JP2007159676A - Air deodorizing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air deodorizing device for removing the dust and deodorizing the cigarette smoke in a game parlor, for example, capable of sufficiently removing the dust and deodorizing the cigarette smoke. <P>SOLUTION: The air deodorizing device has a generator 39 for removing the dust and deodorizing the cigarette smoke by applying high voltage to aqueous solution in which deodorizing functional components such as catechin and silver are dissolved and emitting mist including the deodorizing functional components into the interior by utilizing the discharge phenomenon, and a metal plate 15 capable of adsorbing the emitted mist including the deodorization functional components. With this structure, the emitted nano-sized mist including the deodorizing functional components removes the dust and deodorizes the cigarette smoke in the air, and the mist after removing the dust and deodorizing the cigarette smoke is adsorbed in the metal plate 15, so that adhesion of the smell of the cigarette smoke to the clothes can be prevented. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an air deodorizing apparatus for deodorizing and deodorizing cigarette smoke in, for example, a game arcade.

  In recent years, air cleaners have been proposed that improve the deterioration of the indoor environment due to tobacco smoke and the like at amusement halls.

  This air purifier is attached to, for example, a pachinko island stand, and is configured to purify air sucked from the room and exhaust it into the room. Therefore, it is possible to remove indoor cigarette smoke and improve the indoor environment.

  However, there has been a problem that cigarette smoke cannot be sufficiently deodorized and deodorized, and odors are attached to clothes of pachinko players.

Japanese Patent No. 2536286 Japanese Patent No. 2754359 Japanese Patent No. 28114431

  The problem to be solved is that cigarette smoke cannot be sufficiently deodorized and deodorized.

  The present invention applies a high voltage to an aqueous solution in which a deodorizing functional component is dissolved in order to sufficiently deodorize and deodorize cigarette smoke, etc., and discharges the deodorizing functional component-containing mist into the room by a discharge phenomenon. The main feature is that a generator for deodorizing and deodorizing smoke is provided, and an adsorption medium capable of adsorbing the released deodorant functional component-containing mist is provided.

  The air deodorizer of the present invention is a generator that deodorizes and removes cigarette smoke by applying a high voltage to an aqueous solution in which a deodorant functional component is dissolved, and discharging a deodorant functional component-containing mist by a discharge phenomenon. And the adsorption medium capable of adsorbing the released deodorant functional component-containing mist is provided, so that the nano-size deodorant functional component-containing mist performs deodorization and deodorization of cigarette smoke etc. The deodorized mist is adsorbed by the adsorption medium, and it is possible to suppress the smell of cigarettes from adhering to the clothes.

  The object of making it possible to sufficiently deodorize and deodorize cigarette smoke and the like was realized by a deodorizing functional component-containing mist generator and an adsorption medium.

[Mounting position of air deodorizer]
FIG. 1 is a schematic perspective view showing an example of an attachment position of an air deodorizing apparatus for a gaming machine island stand according to Embodiment 1 of the present invention, and FIG. 2 is a side view of the pachinko island stand.

  As shown in FIG. 1 and FIG. 2, the air deodorizers 1, 1 </ b> A, 1 </ b> B, and 1 </ b> C are a display board 7 of a pachinko island base 3 as a gaming machine island base 5 and a call lamp mounting location 7 of the pachinko island base 3. These are selectively provided at any one of the upper ends 9 of the pachinko island base 3. It is also possible to reduce the size of the air deodorizer and provide it on the pachinko machine 11 that is a gaming machine table.

  A plurality of pachinko machines 11 are connected to the pachinko island table 3. The membrane plate 5 is attached to the pachinko island base 3 so as to be freely opened and closed, and is provided for each pachinko base 11. The display board 7 is provided with a call lamp 13 for each pachinko machine 11.

  Although the air deodorizing apparatus 1, 1A, 1B, 1C will be described later, in this embodiment, the air deodorizing apparatus is configured as an air purifying apparatus. A high voltage is applied to an aqueous solution in which a deodorizing functional component is dissolved, and the deodorizing function is caused by a discharge phenomenon. A generator for deodorizing cigarette smoke by discharging the active ingredient-containing mist into the room is provided, and conductive materials such as copper and stainless steel are used as an adsorption medium capable of adsorbing the released deodorant functional ingredient-containing mist. A metal plate 15 is provided. The metal plate 15 is provided with a filter 17 formed of paper, nonwoven fabric or the like on the upper surface. The filter 17 can also be provided on the lower surface or both upper and lower surfaces. The metal plate 15 and the filter 17 are provided on the pachinko island base 3, and do not require a space, and can be arranged without difficulty. Even if the filter 17 is dirty, it is a position that is not visible to the player, and does not give unpleasant feeling. An operator may get on the pachinko island table 3, but there is no problem in work if the strength of the metal plate 15 is maintained.

  The filter 17 can be selected from various configurations such as a structure in which the metal plate 15 can be peeled off with an adhesive or the like, a structure in which a metal mesh can be mounted on the metal plate 15, and the filter 17 is sandwiched between the metal mesh and the metal plate 15. Can be attached.

  When the air deodorizer 1, 1 </ b> A is attached to the membrane plate 5, the air deodorizer 1 attached to the entire membrane plate 5, the air deodorizer 1 </ b> A attached separately to the left and right membrane plates 5, etc. is there. It is also possible to use the membrane plate 5 integrally as a case for the air deodorizing device 1 or 1A. In this case, the air deodorizing apparatus 1, 1A can be handled together with the membrane plate 5, and assembly, repair, and replacement are facilitated. As for the air deodorizing apparatus 1B attached to the said display board 7, the calling lamp 13 is attached to the surface. The air deodorizing apparatus 1 </ b> C is attached to the upper part on the front side of the pachinko island base 3.

  FIG. 3 is a front view showing the air inlet and the mist outlet of the air deodorizer, and FIG. 4 is a cross-sectional view thereof. As shown in FIGS. 3 and 4, the air deodorizer 1 (1 </ b> A, 1 </ b> B, 1 </ b> C) includes, for example, a suction port 21 that faces obliquely downward in the lower portion of the case 19. 23. Air intake filters 25 and 27 such as anti-virus are provided at the intake port 21 and the exhaust port 23. Mist discharge ports 29 are provided on both the upper left and right sides. The front surface 30 of the case 19 can be used for various information transmissions, and commercials can be performed by a liquid crystal display or the like.

  The air deodorizing apparatus 1 (1A, 1B, 1C) includes a sirocco fan 31 in the vicinity of the air inlet 21 and sucks air from the air inlet 21 by the rotation of the sirocco fan 31 and exhausts air from the air outlet 23. It has become.

