JP2003279089A - Minus ion generating part - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To produce a space where bio metabolic functions and physiologic functions are not depressed by generating ozon-less minus ions in an indoor space, and also to provide a stable space by generating minus ions to electrically neutralize or negatively charge fine particles and the likes. <P>SOLUTION: A photoelectron emission member 47 and an irradiation source 48 are provided to generate minus ions by irradiating ultraviolet rays from the irradiation source 48 to the photoelectron emission member 47. A minus ion generating part 49 provided near an air outlet port 33 for discharging air from a main body of device to atmosphere efficiently diffuses minus ions generated by the minus ion generating part 49 to the whole room by utilizing air flow from the air outlet port 33. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a negative ion for purifying and deodorizing dirty air and odorous air sucked in a room.

[0002]

2. Description of the Related Art A conventional air conditioner having a negative ion generating portion of this type is constructed as shown in FIGS. The configuration will be described below.

As shown in FIGS. 18 to 20, an air conditioner body 1 has an intake port 2 and an exhaust port 3, a partition wall 4 is provided inside, and a vortex chamber 5 is provided at the rear part of the partition wall 4. There is. The swirl chamber 5 surrounds an electric blower including a motor 6 and a fan 7, and opens toward the exhaust port 3. A suction port 8 and a rib 9 are provided on the front surface of the partition wall 4, and the rib 9 supports a filter 10 including an activated carbon filter for deodorization and a charging filter for dust collection arranged on the front surface. The suction port 8 communicates with the electric blower in the air conditioner body 1. The changeover switch unit 11 has a control circuit unit inside and can be operated by the changeover switch unit 11. Reference numeral 12 is a negative ion generator including a high voltage generator 13, a discharge electrode 14 and a ground electrode 15.

In the above structure, the changeover switch unit 1
When the electric blower is rotated by 1, the air in the room is sucked in through the intake port 2. Filter 1 for sucked air flow
After passing 0, the air is purified, deodorized, and exhausted from the exhaust port 3. Further, the negative ions are generated by the discharge generated between the discharge electrode 14 and the ground electrode 15, and are diffused and released into the room along with the air flow exhausted from the exhaust port 3.

[0005]

However, in the above-mentioned conventional negative ion generator, since the negative ions are generated by the discharge, the high voltage generator 13 is required, which is expensive and costly. Further, since high voltage electricity is used, there is a safety problem, and at the same time, there is a safety problem due to ozone generated. The presence of a large amount of ozone in the air is extremely harmful to health, and when the amount of ozone exceeds 10 ppm, various disorders occur in the human body. Therefore, when the electrostatic dust collection method is used for air purification, the amount of ozone is limited to a certain limit, preferably 5
It is desired to maintain around ppm.

That is, conventionally, as a method of generating negative ions, a method of applying a negative high voltage by corona discharge to the electrode has been known, but this method has a problem that high voltage electricity is used. .

On the other hand, at present, there is a demand for a comfortable indoor space that does not impair the metabolic and physiological functions of the living body and is closer to the natural world. For example, in the field of semiconductors, a work space where there is no fear of generation of + static electricity is required, and excess cations are neutralized. In the current indoor space, positive (plus),
Negative (negative) ions are present, but positive (plus) ions are often excessive due to life content and natural phenomena.

That is, 1. Negative (negative) ions are extremely reduced in a closed room. 2. Normal airborne particles are positively charged by the air flow. 3. In the room, there are many particles and air molecules that are positively charged due to space discharge from a high-voltage power source such as a TV and molecular friction when people move.

[0009] In such an atmosphere, the living body has a drawback that metabolism is deteriorated and physiological function is deteriorated.

That is, it is said that, in the case of a living body, for example, the human body, a change in physical condition occurs when the negative (minus) ions decrease.

The human body is composed of an innumerable number of cells, and each cell is surrounded by a cell membrane, and the cells carry out their activities by absorbing nutrients and discharging waste products through the membrane. These cells have positive (plus) ions on the outside and negative (minus) ions on the inside, and when the negative (minus) ions decrease and the positive (plus) ions become excessive, it is difficult to absorb nutrients and discharge waste products. It is said that the following phenomena occur, metabolism is deteriorated, and physiological functions deteriorate.

