JP3241821U - air towel device - Google Patents

Abstract

The present invention provides an air towel device capable of rapidly removing water from wet hands after hand washing to dry the hands and at the same time releasing negative ions. A negative ion generator (5) is provided in an air towel device (1), and the negative ion generator includes an electrode housing portion (40), an electrode portion (41) provided in the electrode housing portion and constituted by a negative electrode and a counter electrode, and an electrode. and a high voltage generating section 42 which is spaced apart from the electrode section and applies a high voltage to the electrode section. A sensor 4 is provided near the air outlet 25 of the air towel device 1 . When the hand is brought close to the air outlet, the sensor senses and the hot air blown out from the air outlet hits the hand, and the negative ion generator generates negative ions, which are emitted outside the cabinet. I have to. [Selection drawing] Fig. 2

Description

The present invention relates to an air towel device.

In recent years, for example, an air towel device has been used as a means for removing moisture from wet hands when washing hands in washrooms in office buildings, factories, hospitals, and other facilities. It has become to. Such an air towel device is as shown in Patent Document 1, which includes a heating device for heating air, a fan for sending out air, an air outlet provided at the tip of the fan, Equipped with a drying section positioned below the air outlet and a water receiving section positioned below the drying section, warm air is sent to the fan when a wet hand after washing is inserted into the drying section. is blown out from an air outlet, and the hand is dried while blowing away the moisture adhering to the hand with the hot air that has flowed out.

JP-A-2000-139768

However, in the case of a general air towel device as shown in Patent Document 1, although it can remove moisture from wet hands after washing, it has no added value other than that. do not have. Therefore, the applicant of the present application has been investigating whether it is possible to give an added value beneficial to the human body to the air towel device. Negative ions are known as atoms and molecules in the air that acquire electrons and are negatively charged. Negative ions reduce stress, have a relaxing effect, improve the air environment, and moisturize the skin. It has various effects such as increase in weight, acceleration of metabolism in the body, strengthening of immunity and resistance to disease. Therefore, if the air towel device can emit negative ions, it is possible to dry the hands after washing hands and at the same time enjoy the beneficial effects of negative ions on the body.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an air towel device that can quickly remove and dry moisture from wet hands after hand washing and simultaneously enjoy the effects of negative ions.

In order to solve the above-mentioned problems, the present invention provides a cabinet formed in a box shape and provided with an air outlet on the lower side, a hot air blowing means provided in the cabinet, and a negative ion generator provided in the cabinet. and a sensor provided near the air outlet, wherein the warm air blowing means includes a heater for heating air, a blower having a fan for blowing out the air heated by the heater, and a blower for rotating the blower. It consists of a motor and an air lead-out passage that guides heated air to the air outlet, and the negative ion generator is composed of an electrode housing portion, and a negative electrode and a counter electrode provided in the electrode housing portion. The sensor comprises an electrode section and a high voltage generating section that is spaced apart from the electrode section and applies a high voltage to the electrode section. approaching the cabinet, the sensor senses the hot air blown out from the air outlet and hits the hand, and negative ions are generated from the negative ion generator and emitted to the outside of the cabinet. is characterized by

Further, in the present invention, a blowing means may be provided in the cabinet for discharging the negative ions generated by the negative ion generator to the outside.

Furthermore, in the present invention, at least the electrode portion of the negative ion generator may be arranged in the air lead-out passage.

Further, in the present invention, a housing case body for housing the negative ion generator inside is provided, the housing case body is arranged in the vicinity of the air lead-out passage, and an opening formed in the case body allows the air to flow. It may be communicated with the lead-out passage.

Furthermore, in the present invention, the negative electrode and the counter electrode may be attached to an electrode-fixing substrate, and the electrode-fixing substrate may be formed of a ceramic substrate.

Furthermore, in the present invention, the counter electrode may be arranged to surround the negative electrode.

Further, in the present invention, a dielectric may be provided between the counter electrode and the negative electrode to insulate the two.