  In the air deodorizing apparatus 1 (1A, 1B, 1C), a cartridge 33 and a tank 35 for storing an aqueous solution in which a deodorizing functional component is dissolved are provided. Only one of the cartridge 33 and the tank 35 may be provided. The aqueous solution in which the deodorizing functional component of the cartridge 33 is dissolved can be performed with one touch by replacing the cartridge 33. The aqueous solution in which the deodorizing functional component in the tank 35 is dissolved can be easily supplied by the liquid feeding hose 37 arranged on the upper side of the pachinko island base 3 in FIGS.

  5 and 6 show the deodorizing functional component-containing mist generating device and the air passage of the air deodorizing apparatus in an emphasized manner, and are substantially the same as the structures of FIGS. 3 and 4. .

  The generators 39 are provided on the upper left and right sides of the case 19. The generator 39 includes a water retention base 41, a pin-shaped release base 43, a mist fan 45, and a filter 47. A tank 49 of an aqueous solution in which a deodorizing functional component is dissolved is connected to the water retention base 41.

  The air passage 51 inside the case 19 has a passage area enlarged at the intermediate portion 53 and narrowed at the suction side 55 and the discharge side 57. The intermediate portion 53 can release the deodorant functional component-containing mist as shown by an arrow A.

  Therefore, in the generator 39, air is sucked in through the filter 47 with the rotation of the mist fan 45, and the deodorizing functional component-containing mist is released as indicated by an arrow B (the principle of mist generation will be described later). The blown mist adheres to the tobacco particles in the amusement hall, and the tobacco particles are negatively charged and are dedusted and deodorized. Since the metal plate 15 is positively charged, the tobacco particles that are negatively charged as described above are adsorbed to the metal plate 15 on the pachinko island platform 3.

  Further, tobacco particles are sucked in from the air inlet 21 by the rotation of the sirocco fan 31, and the tobacco particles are negatively charged by the mist released as shown by the arrow A while reducing the flow velocity at the intermediate portion 53 in the case 19, and the dust is removed. , Deodorized and exhausted from the exhaust port 23. The exhausted tobacco particles and the like are adsorbed by the metal plate 15 on the pachinko island base 3 in FIG.

  When negatively charged tobacco particles or the like are adsorbed on the metal plate 15, a filter such as paper on the surface side receives this, so that the adsorption action of the metal plate 15 can be maintained for a long time by replacing the filter 17 and maintenance is easy. It is.

  On the other hand, the air deodorizer 1 (1A, 1B, 1C) sucks air from the intake port 21 while purifying air through the air purification filter 25, and exhausts air from the exhaust port 23 while purifying air again by the air purification filter 27. Therefore, the air cleaning function can be accurately achieved.

  Therefore, it is possible to effectively remove tobacco particles, dust, and the like that cause odors in the pachinko game hall, and to accurately perform air purification, dust removal, and deodorization in the game hall.

  Further, the deodorizing functional component-containing mist released from the generator 39 as described above also falls on the player's clothes and also deodorizes tobacco particles adhering to the clothes. Thus, it is possible to suppress the cigarette odor from being fixed on the player's clothes.

  The deodorant functional component-containing mist is nano-sized and does not get wet even if it adheres to the clothes, and the pachinko balls do not get wet. Therefore, a comfortable pachinko game can be continued.

[Configuration of generator]
FIG. 7: is a functional block diagram which shows the structure provided with the generator and metal plate of a deodorizing functional component containing mist.

  As shown in FIG. 7, the generator 39 applies a high voltage to the aqueous solution in which the deodorizing functional component is dissolved, and discharges the deodorizing functional component-containing mist into the room by a discharge phenomenon to deodorize and deodorize cigarette smoke. A porous molded body 59 for absorbing and holding an aqueous solution containing a nonvolatile deodorant functional component, and a water supply means 61 for supplying the porous molded body 59 with an aqueous solution containing a nonvolatile deodorant functional component; The DC high-voltage power source 63 for negatively charging the porous molded body 59 holding an aqueous solution containing a non-volatile deodorizing functional component is generally constituted.

  The porous molded body 59 has a water-absorbing property and a water-retaining property. The porous water-retaining base material 41 has a flat plate shape, and the porous discharge base material 43 protrudes from the water-retaining base material 41. It is configured. These water-retaining base material 41 and release base material 43 have excellent water absorption and water-retaining power, and are formed of a ceramic material, a synthetic resin material, a porous material of a metal material, or a fiber body.

  Ceramic materials constituting the porous or fibrous water retention base 41 include single oxides such as silica, alumina, magnesia, titania and zirconia, or mullite, zeolite, bentonite, sepiolite, attapulgite, sillimanite, kaolin, Examples include sericite, diatomite, feldspar, glazed clay, and silicate compounds (perlite, vermiculite, sericite, etc.), and natural fiber materials include pulp fiber, cotton, wool fiber, hemp fiber, and synthetic resin. Examples of the material include polyester, nylon, rayon, urethane (including polyurethane), acrylic, and polypropylene. Examples of the metal material include stainless steel, copper, titanium, tin, platinum, gold, and silver.

  In addition to the shape of porous body and fiber body, honeycomb structure and corrugated structure can be mentioned, and pipe shape, sheet shape, pleated shape etc. are also mentioned, but the necessary condition is that it has excellent water absorption and water retention is there.

  The release substrate 43 is a tip member that is formed as a rod-like body (stick body) and discharges an aqueous solution containing a deodorant functional component as a fine mist of about 1 to 100 nm. Projected. By forming the release base material 43 as a rod-like body in this way, it becomes easy to release mist containing the deodorant functional component from the release base material 43, and a plurality of release base materials 43 are provided on the water retention base material 41. By protruding, it is possible to increase the amount of deodorant functional component-containing mist released. Moreover, the structure of the front-end | tip part of the discharge | release base material 43 has a preferable edge structure rather than the flat surface, However, The front-end | tip part does not need to be sharply sharp. Moreover, the longitudinal cross section of the front-end | tip part of the discharge | release base material 43 is a round circle or an ellipse as shown in FIG.8 (b) rather than the square with an edge as shown in FIG.8 (a) ( In short, it is preferable to form a curved surface rather than an acute point, and by forming in this way, a large amount of a deodorizing functional component can be included in the released mist. Note that the amount of the deodorant functional component-containing mist discharged differs depending on the length, diameter, number, and tip shape of the release base material 43, and details thereof will be discussed in a test example to be described later.

  Further, the water retention rate of the release substrate 43 is preferably about 40 to 130%, more preferably about 80% to 130%. And it is preferable that the discharge | release base material 43 has a water absorption power higher than the water retention base material 41. FIG. This is because the aqueous solution containing the deodorizing functional component absorbed by the water retention base material 41 is supplied to or eluted from the release base material 43 without staying on the water retention base material 41.