The present invention solves the above-mentioned problems. It sucks in dirty air and odorous air in the room, purifies and deodorizes it, promotes safety and cost reduction, and creates ozoneless shadow (minus) in the indoor space. A space that does not impair the metabolic and physiological functions of the living body is created by generating ions, and negative ions are generated to electrically neutralize fine particles and give a negative charge to a stable space. The purpose is to provide.

[0013]

In order to solve the above-mentioned problems, the present invention comprises a photoelectron emitting material and an irradiation source, and the photoelectron emitting material is irradiated with ultraviolet rays from the irradiation source to generate negative ions. In addition, it is a negative ion generating portion provided in the vicinity of the exhaust port that releases air from the device body to the atmosphere.

According to the above invention, ozoneless negative (negative) ions are generated by irradiating the photoelectron emitting material with ultraviolet rays from the irradiation source, and the negative ions are released into the atmosphere. By providing the negative ion generating portion in the vicinity of the exhaust port, the negative ions can be diffused throughout the room by being placed in the airflow exhausted into the room through the exhaust port, and the negative ions can be generated to generate fine particles and the like. It is possible to provide a stable indoor space by electrically neutralizing or carrying a negative charge. Further, according to the above invention, the negative ions generated in the negative ion generation unit can be efficiently diffused in the entire room by being placed on the air flow from the exhaust port.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION The invention according to claim 1 of the present invention is
A photoelectron emission material and an irradiation source are provided, and the photoelectron emission material is irradiated with ultraviolet rays from the irradiation source to generate negative ions, and is provided in the vicinity of an exhaust port for discharging air from the device body to the atmosphere. It is a negative ion generator.

According to the above invention, ozoneless negative (minus) ions are generated by irradiating the photoelectron emitting material with ultraviolet rays from the irradiation source, and the negative ions are released into the atmosphere. By providing the negative ion generating portion in the vicinity of the exhaust port, the negative ions can be diffused throughout the room by being placed in the airflow exhausted into the room through the exhaust port, and the negative ions can be generated to generate fine particles and the like. It is possible to provide a stable indoor space by electrically neutralizing or carrying a negative charge. Further, according to the above invention, the negative ions generated in the negative ion generation unit can be efficiently diffused in the entire room by being placed on the air flow from the exhaust port.

According to a second aspect of the present invention, the equipment main body is provided with an electric blower having a suction action, and is a negative ion generating portion arranged upstream of the electric blower. Further, according to the above-mentioned invention, since the air current before being warmed by the electric blower can be applied to the ultraviolet lamp in the same manner as described above, the ultraviolet lamp can be effectively cooled.

According to a third aspect of the present invention, the equipment main body is provided with an electric blower having a suction action, and is a negative ion generating portion arranged on the downstream side of the electric blower. Further, according to the above-mentioned invention, a large number of negative ions generated in the negative ion generation unit tend to collide with the main body wall surface or the structure and decrease, but the negative ion generation unit is not included in the electric blower without the filter or the electric blower. By arranging on the downstream side on the side of the blowing air near the exhaust port, the reduction of negative ions can be suppressed to the maximum, and a larger number of negative ions can be emitted from the exhaust port.

According to a fourth aspect of the present invention, the photoelectron emitting material is made of a metal material and is subjected to a surface treatment having an Au layer on at least the inner surface. Further, according to the above-mentioned invention, the surface-treated photoelectron emitting material having the Au layer on the inner surface that wraps around the ultraviolet lamp as the irradiation source at a uniform distance is irradiated with ultraviolet light having a uniform irradiation intensity. , Can generate a large number of negative ions stably.

In a fifth aspect of the present invention, the photoelectron emitting material is made of one of materials selected from brass, bronze and phosphor bronze. Further, according to the above invention, the surface treatment having excellent conductivity and having the Au layer such as plating and vapor deposition can be easily performed.

According to a sixth aspect of the present invention, the photoelectron emitting material is cylindrical, and is made of Au plating or vapor deposition.
A plate material before being bent into a cylindrical shape is subjected to the above-mentioned plating or vapor deposition surface treatment. Further, according to the above-mentioned invention, since it is a plate material before being bent into a cylindrical shape, that is, a sheet shape, surface treatment processing such as plating and vapor deposition can be easily performed.