Further, in the present invention, the dielectric is formed in a cylindrical shape, the counter electrode is formed in a cylindrical shape located on the outer periphery of the dielectric, and the negative electrode protrudes from the center of the dielectric. It may be formed in a needle-like shape.

Furthermore, in the present invention, the dielectric may be formed of a ceramic substrate.

According to the air towel device of the present invention, it is possible to quickly remove and dry moisture from wet hands after hand washing, and at the same time, enjoy the effects of negative ions.

The external perspective view of an air towel apparatus. FIG. 2 is a front view of the air towel device with the cover body removed; Side view of the air towel device. The side view of an air blowing means. The perspective view of an electrode accommodating part. Front cross-sectional view of the electrode accommodating portion. Schematic diagram of a high voltage generator. FIG. 11 is a front view of an air towel device with a cover body removed according to another embodiment; FIG. 11 is a front view of an air towel device with a cover body removed according to another embodiment; FIG. 10 is a perspective view of another embodiment of the electrode accommodating portion; FIG. 10 is a cross-sectional view of another embodiment of the electrode accommodating portion; FIG. 10 is a vertical cross-sectional view of another embodiment of the electrode accommodating portion; FIG. 10 is a vertical cross-sectional view of another embodiment of the electrode accommodating portion;

BEST MODE FOR CARRYING OUT THE INVENTION An air towel device according to the present invention will be described below with reference to the drawings. 1 is an external perspective view of an air towel device according to this embodiment, FIG. 2 is a front sectional view of the air towel device according to this embodiment, and FIG. 3 is a side view of the air towel device according to this embodiment. The air towel device 1 according to this embodiment includes a box-shaped cabinet 2, an air blowing means 3, a sensor 4, and a negative ion generator 5 provided in the cabinet 2, and an ultraviolet ray detector provided at the lower end of the cabinet 2. It is roughly configured with a germicidal lamp 6 . The terms "front", "front", "rear", "back", "right", "left", "up", and "lower" in this embodiment refer to the air towel device 1 shown in FIG. is used as a reference.

The cabinet 2 is made of metal, and is configured such that a rectangular box-shaped container body 10 and a rectangular box-shaped cover body 11 attached to the container body 10 are combined to form a space inside. It is Outer dimensions of the container body 10 are set to 275 mm long, 316 mm wide and 40 mm deep, and the outer dimensions of the cover body 11 are set to 280 mm long, 314 mm wide and 96 mm deep.

A container body 10 of the cabinet 2 is provided with an air blowing means 3, which will be described later, on the right half thereof. A control board 12 and a motor board 13 are arranged on the left half of the container body 10, and a heater changeover switch 14 and an inverter changeover switch 15 are provided. Further, on the left side of the control board 12, a buzzer switch 16, an operation timer 17, an intermittent timer 18, and a sensor adjustment 19 are provided. A power cord port 20 is provided on the upper left side of the container body 10, and a power switch 21 is provided slightly below it. At the lower end of the container body 10, there is formed a lamp receiving portion 23 which has an upper wall portion 23a, a rear wall portion 23b, left and right side wall portions 23c, 23c, and is recessed so that the front side and the lower side are open. , where the ultraviolet germicidal lamp 6 is arranged. The ultraviolet germicidal lamp 6 used here has a power of 6 W, and the wavelength of the ultraviolet rays emitted from it can be set in the range of 200 to 280 nm (nanometers), that is, in the range of short-wave ultraviolet rays. there is This short-wave ultraviolet light has a strong sterilizing effect, and in particular, ultraviolet light with a wavelength of 253.7 nm has the strongest sterilizing effect.

The cover body 11 of the cabinet 2 is formed with an air outlet 25 opening in the shape of a horizontally elongated slit as shown in FIG. Further, a plurality of horizontally elongated holes 26, 26, .