  As the release substrate 43, ceramic fibers (ceramic fibers, glass fibers, etc.), organic fibers (polyester fibers, rayon fibers, nylon fibers, etc.), metal fibers (stainless fibers, copper fibers, titanium fibers, etc.), etc., are used as rods. Other examples include a porous body obtained by sintering ceramic particles or metal particles as a rod-like body, and a foam body such as urethane resin or styrene resin formed as a rod-like body. In the case of a porous body, it is convenient for the aqueous solution to pass through that the infinite number of micropores are continuous rather than an aggregate of independent microbubbles.

  For porous structures such as ceramics, resins, metals, etc., the water absorption characteristics determine the release performance, and the amount of water taken up per hour is particularly important. These performances are determined by the water absorption rate per hour of the porous body, and the water absorption rate of about 10 to 200% is suitable for any material. -80% is preferable, 100-200% is preferable for the resin, and 10-60% is preferable for the metal.

  As shown in FIG. 9, as a specific configuration when the release base material 43 is formed in a fibrous structure, in ceramics, glassy fibers called ceramic fibers or silica or mullite crystalline fibers are formed using a binder. Synthetic resins include fibers such as polyester, nylon, and acrylic. Short fibers are molded using a binder, and long fibers are bundled together to have an arbitrary thickness. Cut with appropriate specifications. In these fibrous structures, an aqueous solution containing a deodorant functional component can be sucked up from the water retention base material 41 by capillary action.

  The water supply means 61 contains an aqueous solution containing a deodorizing functional component such as catechin and vitamins, and always supplies an aqueous solution containing the deodorizing functional component to the water retention base 41 using a capillary phenomenon or the like. In this embodiment, it is composed of a storage bottle 65 and a supply tube 67, and a water amount sensor 69 is provided inside thereof.

  Deodorant functional components include catechin, wood vinegar, bamboo vinegar, corn extract component, vitamin C (L-ascorbic acid), vitamin C ester (magnesium L-ascorbate phosphate, sodium L-ascorbate phosphate, phosphate) Ascorbyl magnesium, etc.), vitamin A, vitamin B, vitamin D, vitamin Dα-lipoic acid, amino acids, tea leaf extract (catechin, tannin, saponin, theanine, caffeine, etc.), hyaluronic acid, collagen, aroma essential oil (lavender, rose) Mary, lemongrass, tea tree, sage, clove, orange, grapefruit, cinnamon, jasmine, etc.), coffee beans, tea leaves, wasabi, hinokitiol, chitin, chitosan, propolis, etc. (Nothing System soluble components) in the silver or sodium chloride and the like.

  Here, “deodorization functionality” means deodorizing and deodorizing indoor cigarette smoke.

  The DC high voltage power supply 63 is a power supply that generates a DC negative voltage of about 10 kV, for example, and its negative electrode is connected to the water retention substrate 41 via a conductor 71 to hold an aqueous solution containing a deodorant functional component. The water retaining substrate 41 is negatively charged. The anode of the DC power source is connected to the metal plate 15 by a conducting wire 73 to charge the metal plate 15 positively. By connecting the negative electrode of the DC high-voltage power supply 63 to the water retention substrate 41, the current flows in search of a place where discharge is most likely to occur, and usually gathers in a place where the tip is pointed or a place with excellent electrical conductivity such as a metal. Utilizing the properties, it collects in the release substrate 43.

  The method for generating the deodorant functional component-containing mist is performed using the generating device 39 having the above-described configuration, and an aqueous solution containing a non-volatile deodorant functional component is supplied from the water supply means 61 to the water retention base material 41, and is nonvolatile. The negative electrode of the DC high-voltage power supply 63 is connected to the water retention base material 41 holding the aqueous solution containing the deodorant functional component and charged negatively. When the water retention base 41 holding the aqueous solution containing the non-volatile deodorant functional component is negatively charged in this way, the current flows up to the tips of the plurality of release bases 43 protruding from the water retention base 41. Occurs and a natural discharge phenomenon occurs, and an ionic wind is generated by the discharge action. By using this ionic wind, deodorizing functional components such as vitamins are nano-sized (about 1 to 100 nm) invisible fine. It can be released in large quantities together with mist.

  The porous molded body 59 is composed of a composite of one or more of ceramic material, synthetic resin material, and metal material, and deodorized functional component-containing mist particles released from the release substrate 43. Depends on the electrical conductivity or voltage of the porous molded body 59 and is a particle mist of about 1 to 100 nm, so that it can be scattered to every corner of the room using wind. Further, the release substrate 43 is always wet during operation, and as described above, the water retention amount of the porous material constituting the release substrate 43, the length and diameter of the release substrate 43, the tip shape, the number or The ability to release the deodorant functional component varies depending on the shape.

  Next, as a second embodiment in which a long-term effect of the deodorizing functional component is obtained, a non-volatile deodorizing functional component is formed on the porous molded body 59 composed of the water retention base material 41 and the release base material 43. May be supported. Specifically, the deodorizing functional component is impregnated with or attached to the water retention base material 41 having excellent water absorption and water retention capability as well as the characteristics of the release base material 43 using an inorganic or organic compound binder. . When the functional component is fixed to the water retention base material 41 made of a porous body or fiber body with an inorganic or organic compound binder, the supply amount or elution amount of the deodorizing functional component to the release base material 43 and the suction speed are controlled. It is possible to control the release rate or release amount of the deodorant functional component, and a long life can be expected.

  The porous body or fiber body of the support to be fixed must be excellent in water absorption and water retention, and in the case of a porous body, it is important that the porous structure has continuous pores. Materials include ceramic fibers (ceramic fibers, glass fibers, etc.), organic fibers (polyester fibers, rayon fibers, nylon fibers, etc.), metal fibers (stainless fibers, copper fibers, titanium fibers, etc.), etc. in sheet form or block form. In addition, a molded body, a porous body obtained by sintering ceramic particles or metal particles, and a foamed body such as urethane resin or styrene resin are exemplified.

  Inorganic compounds such as lithium silicate, potassium silicate, sodium silicate, zirconium silicate calcium silicate, aluminum silicate, ethyl silicate, silica sol, and organosilicate are used as binders for supporting (fixing) the deodorant functional component on the water retention substrate 41. Acid salts or phosphates such as phosphoric acid, polyphosphoric acid, ultrapolyphosphoric acid, aluminum phosphate, calcium phosphate, and magnesium phosphate. Examples of organic compounds include methylcellulose, carboxymethylcellulose, polyvinyl alcohol, urethane emulsion, acrylic emulsion, acetic acid Examples include vinyl emulsion.