According to a seventh aspect of the present invention, the photoelectron emitting material is cylindrical, and is made of Au plating or vapor deposition.
The surface is treated by plating or vapor deposition after bending into a cylindrical shape. Then, according to the above invention, by subjecting the surface treatment such as plating or vapor deposition after bending into a cylindrical shape, a metal mold often generated during bending,
It is possible to prevent scratches on the surface of the photoelectron emitting material that has been surface-treated with a jig or tool.

According to the eighth aspect of the present invention, the shape of the photoelectron emitting material is one selected from a cylinder, a polygonal tube, a mesh tube, a fibrous (cotton) tube, and a bellows tube. It consists of According to the above invention, the Au surface is wrapped around the UV lamp, which is the irradiation source, at a uniform distance.
By irradiating the surface-treated photoemissive material of each shape having a layer of
It is possible to stably generate a large number of negative ions.

According to the ninth aspect of the present invention, the ultraviolet irradiation intensity of the irradiation source is varied to control the amount of negative ions generated. According to the above invention, the amount of negative ions generated can be changed by changing the ultraviolet irradiation intensity of the irradiation source according to the use environment and state.

According to the tenth aspect of the present invention, the negative ion generation amount is controlled in response to the value detected by the ion detection sensor for detecting the negative ion generation amount. Further, according to the above-mentioned invention, by controlling the negative ion generation amount in response to the value detected by the ion detection sensor, it is possible to keep the negative ion generation amount which changes depending on the use environment and state constant.

The invention according to claim 11 of the present invention has a plurality of irradiation sources, and ultraviolet rays are alternately irradiated from the plurality of irradiation sources. Further, according to the above-mentioned invention, by alternately lighting a plurality of ultraviolet lamps which are irradiation sources, it is possible to extend the life of the irradiation sources as a whole.

According to a twelfth aspect of the present invention, the irradiation of the irradiation source is performed as an ON-OFF intermittent operation. Further, according to the above invention, the ultraviolet lamp which is the irradiation source is
By turning on the N-OFF intermittent lighting, it is possible to extend the life of the irradiation source as a whole. Further, it is possible to adjust and control the generation of excessive negative ions, and it is possible to generate negative ions that are close to those in nature.

[0028]

Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 is a side sectional view showing an air conditioner having a negative ion generator according to Embodiment 1 of the present invention.

1 to 15, the main body is composed of a front grille 20 forming the front surface of the main body, a main body partition wall 21 forming the middle portion, a rear main body 23 having a rear portion 22 and a main body upper portion 24 forming the upper surface of the main body. The front grille 20 formed on the front surface of the main body is provided with a front air intake port 25 in a concave central portion 20a. The front intake port 25 is formed with an opening 25a which is cut out from the center of the main body toward the left and right sides. Further, rear air inlets 26 that open toward the rear of the main body are formed on both left and right sides of the rear portion 23 of the main body. Reference numeral 27 denotes a vortex chamber formed between the main body partition wall 21 and the main body rear portion 23, and has a fan 29 connected to a motor 28 inside to form an electric blower. A suction port 30 and a rib 31 are provided on the front surface of the main body partition wall 21, and the rib 31 supports a filter 32 including an activated carbon filter for deodorization and a charging filter for dust collection arranged on the front surface. .

The suction port 30 communicates with an electric blower composed of a motor 28 and a fan 29.
An exhaust port 33 is formed above the rear body 23 and communicates with a vortex chamber 27 formed between the main body partition wall 21 and the rear body 23. Inside the front grille 20 is removed, a main body front 34 is disposed above the front surface of the main body, and a display unit 35, a changeover switch 36, a lamp display unit 37,
Further, an odor detecting sensor 38 for detecting an odor in the air and a particle detecting sensor 39 for detecting the amount of dust in the air are arranged. A control circuit 40 and the above-mentioned sensors are provided inside the front of the main body 4, and the driving operation can be performed by the changeover switch 36. The main body upper part 24 is sandwiched between the main body front wall 34 and the main body rear wall 23 above the main body partition wall 21, and has a negative ion emission port 41.

In the front grille 20, the hooking portion 42 formed in the lower portion is inserted into the fitting hole 43 formed in the lower portion of the main body partition wall 21, and then the claws 44 provided on the left and right sides of the upper portion of the front grille 20 are attached to the front of the main body. It is detachably attached by engaging with engaging portions 44a provided on both left and right sides of 34. Reference numeral 45 denotes a pedestal portion which is integrally formed on the lower portion of the main body partition wall 21.