The blower means 3 includes an electric heater 30 that heats air, a blower 31 that blows out the air heated by the electric heater 30, a motor 32 that rotates the blower 31, and guides the heated air to the air outlet 25. and an air lead-out passage 33 . Among these, the blower 31 is formed by providing a fan 36 in a circular case body 35 fixed slightly above the center of the right half of the container body 10. The fan 36 used here is a so-called sirocco type is adopted. A motor 32 for rotating the fan 36 is arranged in the center of the fan 36 . A high voltage brushless motor is adopted as the motor 32 used here, and a rotational speed of 7200 rpm can be obtained. Further, a circularly-opened intake port 37 is formed in the center of the front surface of the case body 35 so that air can be taken into the case body 35 . A first air lead-out passage 33a communicating downward is formed at the left end of the case body 35, and a second air lead-out passage 33b is connected to the lower end of the first air lead-out passage 33a. . An electric heater 30 is arranged in the second air lead-out passage 33b. The temperature of the electric heater 30 can be switched between 131.degree. C. and 115.degree. That is, the temperature can be set to 131° C. in seasons or places where the temperature is low, and can be set to 115° C. in seasons or places where the temperature is high. The lower end of the second air lead-out passage 33b is slightly bent forward and positioned to face the air outlet 25 opened in the cover body 11. As shown in FIG.

A sensor 4 is fixed to the front portion of the lower end of the air lead-out passage 33 . This sensor 4 employs an optical electronic sensor that senses a hand when it approaches the air outlet 25. - 特許庁In addition, the sensor 4 can set the distance from the hand that triggers the operation of the sensor 4 to a range of 0 to 20 cm by the sensor adjustment 19 described above. That is, the distance from the hand sensed by the sensor 4 can be freely adjusted according to the situation such as the installation location of the air towel device 1 . Incidentally, the wind speed of the hot air blown out from the air outlet 25 can be set in the range of 35 to 65 m/s by the air volume volume 22, and is normally set at 50 m/s.

The negative ion generator 5 is provided inside the container body 10 of the cabinet 2 . Specifically, the negative ion generator 5 shown in this embodiment is provided slightly below the lower end of the case body 35 of the air blowing means 3 . The negative ion generator 5 includes an electrode accommodating portion 40, an electrode portion 41 provided in the electrode accommodating portion 40, and a high voltage generator which is provided apart from the electrode portion 41 and applies a high voltage to the electrode portion 41. and a portion 42 .

The electrode housing portion 40 is provided slightly below the lower end of the case body 35 of the air blowing means 3 . As shown in FIGS. 5 and 6, the electrode housing portion 40 is a rectangular parallelepiped with a hollow interior, and is constructed by combining two box-shaped halves 40a and 40b. Further, the electrode housing portion 40 in this embodiment is formed of a ceramic nonflammable material. This enhances the safety of the negative ion generator 5 itself, which applies a high voltage of several thousand volts. Furthermore, the electrode accommodating portion 40 in which the box-shaped halves 40a and 40b are combined has openings 45 extending from the center of the front surface to the left and right side surfaces thereof. An electrode portion 41 is provided inside the electrode accommodating portion 40 . The electrode portion 41 is formed by attaching a negative electrode 47 and a counter electrode 48 to a rectangular plate-shaped electrode fixing substrate 46 . Of these, the negative electrode 47 is a plate-shaped member formed by stamping a metal plate by press working. A lead wire 49 connected to the high voltage generator 42 can be connected. Attachment pieces (not shown) formed by bending at right angles are provided at both central ends of the negative electrode 47 , and these attachment pieces are attached to attachment slits (not shown) formed in the electrode fixing substrate 46 . (not shown)), the negative electrode 47 is attached to the electrode fixing substrate 46 . On the other hand, like the negative electrode 47, the counter electrode 48 is a member formed into a rectangular plate by punching a metal plate by press working, and a lead wire 50 connected to the high voltage generator 42 is connected to the lower end side thereof. It's like Attachment pieces (not shown) formed by bending at right angles are formed on both side ends of the counter electrode 48 , and these attachment pieces are attached to attachment slits formed in the electrode fixing substrate 46 . (not shown), the counter electrode 48 is attached to the electrode fixing substrate 46 . In addition, the negative electrode 47 and the counter electrode 48 are arranged on the electrode-fixing substrate 46 with a certain distance therebetween. In addition, since the negative electrode 47 and the counter electrode 48 are positioned so as to face the opening 45 of the electrode housing portion 40 , when it becomes necessary to clean the negative electrode 47 and the counter electrode 48 , a brush or the like is placed in the opening 45 . It can be easily cleaned by aligning it. Incidentally, the electrode-fixing substrate 46 described above is made of ceramic. As a result, it is possible to avoid the problem of accumulation of negative charges in the electrode fixing substrate 46 .