  The impregnation and adhesion of the deodorizing functional component to the water-retaining base material 41 of the porous body or the fiber body is performed by dissolving one or two or more types of the deodorizing functional component in a binder aqueous solution of an inorganic or organic compound. The water retention substrate 41 is brought into contact with this aqueous solution and dried.

  In this embodiment, the water retention base material 41 carrying the deodorant functional component functions as a deodorant functional component stock yard provided for supplying the release base material 43 with the aqueous solution from which the deodorant functional component is eluted. The characteristics required of the water retention substrate 41 are firstly the water retention amount of the aqueous solution, and secondly, it is a structure that can supply the aqueous solution from which the functional component is eluted over a long period of time. That is, if the deodorizing functional component can be gradually eluted in water using an inorganic or organic compound binder, the deodorizing functional component can be supplied to the release substrate 43 for a long time. .

  In this way, water is supplied from the water supply means 61 to the water retention base 41 carrying (fixing) the deodorant functional component, and the negative electrode of the DC high-voltage power supply 63 is connected to the water retention base 41 in the water retention state to be negatively charged. As a result, a current flows to the tips of the plurality of discharge base materials 43 projecting from the water retention base material 41, a spontaneous discharge phenomenon occurs, and an ionic wind is generated by the discharge action. The deodorizing functional component fixed to the base material 41 is released in a large amount together with a fine mist that is invisible to the nanosize (about 1 to 100 nm) while moving as an aqueous solution to the release base material 43. And according to the application to be used, the material selection of the release base material 43, the length, diameter, tip shape, and number of the release base material 43 are appropriately designed to reduce the amount of mist containing the deodorant functional component. Can be designed arbitrarily.

  The mist containing the deodorant functional component is nano-sized with a particle size of about 1 to 100 nm, and is in a very fine state such that the wall surface does not get wet. , You can go to every corner of the game hall and car.

[Test Example 1]
Test Example 1 is an evaluation of the influence of the water retention amount of the release substrate for the purpose of enabling the release control of a mist containing a deodorant functional component (hereinafter referred to as “deodorant mist”).

(Test equipment)
As shown in FIG. 10, as a test apparatus, an evaluation generating unit 83 is installed on the floor of a hollow cubic acrylic container 81 (1 m3) having a side of 1 m, and a discharge base material of the generating unit 83 is used as a test substrate. An evaluation system was used, which was covered with a funnel-shaped glass container 85, and the discharged deodorized mist was directly sucked and bubbled and dissolved in pure water in the container 89 evacuated by the vacuum pump 87. The acrylic container 81 was previously installed in a room maintained at 25 ° C.-55% RH. In FIG. 10, 91 is a water retention substrate, 93 is a discharge substrate, 95 is a suction tube, and 97 is a DC high voltage power source. The length of the prototype release substrate is 30 mm and the thickness (diameter) is 2.0 mmφ. Table 1 below shows the material and weight% of the prototype release substrate.

(Test conditions)
The test conditions are: measurement environment is air temperature 25 ° C., humidity 55%, release substrate material is polyester fiber and porous alumina, release substrate number is 24, DC minus voltage is 10 kV, and operation time is 6 hours. A spectrophotometer U-3010 manufactured by Hitachi was used as a vitamin release amount measuring device.

(contents of the test)
The deodorant mist release test method has a plurality of porous release bases protruding from the generating part as bases for releasing nano-size mist. As for the effect of the deodorizing mist released from the release substrate on the release amount per hour, the number of release substrates, the tip shape, and the negative voltage were constant, and the mist release amount was comparatively analyzed. That is, as shown in FIG. 10, in the sealed space in the acrylic container 81, the generating unit 83, the vacuum pump 87, pure water stored in the container 89 and the like are prepared, and the deodorized mist discharged from the generating unit 83. Is directly bubbled into pure water, the vitamin concentration per hour dissolved in the pure water is quantitatively analyzed, the amount of vitamin released per hour according to the amount of water retained in the release substrate 93 is compared, and the amount of water retained in the release substrate 93 is determined. We prepared several prototype base materials with different specifications, and compared and verified the deodorant mist release ability of each prototype base material with different water holding capacity. In this evaluation, a 1% vitamin aqueous solution was used, and the amount of deodorized mist released per hour was measured.

(Analysis method of deodorant functional component release concentration)
As shown in FIG. 11, the concentration of ascorbic acid, which is a vitamin component, was determined from the numerical value of the DPPH radical reduction amount of pure water dissolved by bubbling the deodorant mist subjected to the release test in this way. The analysis method is a method of quantitatively analyzing the concentration of ascorbic acid using a spectrophotometer by utilizing the property (antioxidant action) that DPPH radicals are eliminated by the concentration of ascorbic acid dissolved in the DPPH solution. .

  DPPH (manufactured by Wako Pure Chemicals Co., Ltd .: 1,1-diphenyl-2-picrylhydrazyl) prepared in a 0.125 mmol / · ethanol solution is placed in a 5 cc Erlenmeyer flask and shaken at 30 ° C. Put in. First, the peak of DPPH ethanol solution is measured, and 1 cc of sample is put. If the sample is antioxidant, the radicals in the DPPH ethanol solution will decrease and the solution will change from purple to yellow. A value obtained by subtracting the peak at that time from the peak of the DPPH ethanol solution is a value indicating the antioxidant power.

(Test results)
Table 2 below shows the measurement results of each prototype base material made of polyester fiber, and FIG. 12 is an explanatory diagram showing the influence of the water retention rate of the polyester base material on the vitamin release performance based on the measurement results. It is.

  Table 3 below shows the measurement results of each prototype substrate made of a ceramic porous body (porous alumina). FIG. 13 shows vitamins based on the water retention rate of the ceramic porous substrate based on the measurement results. It is explanatory drawing which showed the influence on discharge | release performance.

  According to this test example, as shown in FIG. 12 and FIG. 13, the influence of the water retention amount (water retention rate) of the release substrate is less likely to generate deodorant mist as expected with a low water retention amount, and the water retention amount is 80 to 80%. The most generated amount is obtained at about 100%. However, as the amount of water retained increased and became supersaturated, it was confirmed that the amount of vitamin generated rapidly decreased. The release performance of the release substrate depends on the amount of water retained rather than the material, and the water retention rate is in the range of 40 to 130%, preferably in the range of 80 to 100%, under the condition that most deodorant mist can be released. It is believed that there is.

[Test Example 2]
Test Example 2 evaluated the influence of the length and diameter (thickness) of the release substrate for the purpose of enabling release control of a mist containing a deodorant functional component (hereinafter referred to as “deodorant mist”). Is.