Reference numeral 46 denotes a negative ion generating unit, which has a negative ion generating unit 49 including a photoelectron emitting material 47 and an irradiation source 48 for irradiating the photoelectron emitting material 47 with ultraviolet rays. The negative ion generating unit 49 includes a photoelectron emitting material 47 and an ultraviolet ray irradiation source 4 for the photoelectron emitting material 47.
8 and the photoelectron emission material 47 is the photoelectron emission material 4
While irradiating the surface of 7 with ultraviolet rays, the photoelectron emitting material 4
An air flow is introduced to the surface of the photoelectron emitting material 7 to generate photoelectrons (negative ions 66) on the surface of the photoelectron emitting material 47. An ultraviolet lamp 50 is used as an irradiation source 48 for irradiating ultraviolet rays, and includes a lamp part 51 having a filament and a mercury sphere inside and a screw-shaped base part 53 for attaching to a porcelain (ceramic) socket 52. Become.

An irradiation source 48 for irradiating ultraviolet rays is connected to the control circuit 40 to turn on / off the irradiation of the irradiation source.
By intermittently changing the ultraviolet irradiation intensity of the irradiation source,
Alternatively, control such as intermittent ON / OFF of the irradiation source or variable of the ultraviolet irradiation intensity is performed in response to the value detected by the ion detection sensor 68 provided in the negative ion outlet 41.

The photoelectron emitting material 47 is made of a cylindrical metal material, here phosphor bronze, and the entire surface including the cylindrical inner surface is subjected to a surface treatment having a surface layer of Au (gold). Although Au (gold) plating is applied here,
It may be u (gold) vapor deposition. Then, the plate material before being bent into a cylindrical shape is subjected to the surface treatment of the Au (gold) plating. Further, the photoelectron emitting material 47 has a terminal connecting portion 5
4 is integrally formed, and a terminal 55 that is electrically connected to the control circuit 40 is connected to the control circuit 40. The socket 52, to which the ultraviolet lamp 50 is attached, is screwed and fixed to a fixed base 56 formed of sheet metal, and the fixed base 56 is further fixed to a lower protective cover 57 by screwing. The photoelectron emitting material 47 is screwed and fixed to the boss of the main body partition wall 21 that penetrates the lower protective cover 57 with the insulating sheet 58 sandwiched therebetween. The upper protective cover 59 is attached so as to cover the lower protective cover 57 from above, prevents ultraviolet rays emitted from the ultraviolet lamp 50 from leaking to the outside, and forms a passage through which an air flow passes. An airflow intake port 60 or a negative ion emission port 4 that serves as a guide for the airflow to the generation unit 49.
The channels up to 1 are formed. A packing 61 is attached on the outer periphery of the cylindrical photoelectron emitting material 47 between the protective cover upper portion 59 and the protective cover lower portion 57, and the passage for air flow is limited to the inner surface of the cylindrical photoelectron emitting material 47. It is air tight. The negative ion generator unit 46 is provided with a rib body 62 from the mounting surface of the main body partition wall 21.
Since it is mounted so as to float from the wall surface and is inclined (about 25 °) with respect to the wall surface of the main body partition wall 21,
The negative ion generator 49 is arranged so as to be inclined with respect to the air flow.

The air flow inlet 60 of the negative ion generator unit 46 is provided along the shape of the tongue portion 63. Reference numeral 64 denotes an eaves A formed on the protective cover 59, which prevents the irradiation source 48 from looking directly at the irradiation source 48 even when looking through the negative ion emission port 41 or the exhaust port 33. Further, the ultraviolet irradiation to other parts near the negative ion emission port 41 is prevented, and the negative ion generation part 49 is prevented from being exposed to water even when water enters from the outside.

Reference numeral 65 denotes an eaves B formed under the protective cover 57, which, like the eaves A64, prevents direct irradiation of the irradiation source 48, prevents ultraviolet rays from irradiating other parts, and generates negative ions even when water enters from the outside. The rib body 62 also serves as a guide for feeding water into the clearance floated from the wall surface so that the portion 49 is not splashed with water. Although the eaves A64 and the eaves B65 are provided in the rear part of the negative ion generation part 49, the same effect can be obtained by providing them in the front part or both.