As described above, an example in which both the electrode housing portion 40 and the electrode fixing substrate 46 are made of ceramic is shown here as a suitable example, but they do not necessarily have to be made of ceramic. do not have. Further, as described above, the negative electrode 47 and the counter electrode 48 can be easily and efficiently formed by punching a metal plate, and thus the manufacturing cost can be reduced. Molding is of course also possible.

As shown in FIG. 2, the high voltage generating section 42 is provided below the lower end of the case body 35 of the air blowing means 3 at a predetermined distance from the electrode accommodating section 40 described above. The high voltage generating section 42 generates a high voltage and applies it to the negative electrode 47 and the counter electrode 48 of the electrode section 41 . The high-voltage generator 42 is provided inside a container 55 made of resin. Incidentally, the container 55 is made of insulating resin. Here, looking at the structure of the high voltage generating section 42 in detail, as shown in FIG. there is Of these, the half-wave rectifier circuit 56 half-wave rectifies the AC 100 V of the commercial power supply, and the pulse generator circuit 57 converts the current rectified by the half-wave rectifier circuit 56 into a pulse current. . Further, the transformer 58 transforms the pulse current converted by the pulse generation circuit 57 into a high voltage. The half-wave rectifier circuit 56 is implemented by a diode 59 interposed between the transformer 58 and the electrode portion 41 .

Next, how to use the air towel device 1 configured as described above will be described. First, in using the air towel device 1, the power switch 21 provided on the left side of the container body 10 of the cabinet 2 is turned on. As a result, the air towel device 1 can be used at all times. When a person who has washed his/her hands brings his wet hand closer to the air outlet 21 of the air towel device 1, the sensor 4 senses the hand. As a result, the electric heater 30 is heated to a predetermined temperature, and the motor 32 is driven to operate the fan 36 . As a result, the air heated to a predetermined temperature flows out from the air outlet 25 at a blowing speed of 50 m/s and hits the hands, and the moisture on the wet hands is blown away by the wind force, and the moisture is evaporated by the hot air. It will dry your wet hands in a short time.

Further, in this air towel device 1, the sensing of the sensor 4 causes the ultraviolet germicidal lamp 6 to light up and generates negative ions. That is, when the sensor 4 senses a hand brought close to the air outlet 25, the ultraviolet germicidal lamp 6 is turned on. When the ultraviolet germicidal lamp 6 is turned on, the hands are irradiated with short-wave ultraviolet rays from the ultraviolet germicidal lamp 6, so that the sterilization power kills all germs and viruses adhering to the hands. . In the above-described method of use, when a person approaches the air outlet 21 with his or her hand, the sensor 4 senses this to turn on the ultraviolet germicidal lamp 6. However, the power switch of the air towel device 1 It is also possible to set so that the ultraviolet germicidal lamp 6 is always lit after turning on the lamp 21 . In this case, even if a person does not use the air towel device 1, as long as the power switch 21 of the air towel device 1 is turned on, the short-wave UV rays will continue to irradiate the surroundings. , bacteria and viruses existing around the air towel device 1 can be killed in advance. Further, on the premise that the power switch 21 of the air towel device 1 is turned on, it is also possible to set the ultraviolet germicidal lamp 6 to light up at regular time intervals. In this case, while saving the electric power consumed by the ultraviolet germicidal lamp 6, various bacteria and viruses existing around the air towel device 1 can be exterminated in advance.