(Test equipment)
As the test apparatus, the evaluation system shown in FIG. The acrylic container 81 was previously installed in a room maintained at 25 ° C.-55% RH. Table 4 below shows the length / diameter of the prototype release substrate.

(Test conditions)
Test conditions are: ambient temperature 25 ° C, humidity 55%, release substrate material is polyester fiber, release substrate number 24, DC minus voltage 10kV, operation time 6 hours, vitamin release amount A spectrophotometer U-3010 manufactured by Hitachi was used as a measuring machine.

(contents of the test)
In the deodorant mist release test method, a plurality of porous release substrates are protruded from the generation part as a substrate for releasing nano-sized mist, but the length or diameter of the release substrate is changed. In this case, the mist emission amount was compared and analyzed with respect to the influence of the deodorizing mist released from the release substrate on the release amount per hour, with the number of release substrates, the tip shape, and the negative voltage being constant. That is, as shown in FIG. 10, a generating unit 83, a vacuum pump 87, pure water stored in a container 89, etc. are prepared in a sealed space in an acrylic container 81, and deodorized mist discharged from the generating unit 83 is removed. Directly bubbling in pure water, quantitatively analyzing the vitamin concentration per hour dissolved in pure water, comparing the amount of vitamin released per hour according to the length or diameter of the release substrate, the length or diameter of the release substrate We compared and verified the deodorant mist release ability when changing the odor. In this evaluation, a 1% vitamin aqueous solution was used, and the amount of deodorized mist released per hour was measured.

(Analysis method of deodorant functional component release concentration)
As the method for analyzing the deodorant functional component release concentration, as in Test Example 1, a method of quantitatively analyzing the concentration of ascorbic acid using a spectrophotometer was adopted.

(Test results)
Table 5 below shows the measurement results of each prototype substrate, and FIG. 14 is an explanatory diagram showing the influence of the length / thickness of the release substrate on the release amount based on the measurement result.

  According to this test example, as shown in FIG. 14, the influence of the length and thickness (diameter) of the release substrate confirms the tendency that the amount of deodorant mist released increases as the length increases. did it. Moreover, when the length was the same, the tendency that the discharge | release amount of deodorant mist decreased as the thickness of the discharge | release base material became thick was able to be confirmed.

  Furthermore, it is judged that the appropriate conditions for increasing the amount of deodorized mist released are that the length of the release substrate is long and the thickness (diameter) is preferably about 1 to 2 mm. Moreover, when the length of a discharge | release base material exceeds 20 mm, there exists a tendency for discharge | release amount to become stable, and when it is less than about 15 mm, it is thought that it reduces rapidly.

[Test Example 3]
Test Example 3 evaluates the influence of the shape (tip shape) of the tip of the release substrate for the purpose of enabling the release control of a mist containing a deodorant functional component (hereinafter referred to as “deodorant mist”). It is a thing.

(Test equipment)
As the test apparatus, the evaluation system shown in FIG. 10 was used as in Test Example 1 and Test Example 2. The acrylic container 81 was previously installed in a room maintained at 25 ° C.-55% RH. FIG. 15 shows the tip shape of the prototype release substrate.

(Test conditions)
The test conditions were the same as in Test Example 2, and a Hitachi spectrophotometer U-3010 was used as a deodorant functional component release amount measuring device.

(contents of the test)
In the deodorant mist release test method, a plurality of porous release substrates are projected as the substrate to release nano-size mist at the generating part, but the tip shape of the release substrate is changed Furthermore, regarding the influence of the deodorant mist released from the release substrate on the release amount per hour, the number of release substrates and the negative voltage were constant, and the mist release amount was comparatively analyzed. That is, as shown in FIG. 10, a generating unit 83, a vacuum pump 87, pure water stored in a container 89, etc. are prepared in a sealed space in an acrylic container 81, and deodorized mist discharged from the generating unit 83 is removed. When bubbling directly into pure water and quantitatively analyzing the vitamin concentration per hour dissolved in pure water, comparing the amount of vitamin released per hour according to the tip shape of the release substrate, and changing the tip shape of the release substrate The deodorant mist release ability was compared and verified. In this evaluation, a 1% vitamin aqueous solution was used, and the amount of vitamin mist released per hour was measured.

(Analysis method of deodorant functional component release concentration)
The deodorant functional component release concentration was analyzed by a method of quantitatively analyzing the concentration of ascorbic acid using a spectrophotometer, as in Test Example 1 and Test Example 2.

(Test results)
Table 6 below shows the measurement results of each prototype base material, and FIG. 16 is an explanatory diagram showing the influence of the shape of the tip of the release base material on the amount of deodorized mist released based on this measurement result.

  According to this test example, as shown in FIG. 16, the tip shape of the release base material is such that the prototype base material (1) that is sharply sharpened and the flat shape of the prototype base material (5) are It is determined that the ascorbic acid concentration is difficult to increase even when the energization time has elapsed. As for the tip shape of the release substrate, it is considered that the rounded shape of the prototype substrates (3) and (4) is suitable for releasing mist containing a deodorant functional component.

[Test Example 4]
Test Example 4 is for the purpose of confirming that the deodorant mist generator enables indoor humidity control that could not be adequately handled by a humidifier, and humidity control test data by the deodorant mist generator was used. It is to provide.

(Test equipment)
As shown in FIG. 17, as a test apparatus, an evaluation generation unit 103 is attached to the top of a hollow cubic acrylic container 101 (1 m3) having a side of 1 m, and an air fan is placed on the floor of the acrylic container 101. An evaluation system provided with an (axial fan) 105 and a humidity data logger 107 was used. The acrylic container 101 was previously installed in a room maintained at 25 ° C.-55% RH. Using such a test apparatus, the influence of the deodorant mist emission amount due to the difference in the number of release substrates (pins) or the negative voltage was tested.

(Test conditions)
The test conditions are as follows: the measurement environment is an air temperature of 25 ° C., the humidity is 55%, the number of release substrates is 24, 18, 12, 6, DC negative voltages are 10 kV and 5 kV, the operation time is 6 hours, and the humidity A digital humidity data logger was used as a measuring machine.

(contents of the test)
The deodorant mist release test method has a plurality of porous release bases protruding from the generation part as a base for releasing nano-size mist, but when the number of release bases is changed, Alternatively, when the negative voltage generated from the DC power source is changed, the humidity change in the sealed space in the acrylic container 101 is measured for the influence on the discharge amount of the deodorant mist discharged from the discharge base material, and various conditions The humidity control effect was compared and verified. In addition, this evaluation measured the humidity change in the sealed space in the acrylic container 101 using 5% vitamin aqueous solution.