In the above structure, the operation will be described. When the motor 28 is rotated by the changeover switch 36,
The fan 29 connected to the motor 28 rotates, and air is sucked in through the front intake port 25 and the rear intake port 26. The sucked airflow passes through a filter 32, which is a combination of an activated carbon filter and a charging filter, and is discharged to an exhaust port 33 to deodorize and purify the air.

Further, in the automatic operation, each sensor detects according to the dirt of the air in the room. The particle detection sensor 39 detects dust and the like and the odor detection sensor 38 detects odor of cigarette smoke and the like, and the control circuit 40 controls the motor 28 in accordance with the output of each sensor which changes depending on the concentration of the operation. To do. Then, the air that has passed through the filter 32 and is exhausted to the exhaust port 33 has a portion of the exhaust gas that flows in from the air flow intake port 60 of the negative ion generation unit 46 that is provided along the shape of the tongue portion 63, generating negative ions. It flows into the part 49. Negative ions 66 are generated in the airflow that has flowed into the negative ion generation unit 49. That is,
The photoelectrons (negative ions) 66 are obtained by irradiating the photoelectron emitting material 47 with the ultraviolet rays from the ultraviolet lamp 8. In this way, the air flow containing the obtained negative ions 66 is discharged from the negative ion discharge port 41. At this time, the negative ions 66 are diffused in the entire room by being placed on this airflow exhausted into the room through the exhaust port 33.

Then, according to the above, by irradiating the photoelectron emitting material 47 with the ultraviolet rays from the irradiation source 48, the negative ions 66 are generated in the air flow, and the air containing the negative ions 66 is obtained, while the front air intake port The airflow sucked from the intake ports 25 and the rear intake port 26 passes through the filter 32, is deodorized and purified, and is exhausted into the room through the exhaust port 33. The negative ions 66 are diffused in the entire room by being carried on the air flow, and the negative ions 66 are generated to electrically neutralize the fine particles or carry a negative charge to provide a stable indoor space.

Since the negative ion emission port 41 is provided in the vicinity of the exhaust port 33, the negative ions 66 emitted from the negative ion emission port 41 by being carried by the air flow from the exhaust port 33 are effective for the entire room. Can be diffused and released.

A part of the air flow from the electric blower composed of the motor 28 and the fan 29 is used as a negative ion generator 49.
Since it is passed through the inside, there is no need for an electric blower composed of a dedicated motor, fan, etc. for passing the air flow into the negative ion generation part 49, and the air flow from the main body is used to generate the negative ions 66, It can be released and the structure is simple and can be provided at low cost.

Then, a part of the air flow from the electric blower composed of the motor 28 and the fan 29 is used as the negative ion generating unit 4.
The amount of air passing through 9 is 0.5 of the air flow from the electric blower.
% To 15% is suitable, preferably 0.5
% To 5% is suitable. In the air volume value,
0.05 m ³ / min to 1.0 m ³ / are suitable for passing minute, preferably is suitable for passing air volume of 0.05 m ³ / min to 0.2 m ³ / min. If the amount of the air flow passing through the negative ion generator 49 increases, the amount of the negative ions 66 generated can be increased, but since the pressure loss of the air flow of the air conditioner body is correspondingly increased, the intake and exhaust amount of the air conditioner body is increased. And the deodorizing and purifying performance of indoor air is deteriorated, and even if the amount of generation of negative ions 66 is increased, diffusion and release into the room will be decreased. Negative ion 6
When the deodorizing and purifying performance of the indoor air is sacrificed to some extent, 0.5% to 15% or 0.
05M ³ / min to 1.0 m ³ / min while that through the air volume are suitable, not the pressure loss of the airflow through 5% or 0.05 m ³ / min to 0.2 m ³ / min air volume from 0.5% It is preferable to generate a large amount of negative ions 66 while ensuring the cleaning effect and to stabilize the amount of negative ions 66 generated. By setting the above-mentioned range, it is possible to generate a large amount of negative ions 66 and to stabilize the amount of negative ions 66 while maintaining the cleaning effect without causing pressure loss of the air flow.