Furthermore, when the sensor 4 senses the hand of the user of the air towel device 1, the negative ion generator 5 is activated to emit negative ions from the air towel device 1 to the outside. That is, when the sensor 4 senses a hand, the current after half-wave rectification by the half-wave rectification circuit 56 of the high voltage generator 42 of the negative ion generator 5 is received, and the pulse generation circuit 57 operates. Then, the pressure due to the piezoelectric vibration caused by the pulse current converted by the pulse generation circuit 57 is applied to the transformer 58, a high voltage is generated from the transformer 58, and the negative electrode 47 is caused to generate a high voltage of several thousand volts. Here, since the counter electrode 48 is set to 0 volts, a sudden potential difference is generated with respect to the counter electrode 48 . Therefore, negative ions are emitted from the tip of the negative electrode 47 toward the counter electrode 48 . That is, since the tip of the negative electrode 47 is a sharply sharpened protrusion, when the voltage reaches several thousand volts, it discharges into the air. Then, the discharged negative charges ionize oxygen in the air, and eject negative ions toward the front of the electrode portion 41 . Then, when the negative ion generator 5 emits negative ions, the negative ions are emitted outside from the horizontally elongated holes 26, 26, . . . As a result, negative ions are present in the air around the person using the air towel device 1, and in addition to the inherent effect of the air towel device 1 of drying hands, the relaxation obtained by the negative ions is achieved. effects can be obtained at the same time.

Although not shown, a blowing means such as a blade rotated by a motor is provided near the negative ion generator 5, and the wind generated by this blade is directed toward the electrode portion 41 of the negative ion generator 5. Thereby, the negative ions generated from the negative ion generator 5 may be diffused. With this configuration, the negative ions emitted from the negative ion generator 5 are efficiently diffused into the container body 10, and are also efficiently emitted from the oblong holes 26, 26, . . . Therefore, it is possible to enjoy the effects of releasing negative ions, such as relaxing effects.

FIG. 8 shows another embodiment in which the location of the negative ion generator 5 is modified. Since the configuration is the same as that of the above-described embodiment except for the position where the negative ion generator 5 is arranged, the same reference numerals as those of the above-described embodiment will be used for description. In the embodiment shown in FIG. 8, the negative ions generated by the negative ion generator 5 of the above embodiment are more effectively released to the outside. Specifically, of the electrode portion 41 and the high voltage generating portion 42 in the negative ion generator 5 , only the electrode portion 41 is formed so as to be located inside the second air lead-out passage 33 b of the air blowing means 3 . That is, as shown in FIG. 8, the electrode portion 41 provided inside the electrode accommodating portion 40 is arranged in the second air lead-out passage 33b and on the upper right side of the electric heater 30. As shown in FIG. The high voltage generator 42 is arranged outside the second air lead-out passage 33b and below the air blower 3. As shown in FIG. Lead wires 49 and 50 extending from the electrode portion 41 are led to the outside from insertion holes (not shown) formed in the second air lead-out passage 33b and connected to the high voltage generating portion 42. there is Therefore, when a person brings his or her hand close to the air outlet 21 and the sensor 4 senses it, the current after half-wave rectification by the half-wave rectification circuit 56 of the high voltage generator 42 of the negative ion generator 5 is received and pulsed. The generation circuit 57 is activated, and pressure is applied to the transformer 58 by piezoelectric vibration caused by the pulse current converted by the pulse generation circuit 57 . Then, a high voltage is generated from the transformer 58 to generate a high voltage of several thousand volts in the negative electrode 47 , and a sudden potential difference is generated with respect to the counter electrode 48 . It shoots negative ions towards you. As a result, the negative ions generated by the negative ion generator 5 are carried by the air blown out by the fan 36 of the air blowing means 3 in the second air lead-out passage 33b and are discharged outside from the air outlet 25. It will be. That is, in this embodiment, since the negative ions are emitted from the air outlet 25 while utilizing the wind current of the fan 36 of the air blowing means 3, the negative ions can be emitted to the outside more efficiently. In particular, the negative ions carried from the second air lead-out passage 33b and emitted from the air outlet 25 directly hit the hands of the person using the air towel device 1, so they are given to the body as follows. Beneficial effects can be expected. Specifically, negative ions are expected to have the effect of purifying the blood, increasing gamma globulin in the blood, and enhancing the resistance and immunity of the body. Therefore, direct contact with negative ions can provide these effects, which in turn leads to health promotion.