(Test results)
Table 7 below shows the measurement results of each prototype base material, and FIG. 18 is an explanatory diagram showing the transition of humidity due to clear mist emission every 30 minutes based on the measurement results.

  According to this test example, as shown in FIG. 18, it can be seen that the number of deodorant mist release substrates (pins) greatly affects the deodorant mist to be released. In addition, when the number of release substrates is the same, the amount of deodorant mist released is affected by the applied voltage, and as the number of release substrates increases, the difference in the amount of deodorant mist released due to the voltage difference increases. The tendency to become was seen. Furthermore, the number of release base materials tended to increase the difference in clear mist discharge amount with the operating time. In particular, in the case of six, the influence by the voltage difference is hardly seen, and it is judged that a certain number of release substrates are necessary. As described in Test Example 1 to Test Example 3 above, the amount of deodorant mist released is influenced by the water retention amount of the release substrate, the length and thickness (diameter) of the release substrate, the tip shape, etc. Wet effect seems to be different. It seems that the amount of deodorant mist released in this way can be controlled by setting several conditions.

[Test Example 5]
Test Example 5 verifies the effect of improving the indoor environment when the generator is applied to an air cleaner or a humidifier.

  As shown in FIG. 19, the apparatus configuration in the case of applying to these devices is a discharge base material in which a generator 111 is attached to a blowout port or the like of an air purifier or a humidifier and protrudes from a water retention base material 113. It is conceivable to supply water or an aqueous vitamin solution to the water 115 from the water supply means 117 and connect the negative electrode of the DC high voltage power source 119 to the water retention base 113 to negatively charge the water retention base 113 in the water retention state.

(contents of the test)
A 1m3 cubic sealed container is filled with smoke of five cigarettes (mild seven) with a suction-type tobacco smoke generator, and using a gas detector tube (made by Gastec) dedicated to ammonia gas, in dry mist continuous operation The residual ammonia concentration was measured after 30 minutes and 60 minutes. When the cigarette was completely burned out, the initial concentration was set, and the dry mist switch was turned on.

  The calculation method of the deodorization rate of each odor component after 30 minutes and after 60 minutes was obtained by the following formula.

Deodorization rate (%) η30 = (1−C30 / C0) × 100
η60 = (1−C60 / C0) × 100
(Test results)
Table 8 below shows the measurement results of the ammonia concentration after 30 minutes and 60 minutes in the case of dry operation in the case of dry mist-10 kV, in the case of dry mist-10 kV and deodorizer, in the case of dry mist-5 kV. FIG. 20 is an explanatory diagram showing the change over time in the ammonia concentration based on the measurement results.

  According to this test example, as shown in FIG. 20, the ammonia concentration decreased with time in any case, and in the case of dry mist-10 kV, the case of dry mist-10 kV and deodorant was ammonia. It can be seen that the deodorizing effect is high.

[Test Example 6]
Test Example 6 verifies the effect of improving the indoor environment when the generator is applied to an air cleaner.

  First, Table 9 below shows the measurement results of the formaldehyde deodorizing performance after 30 minutes and 60 minutes when the mist is generated indoors, when nano e negative ions are generated, and when the idle operation is performed. Yes, FIG. 21 is an explanatory diagram showing a comparison of the deodorization rate of formaldehyde based on the measurement results.

  As shown in FIG. 21, in any case, the formaldehyde deodorization rate increases with the passage of time, but it can be seen that the formaldehyde deodorization effect is higher when mist is generated than in other cases.

  Next, Table 10 below shows measurement results of ammonia deodorization performance after 30 minutes and 60 minutes when mist is generated indoors, when nano e negative ions are generated, and when idling is performed. FIG. 22 is an explanatory diagram showing a comparison of deodorization rates of ammonia based on the measurement results.

  As shown in FIG. 22, in any case, the ammonia deodorization rate increases with time, but it can be seen that the case where mist is generated has a higher ammonia deodorization effect than the other cases.

  Table 11 below shows that when tobacco dust is naturally attenuated, when it is removed by an electrostatic filter, when mist is generated, and when nano e negative ions are generated, 10 minutes, 20 minutes later, 30 The measurement result of the tobacco dust density | concentration after 40 minutes after a minute is shown, FIG. 23 is explanatory drawing which shows the comparison of a tobacco dust density | concentration based on this measurement result.

  As shown in FIG. 23, in any case, the tobacco dust concentration gradually decreases with the passage of time, but it can be seen that when the deodorizing mist is generated, the tobacco dust concentration is drastically reduced as compared to other cases. .

  Further, Table 12 below shows the measurement results of the tobacco deodorization performance after 30 minutes and 60 minutes when mist is generated, when nano e negative ions are generated, and when idling is performed. FIG. 24 is an explanatory diagram showing a comparison of tobacco deodorization rates based on the measurement results.

  As shown in FIG. 24, in any case, the tobacco deodorization rate increases with time, but it can be seen that the case where the deodorizing mist is generated has a higher tobacco deodorizing effect than the other cases.

[Effect of Example 1]
The air deodorizing apparatus 1, 1A, 1B, 1C of Example 1 of the present invention applies a high voltage to an aqueous solution in which a deodorizing functional component is dissolved, and releases a mist containing a deodorizing functional component into a room by a discharge phenomenon. Generator 39 for deodorizing and deodorizing the smoke and the metal plate 15 capable of adsorbing the released deodorant functional component-containing mist are provided, so that the nano-size deodorant functional component-containing mist is removed from the cigarette in the air. In addition, the mist that has been deodorized and deodorized is adsorbed by the metal plate 15 and the odor of cigarettes and the like can be prevented from being fixed on clothes.

  Since the metal plate 15 includes the filter 17, the adsorption function of the metal plate 15 can be maintained for a long time, and maintenance is easy by replacing the filter.

  Since the generating device 39 is disposed in the game hall where the pachinko island base 3 is installed, and the metal plate 15 is provided at the upper end of the pachinko island base 3, it does not require a space and is arranged without difficulty. Can do. Even if the filter 17 is dirty, it is a position that is not visible to the player, and does not give unpleasant feeling.

  The generating device 39 is provided in the case 19, and the case 19 sucks air from the air inlet 21, the air outlet 23, the air inlet 21 and exhausts the air from the air outlet 23, and purifies the exhausted air to exhaust the air. Since the air purification filters 25 and 27 are provided, the air deodorization can be performed while performing the air purification.

Since the generator 39 is provided at any one of the membrane plate 5 of the pachinko island base 3 installed in the amusement hall, the calling lamp mounting position of the pachinko island base 3, and the upper end of the pachinko island base 3,
In particular, it can be arranged without difficulty without requiring space.

