be mounted on one fan unit 200 side by side, or a plurality of units can be combined as shown in FIG. 21.

  (4) In the above embodiments, the air generation unit 40 is fixed to the ion generation unit 20 with a screw. However, it can be applied as long as it can be detached. On the other hand, the ion generating unit 20 may be provided with convex pieces for the concave grooves, and the units 20 and 40 may be held by fitting the concave and convex portions, and separated by releasing the fitting.

  (5) In Embodiments 1 and 5, the ion generation unit 20 is provided with the power supply line L1 and the power supply terminal 36, while the blower unit 40 is provided with the power reception terminal 66, and power is supplied from the ion generation unit 20 to the blower unit 40. The configuration may be reversed, that is, the power supply line L1 and the power supply terminal 36 are provided in the blower unit 40, while the power receiving terminal 66 is provided in the ion generating unit 20, and the ions from the blower unit 40 are provided. It is good also as a structure by which electric power is supplied to the generation | occurrence | production unit 20. FIG.

1 is an exploded perspective view of a static eliminator applied to Embodiment 1. FIG. Cross section of housing and casing Diagram showing the mounting structure of the discharge needle The figure which shows the electric constitution of a static elimination apparatus Cross section of static eliminator Similarly, a diagram showing the electrical configuration of the static eliminator The perspective view which shows the usage example of a static elimination apparatus BB sectional view in FIG. CC sectional view in FIG. Diagram explaining the turbulence phenomenon The perspective view of the ion generation unit applied to Embodiment 3, and a rectification unit. Sectional drawing which shows the state which attached the rectification unit to the ion generation unit Sectional drawing of the fan unit in Embodiment 3. The perspective view of the ion generation unit applied to Embodiment 4, and a coating plate Sectional drawing which shows the state which attached the covering board to the ion generating unit The block diagram which shows the electric constitution of the static elimination apparatus in Embodiment 5. The figure which shows the state just before both connectors are fitted The figure which shows the state where both connectors were fitted The top view of the static elimination apparatus in Embodiment 6. The figure which shows another Example The figure which shows another Example

DESCRIPTION OF SYMBOLS 20 ... Ion generation unit 22A ... Ion discharge port 25 ... Discharge needle 40 ... Blower unit 50 ... Fan unit 70 ... Air ejection unit 90 ... Rectification unit

Claims (7)

An ion generation unit comprising: an ion generation unit that generates ions by power supply from the outside; and an ion emission port for discharging ions generated by the ion generation unit to the outside;
A blower unit having a predetermined blow mode, and the ion generation unit is a static eliminator that discharges ions to the outside based on the predetermined blow mode,
The air blowing unit is detachable from the ion generating unit ,
The ion generation unit includes an ion generation circuit for generating the ions,
The blower unit includes an electric circuit,
Either one of the ion generation unit or the blower unit is provided with a power supply line for supplying power from a power supply to the circuit and a power supply terminal connected to the power supply line,
The unit on the other side is provided with a power receiving terminal,
When the power feeding terminal and the power receiving terminal are energized, power is supplied from the one side unit to the circuit of the other unit,
The ion generating unit and the air blowing unit are a static eliminator characterized in that a combination of both units is combined in different numbers . An ion generation unit comprising: an ion generation unit that generates ions by power supply from the outside; and an ion emission port for discharging ions generated by the ion generation unit to the outside;
A blower unit having a predetermined blow mode, and the ion generation unit is a static eliminator that discharges ions to the outside based on the predetermined blow mode,
The air blowing unit is detachable from the ion generating unit ,
The ion generation unit includes an ion generation circuit for generating the ions,
The blower unit includes an electric circuit,
Either one of the ion generation unit or the blower unit is provided with a power supply line for supplying power from a power supply to the circuit and a power supply terminal connected to the power supply line,
The unit on the other side is provided with a power receiving terminal,
When the power feeding terminal and the power receiving terminal are energized, power is supplied from the one side unit to the circuit of the other unit,
The blower unit includes a plurality of types of blower units, and the plurality of types of blower units have the same shape of the mounting portion with respect to the ion generation unit, and can be selectively attached to the ion generation unit. The static eliminator characterized by having. The static eliminator according to claim 2 , wherein the plurality of types of air blowing units include air blowing units having different air blowing modes. The blower unit is provided with an air outlet hole facing the air outlet, and the air taken in from the outside passes through the air outlet hole and is sent to the ion outlet.
The plurality of types of air blowing units include air blowing units having different discharge amounts or discharge areas of the air discharged to the outside from the ion discharge port by making the shapes of the air outlet holes different from each other. The static eliminator according to claim 3 . The size of the opening of the ion emission port, to claim 3 or claim 4, characterized in that it is formed larger than the opening of the air outlet hole in at least one blower unit of the plurality of types of blower units The static elimination apparatus of description. The ion generation units include those having different ion generation methods, and the ion generation units having different ion generation methods have the same shape of the mounting portion with respect to the blower unit, and any ion generation unit neutralization apparatus according to any one of is also attachable to the blower unit, to claims 2, wherein the claim 5. The neutralization device according to claim 3 , wherein the air blowing mode includes a non-air blowing mode.

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