In the embodiment described in the preceding paragraph, only the electrode part 41 of the negative ion generator 5 is provided inside the lead-out passage 33 of the air blowing means 3. is intended to secure a passage for the air blown out from the fan 36. However, even if not only the electrode portion 41 but also the high voltage generating portion 42 are provided in the lead-out passage 33, the object itself of the present invention can be achieved. That is, for example, if the lead-out passage 33 of the air blowing means 3 is expanded so that the high voltage generator 42 can be arranged in the passage 33, the above effects can be obtained.

FIG. 9 shows another embodiment modified so that the negative ion generator 5 can be attached and detached easily. Since the configuration of the negative ion generator 5 of this embodiment is mostly the same as that of the above-described embodiment, only the portions that differ from the above-described embodiment are denoted by new reference numerals, and the portions that have the same configuration as those of the above-described embodiment are denoted by new reference numerals. Description will be made using the same reference numerals as in the example. The embodiment shown in FIG. 9 shows an example in which the negative ion generator 5 is provided inside the housing case body 65 . The storage case body 65 is detachably provided slightly below the lower end of the case body 35 of the blowing means 3 and near the second air lead-out passage 33b of the blowing means 3 . Here, the storage case body 65 has a hollow interior and is configured by combining two box-shaped halves. A plurality of locking portions (not shown) are formed around the housing case 65. These locking portions are fitted with locking claws 66, 66, . . . can be attached to the container body 10 in a one-touch manner. One side (the left side in FIG. 9) of the storage case body 65, specifically, the side located in the second air lead-out passage 33b of the air blowing means 3, is a narrow portion 65a. An electrode portion 41 stored in the housing portion 40 is arranged. On the other hand, the other side (the right side portion in FIG. 9) of housing case 65 is wider than the narrow width portion, and high voltage generator 42 housed in housing body 55 is arranged here. That is, the negative ion generator 5 in this embodiment is provided with the electrode portion 41 on the narrow width portion 65a on the right side of the storage case body 65 provided separately from the container body 10 of the cabinet 2, and the wide width portion on the left side of the storage case 65. A high voltage generating section 42 is provided at 65b at a predetermined distance from the electrode section 41 . Furthermore, although not shown, an opening is formed at the left end of the narrow portion of the storage case 65, and the opening of the storage case 65 is aligned above the right side of the second air lead-out passage 33b. A passage opening is formed at a position, and the opening of the storage case 65 and the passage opening of the second air lead-out passage 33b communicate with each other. The electrode portion 41 provided on the narrow portion 65 a of the storage case body 65 is provided so that the tip 47 a of the negative electrode 47 faces the opening of the storage case body 65 . Since the tip 47 a of the negative electrode 47 of the electrode portion 41 faces the opening of the housing case body 65 in this manner, the negative ions generated by the negative ion generator 5 are emitted from the opening of the housing case body 65 . The air is discharged toward the passage opening of the second air outlet passage 33b communicating with the unit, guided to the second air outlet passage 33b, and further inside the second air outlet passage 33b by the fan 36 of the air blowing means 3. It is carried by the blown air and discharged from the air outlet 25 to the outside. That is, in this embodiment as well, since the negative ions are emitted from the air outlet 25 while utilizing the wind current of the fan 36 of the air blowing means 3, the negative ions can be efficiently emitted to the outside, and the negative ions can be emitted by the air. The towel device 1 can be applied directly to the user's hand. In addition, since the negative ion generator 5 is arranged inside the housing case body 65, the problem of dust or the like adhering to the electrode portion 41 can be reduced. Furthermore, since the storage case body 65 is detachably attached to the container body 10 of the air towel device 1, it can be handled like a unit component when assembling the air towel device 1. Manufacturing work efficiency can be improved. Further, when it becomes necessary to clean the negative electrode 47 and the counter electrode 48 of the negative ion generator 5 , the storage case body 65 is once removed from the container body 10 , and a brush or the like is removed from the opening 67 of the storage case body 65 . can be inserted and cleaned easily.