  The deodorant functional component is catechin, wood vinegar, bamboo vinegar, corn extract component, vitamins, vitamin derivatives, catechin, hyaluronic acid, amino acids, organic soluble components such as collagen, or inorganic such as silver or salt Since it is one type or two or more types among the system-soluble components, it can be surely deodorized.

  The generating device 39 includes a porous molded body 59 having water absorption and water retention properties by projecting a porous discharge base material 43 to a porous water retention substrate 41, and the water retention substrate 41 having a non-volatile property. The water supply means 61 for holding the aqueous solution containing the deodorizing functional component and the porous molded body 59 holding the aqueous solution containing the nonvolatile deodorizing functional component with the negative electrode connected to the porous molded body 59 are negative. Therefore, the nano-sized deodorizing functional component-containing mist can be reliably discharged indoors.

  FIG. 25 is a perspective view of a pachinko island stand showing the arrangement of an air deodorizing apparatus consisting only of a mist generating device, and FIG. 26 is a schematic cross-sectional view showing the arrangement of the adsorption medium.

  In the present embodiment, the upper part of the pachinko island base 3, the membrane plate 5, the width board space 123, the calling lamp 13, a part of the center on the pachinko base 11, the entire upper width direction of the pachinko base 11, at least one of the left and right on the pachinko base 11, Air deodorizers 121, 121B, which include only a deodorizing functional component-containing mist generating device on at least one of the left and right sides of the pachinko base 11, at least one of the upper left and right sides of the pachinko base 11, the entire membrane plate, the ball plate, and the bottom of the foot. 121C, 121D, 121E, 121F, 121G, 121H, 121I, 121J, 121K, 121L were attached.

  The metal plate 15 and the filter 17 are on the pachinko island platform 3 and can adsorb the negatively charged tobacco particles as described above.

  FIG. 27 is a cross-sectional view of the pachinko island stand showing the arrangement of the air deodorizer. The basic configuration is the same as that of the first embodiment.

  The left air deodorization device 125 is an integral type of the membrane plate 5, and the membrane plate 5 constitutes the case 19.

  The right side air deodorization device 127 is a membrane plate 5 integrated type, and a part of the membrane plate 5 is rotatably attached to form an island rack 5A. When the island rack 5A is rotated to a horizontal position, the luggage storage is performed. Can be used as

  FIG. 28 is a plan view showing the positional relationship between the air deodorizing apparatus and the adsorption medium, and FIG. 29 is a cross-sectional view of the main part thereof. The basic configuration is the same as that of the first embodiment.

  The exhaust ports 23 of the air deodorizer 129 are located on the left and right on the pachinko island base 3, and the metal plate 15 and the filter 17 are disposed between the left and right exhaust ports 23. The filter 17 is disposed on both surfaces of the metal plate 15, and an air passage 131 is formed between the pachinko island base 3 and the metal plate 15.

  Accordingly, the exhaust gas containing the negatively charged tobacco particles can immediately flow directly into the air passage 131 when discharged from the exhaust port 23, and the tobacco particles and the like can be efficiently and reliably adsorbed to the metal plate 15. it can.

  FIG. 30 is a cross-sectional view of the pachinko island stand showing the arrangement of the air deodorizer.

  The left air deodorizer 133 has the same structure as that of the first embodiment. The right air deodorization device 135 has the generator 39 as a separate component and is mounted on the pachinko island base 3.

  FIG. 31 is a cross-sectional view of the pachinko island stand showing the arrangement of the air deodorizer.

  The air deodorizing device 137 has a main body 139 and a mist generating device 39 which are separated from each other, and the main body 139 is provided integrally with the calling lamp 13, and the generating device 39 is an upper part of the pachinko island base 3 or a membrane plate. 5 is attached.

  In addition, it should be thought that the above-mentioned Example is an illustration and restrictive at no points. The present invention is not limited to the above description, but is defined by the scope of the claims, and includes all modifications within the scope and meaning equivalent to the scope of the claims.

  When disposing the mist generating device separately from the air deodorizing device main body, the generating portions of the water retention base material 41 and the discharge base material 43 can be disposed apart from the tank 49 or the like which is another member.

  As a gaming machine island stand, it can also be applied to the throttle island stand, and as a gaming machine, it can also be applied to a throttle stand.

  The generators 1, 1A, 1B, 1C, 121, 121A, 121B, 121C, 121D, 121E, 121F, 121G, 121H, 121I, 125, 127, 129, 133, 135, and 137 are related separately from the adsorption medium. The upper part of the pachinko island stand 3 installed in the amusement hall, the membrane plate 5, the width plate space 123, the calling lamp 13, the central part on the pachinko stand 11, the entire upper width direction of the pachinko stand 11, the left and right on the pachinko stand 11 at least On the other hand, it can be provided on at least one of the left and right under the pachinko machine 11, at least one of the upper and lower middle of the pachinko machine 11, the entire membrane plate, the ball plate, the lower surface of the foot, or the like.

  The generators 1, 1A, 1B, 1C, 121, 121A, 121B, 121C, 121D, 121E, 121F, 121G, 121H, 121I, 121J, 121K, 121L, 125, 127, 129, 133, 135, 137 are mist. The only part of the pachinko island base 3 installed in the amusement hall as the generation part of the pachinko island base 3, the membrane plate 5, the width plate space 123, the calling lamp 13, the central part on the pachinko base 11, the pachinko base 11 top width direction The whole, at least one of the left and right on the pachinko machine 11, at least one of the lower and right of the pachinko machine 11, at least one of the upper and middle of the pachinko machine 11, the whole membrane plate, the ball plate, the lower surface of the foot, etc. Etc. can also be arranged separately in the gaming machine Shimadai etc.

  The upper part of the pachinko island base 3 where the generator or the porous molded body is installed in the amusement hall, the membrane plate 5, the width plate space 123, the calling lamp 13, a part of the center on the pachinko base 11, and the entire width direction of the pachinko base 11 By providing it on at least one of the left and right sides of the pachinko machine 11, at least one of the left and right sides of the pachinko machine 11, at least one of the upper left and right sides of the pachinko machine 11, the entire film board, the ball plate, the lower surface of the foot, etc. The mist can be spread over and the deodorant of the amusement hall where the environment of smell such as cigarette tends to become extremely bad can be performed. In addition, it is possible to deodorize the smoke of cigarettes of adjacent players before they reach each other, and the air environment can be reliably improved.