10 to 12 show modifications of the electrode portion of the negative ion generator 5. FIG. In the electrode part 70 of this embodiment, a thin plate-like electrode fixing substrate 72 is mounted in an electrode accommodating part 71 which is formed in the shape of a hollow rectangular parallelepiped. 74 is provided and formed. Specifically, as shown in FIGS. 10 to 12, two box-shaped halves 71a and 71b made of synthetic resin are joined together to form a hollow rectangular parallelepiped electrode accommodating portion 71. are doing. A negative ion emission opening 75 is formed at the left end of the electrode housing portion 71 . Further, an electrode fixing substrate 72 is fixed inside the electrode accommodating portion 71 so as to be sandwiched between the box-shaped halves 71 a and 71 b forming the electrode accommodating portion 71 . Therefore, the electrode fixing substrate 72 is positioned at the central portion of the electrode accommodating portion 71 in the front-rear direction. The electrode-fixing substrate 72 in this embodiment is made of ceramic, and the central portion of the left end of the electrode-fixing substrate 72 is notched inward in a concave shape. Each piece portion other than the notch serves as the opposing electrodes 74 , 74 . A needle-shaped negative electrode 73 is provided between the opposing electrodes 74 and 74 in the recessed center portion of the electrode fixing substrate 72 . A high voltage generated by the high voltage generator 42 is applied to the negative electrode 73 and the counter electrodes 74 , 74 to generate negative ions and emit them from the negative ion emission opening 75 . Reference numerals 76 and 77 in FIG. 11 denote lead wires. By configuring the negative ion generator 5 as in this embodiment, the configuration of the negative ion generator 5 itself can be simplified, so that the assembly is facilitated and the manufacturing cost can be reduced. can be obtained.

The negative ion generator 5 having the electrode section 70 described above may be provided inside the container body 10 of the cabinet 2 slightly below the lower end of the case body 35 of the air blowing means 3, as in the other embodiments. However, it is also possible to provide it in the second air lead-out passage 33b. Further, the aforementioned passage opening is formed in the second air lead-out passage 33b, and the negative ion emission opening 75 of the electrode housing portion 71 of the electrode portion 70 is installed so as to face the passage opening of the second air lead-out passage 33b. is also possible.

FIG. 13 shows yet another modification of the electrode portion of the negative ion generator 5. As shown in FIG. The electrode part 80 in this embodiment is provided with an electrode support 82 inside an electrode housing part 81 which is hollow inside and formed in the shape of a box whose left side is open. An electrode 84 is provided and formed. Specifically, as shown in FIG. 13, the bottom surface of a bottomed cylindrical electrode support 82 is fixed to the inner surface of the right side surface of a box-shaped electrode housing portion 81 made of synthetic resin. Therefore, the fixed electrode support 82 is in a state in which the opening side of the electrode accommodating portion 81 is open. The electrode support 82 is made of insulating synthetic resin, ceramic, or the like. A negative electrode 83 penetrates through the center of the bottom surface of the electrode support 82 , and the tip of the negative electrode 83 extends toward the opening of the electrode accommodating portion 81 . The negative electrode 83 is made of tungsten having a low discharge resistance, and has a pointed projection 83a at its tip. A lead wire 49 is connected to the other end of the negative electrode 83 to be connected to the high voltage generator electrode portion 42 . Furthermore, a counter electrode 84 is attached to the outer peripheral portion of the electrode support 82 . Specifically, the counter electrode 84 is formed in a ring shape, and a plurality of protrusions 84, 84, . . . are formed on one end side thereof. The counter electrode 84 is fitted to the electrode support 82 so as to surround the outer periphery of the electrode support 82 . A lead wire 50 connected to the high voltage generator electrode portion 42 is connected to the other end of the counter electrode 84 . Incidentally, the tip of the negative electrode 83 is located inside the tip of the electrode support 82 (the left end in FIG. 14). This is to prevent the negative electrode 83 and the counter electrode 84 from sparking each other, and by doing so, negative ions can be effectively generated. Although the example in which the negative electrode 83 is made of tungsten is shown in this embodiment, it is of course possible to make the negative electrode 83 of another metallic material without being limited to this. Similarly, for the counter electrode 84, various metal materials can be selected.

The negative ion generator 5 having the electrode section 80 described above may be provided inside the container body 10 of the cabinet 2 slightly below the lower end of the case body 35 of the air blowing means 3 as in the other embodiments. However, it is also possible to provide it in the second air lead-out passage 33b. Further, it is also possible to form the above-described passage opening in the second air lead-out passage 33b and install the opening of the electrode accommodating portion 81 of the electrode portion 80 so as to face the passage opening of the second air lead-out passage 33b. be.

1 Air towel device 2 Cabinet 3 Warm air blowing means 4 Sensor 5 Negative ion generator 25 Air outlet 30 Heater 31 Air blower 32 Motor 33 Air lead-out passage 36 Fan 40 Electrode housing 41 Electrode 42 High voltage generator

Claims (9)

A cabinet formed in a box shape and provided with an air outlet on the lower side, a warm air blower provided in the cabinet, a negative ion generator provided in the cabinet, and provided near the air outlet. a sensor and
The hot air blowing means includes a heater that heats air, a blower that has a fan that blows out the air heated by the heater, a motor that rotates the blower, and air that guides the heated air to the air outlet. and a lead-out passage,
The negative ion generator includes an electrode accommodating portion, an electrode portion provided in the electrode accommodating portion and configured by a negative electrode and a counter electrode, and a high voltage applied to the electrode portion provided apart from the electrode portion. and a high voltage generator,
The sensor is provided near the air outlet,
When the hand is brought close to the air outlet, the sensor senses and the hot air blown out from the air outlet hits the hand, and the negative ion generator generates negative ions and emits them to the outside of the cabinet. An air towel device characterized by being made to be. 2. An air towel apparatus according to claim 1, wherein said cabinet is provided with air blowing means for discharging the negative ions generated by said negative ion generator to the outside. 2. The air towel device according to claim 1, wherein at least an electrode portion of said negative ion generator is arranged in said air lead-out passage. A housing case body for housing the negative ion generator inside is provided, the housing case body is arranged in the vicinity of the air lead-out passage, and an opening formed in the case body communicates with the air lead-out passage. 2. The air towel device of claim 1, wherein a. 2. The air towel device according to claim 1, wherein said negative electrode and said counter electrode are attached to an electrode-fixing substrate, and said electrode-fixing substrate is formed of a ceramic substrate. 2. The air towel device according to claim 1, wherein said counter electrode is arranged so as to surround said negative electrode. 7. The air towel device according to claim 6, wherein a dielectric is provided between said counter electrode and said negative electrode for insulation and isolation between the two. The dielectric is formed in a cylindrical shape, the counter electrode is formed in a cylindrical shape located on the outer periphery of the dielectric, and the negative electrode is formed in a needle shape protruding from the center of the dielectric. 8. The air towel device of claim 7, wherein the air towel device is 9. The air towel device of claim 8, wherein said dielectric is formed from a ceramic substrate.

Images