  The upper part of the pachinko island base 3 installed in the amusement hall as an air purifier equipped with an air inlet, an air outlet, and a fan, a membrane board 5, a width board space 123, a calling lamp 13, a central part on the pachinko board 11, If it is provided on the entire upper width direction of the pachinko machine 11, at least one of the left and right sides of the pachinko machine 11, at least one of the lower left and right of the pachinko machine 11, at least one of the upper left and right sides of the pachinko machine 11, A player's cigarette smoke can be sucked in, and it is also possible to prevent smoke damage from adjacent cigarettes.

It is a perspective view of a pachinko island stand (Example 1). (Example 2) which is a side view of a pachinko island stand. (Example 3) which is a front view which shows the inlet port of an air deodorizing apparatus, and the discharge port of mist. It is sectional drawing which shows the inlet port of an air deodorizing apparatus, and the discharge port of mist (Example 1). It is the schematic which emphasized and showed the generator and air passage of the deodorizing functional component containing mist of an air deodorizing apparatus (Example 1). It is the schematic which emphasized and showed the generator and air passage of the deodorizing functional component containing mist of an air deodorizing apparatus (Example 1). It is the schematic which shows the deodorizing apparatus provided with the generator of a deodorizing functional component containing mist, and the metal plate (Example 1). It is the schematic which shows the shape of the front-end | tip part of a discharge | release base material (Example 1). It is the schematic which shows the specific structure in the case of forming a discharge | release base material in a fibrous structure (Example 1). It is the schematic which shows the evaluation system of deodorant mist discharge | release (Example 1). It is a conceptual diagram which shows the method of quantitatively analyzing the containing density | concentration of ascorbic acid using a spectrophotometer (Example 1). It is explanatory drawing which showed the influence on the vitamin release performance by the water retention of a polyester base material (Example 1). It is explanatory drawing which showed the influence on the vitamin-release performance by the water retention of a ceramic porous body base material (Example 1). It is explanatory drawing which showed the influence on the discharge amount by the length / thickness of a discharge | release base material (Example 1). It is the schematic which shows the front-end | tip shape of each release base material made as an experiment (Example 1). It is explanatory drawing which showed the influence on the deodorizing mist discharge | release amount by the front-end | tip shape of a discharge | release base material (Example 1). It is the schematic which shows the test apparatus of a humidity control test (Example 1). It is explanatory drawing which showed transition of the humidity by clear mist discharge | emission for every 30 minutes (Example 1). It is the schematic which shows the apparatus structure in the case of applying a generating part to an air deodorizing apparatus or a humidifier (Example 1). It is explanatory drawing which shows the time change of ammonia concentration (Example 1). It is explanatory drawing which shows the comparison of the deodorizing speed | rate of formaldehyde (Example 1). It is explanatory drawing which shows the comparison of the deodorizing speed | velocity | rate of ammonia (Example 1). It is explanatory drawing which shows the comparison of a tobacco dust density | concentration (Example 1). It is explanatory drawing which shows the comparison of a tobacco deodorizing speed (Example 1). (Example 2) which is a schematic perspective view of a pachinko island stand. (Example 2) which is a schematic sectional drawing of a pachinko island stand. (Example 3) which is a schematic sectional drawing of a pachinko island stand. (Example 4) which is a schematic plan view which shows the arrangement | positioning relationship between an air deodorizing apparatus and an adsorption medium. (Example 4) which is a principal part schematic sectional drawing which shows the arrangement | positioning relationship between an air deodorizing apparatus and an adsorption medium. It is a schematic sectional drawing of the pachinko island stand which shows arrangement | positioning of an air deodorizing apparatus (Example 5). It is a schematic sectional drawing of the pachinko island stand which shows arrangement | positioning of an air deodorizing apparatus (Example 6).

Explanation of symbols

1, 1A, 1B, 1C, 121, 121A, 121B, 121C, 121D, 121E, 121F, 121G, 121H, 121I, 125, 127, 129, 133, 135, 137 Deodorant functional component-containing mist generator 3 Pachinko island stand 5 Membrane plate 5A Island rack 7 Display plate 11 Pachinko stand 13 Call lamp 15 Metal plate (adsorption medium)
17 Filter 19 Case 21 Air inlet 23 Air outlet 31 Sirocco fan (fan)
39 Mist Generator 41 Water Retention Base Material 43 Release Base Material 59 Porous Molded Body 61 Water Supply Means 63 DC High Voltage Power Supply 83 Generation Unit 91 Water Retention Base Material 93 Release Base Material 97 DC High Voltage Power Supply 103 Generation Unit 111 Generation Unit 113 Water Retention Base material 115 Discharge base material 117 Water supply means

Claims (8)

Air with a deodorizing and deodorizing device for cigarette smoke by applying a high voltage to an aqueous solution in which the deodorizing functional component is dissolved and discharging a mist containing the deodorizing functional component into the amusement hall by a discharge phenomenon Deodorizing device. The air deodorization device according to claim 1,
An air deodorizing apparatus comprising an adsorption medium capable of adsorbing the released deodorant functional component-containing mist. The air deodorization device according to claim 1 or 2,
An air deodorizing apparatus, wherein the adsorption medium includes a filter. It is an air deodorizing apparatus in any one of Claims 1-3,
The generating device is arranged in a game hall where a gaming machine island stand is installed,
The air deodorizing apparatus, wherein the adsorption medium is provided at an upper end portion of the gaming machine island stand. It is an air deodorizing apparatus in any one of Claims 1-4,
The generator is provided in a case,
The case is equipped with an air inlet and exhaust port, a fan for sucking air from the air inlet and exhausting it from the air outlet, and an air purifying filter for purifying and exhausting the sucked air. apparatus. It is an air deodorizing apparatus in any one of Claims 1-5,
The generating device is provided in any of a film board of a gaming machine island stand installed in a game arcade, a calling lamp mounting location of the gaming machine island stand, an upper end of the gaming machine island stand, or a gaming machine stand. Air deodorizer. It is an air deodorizing apparatus in any one of Claims 1-6,
The deodorizing functional ingredient is catechin, wood vinegar, bamboo vinegar, corn extract ingredient, vitamins, vitamin derivatives, catechin, hyaluronic acid, amino acids, organic soluble ingredients such as collagen, or inorganic substances such as silver or salt One type or two or more types of system soluble components. It is an air deodorizing apparatus in any one of Claims 1-7,
The generator includes a porous molded body having a water-absorbing property and a water-retaining property by projecting a porous release substrate on a porous water-retaining substrate, and the deodorizing functional component that is nonvolatile on the water-retaining substrate. A water supply means for holding an aqueous solution containing water, a DC high-voltage power source for negatively charging the porous molded body holding an aqueous solution containing a non-volatile deodorant functional component with a negative electrode connected to the porous molded body, and An air deodorizing apparatus characterized by comprising:

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