Then, the tongue portion 63 with which the airflow from the electric blower composed of the motor 28 and the fan 29 collides most.
Since the air flow intake port 60 of the negative ion generation unit 46 is provided along the air flow, the air flow can smoothly flow into the air flow intake port 46 along the tongue shape, thereby generating and releasing a large number of negative ions 66. You can do it.

Further, an ultraviolet lamp 50 is used as an irradiation source 48 for irradiating the photoelectron emitting material 47 with ultraviolet rays, and the base portion 53 of the ultraviolet lamp 50 composed of the lamp portion 51 and the base portion 53 is flown into the negative ion generating portion 49. Intake 6
Since the lamp unit 51 is arranged on the 0 side, the lamp unit 51 irradiates the photoelectron emitting material 47 with ultraviolet rays to generate negative ions 66 in the air flow, but the base unit 53 is positioned in the subsequent flow. If so, some of the negative ions 66 will be reduced in the base 53, but the base 53 of the ultraviolet lamp 50 will be replaced by the negative ion generator 49.
By arranging it on the side of the air flow intake port 60, the decrease of negative ions 66 is prevented, and a large number of negative ions 6
6 can be generated and released.

In FIG. 13, an ultraviolet lamp 50 is used as an irradiation source 48 for irradiating the photoelectron emitting material 47 with ultraviolet rays, and the ultraviolet lamp 50 comprises a lamp portion 51 and a base portion 53.
The lamp unit 51 of No. 1 is arranged on the air flow intake port 60 side of the negative ion generating unit 49. In this case, the irradiation source 4
The lamp section 51 of the ultraviolet lamp 50, which is No. 8, generates heat when irradiated with ultraviolet rays and therefore needs to be cooled.
By arranging the lamp 9 on the side of the air flow intake port 60, the air flow of the exhaust gas first hits the lamp portion 51, which is a heat generating portion, and the ultraviolet lamp 50 can be effectively cooled.

In FIG. 14, activated carbon 67 is arranged on the downstream side of the negative ion generator 49 and upstream of the negative ion emission port 41.

According to the above-mentioned structure, the photoelectron emitting material 47 is irradiated with the ultraviolet rays from the irradiation source 48 to generate the negative ions 66 in the air flow.
Even if a slight amount of ozone is generated at this time, this ozone odor can be completely removed by the activated carbon 67 on the downstream side to deodorize.

Here, the negative ion generator unit 46 is mounted by being floated from the wall surface by the rib body 62 from the mounting surface of the main body partition wall 21 and inclined (about 25 °) with respect to the wall surface of the main body partition wall 21. Since the negative ion generating portion 49 is disposed so as to be inclined with respect to the air flow and the exhaust port 33, the ultraviolet light emitted from the irradiation source 48 leaks from the exhaust port 33 to the outside of the main body. Can be prevented. In other words, if the negative ion generating portion 49 is not inclined with respect to the air flow and the exhaust port 33, the ultraviolet light emitted from the irradiation source 48 passes through the cylindrical photoelectron emitting material 47, and It will be irradiated to the outside.

The negative ion generator unit 46
Since the rib body 62 is floated from the mounting surface of the main body and is attached, even if water accidentally enters from the negative ion emission port 41 or the exhaust port 33, the water that has entered is a gap floated by the rib body 62. To prevent water from entering the negative ion generating portion 49. Also irradiation source 4
The ultraviolet lamp 50, which is No. 8, generates heat when irradiated with ultraviolet rays, but the irradiation source 48 in the negative ion generation unit 49
The heat generated in (1) is prevented from propagating to the mounting surface of the main body partition wall 21 by the gap formed by the rib body 62. Although a small amount, a part of the airflow passes through the gap floated by the rib body 62.

The protective cover upper part 59 is attached so as to cover the protective cover lower part 57 from above, and protects the periphery of the negative ion generating part 49 inside, so that the ultraviolet light emitted from the ultraviolet lamp 50 does not leak to the outside. In addition to forming a passage through which the air flow passes, a flow path is formed to the air flow inlet 60 and the negative ion emission port 41 that serve as a guide for the air flow to the negative ion generation unit 49. With the above configuration, the ultraviolet light emitted from the irradiation source 48 is prevented from leaking to the outside of the main body, and at the same time, the air flow inlet 6 serves as a guide for the air flow to the negative ion generating portion 49.
A flow path to 0 or the negative ion emission port 41 is formed.

Above the protective cover 59 and below the protective cover 57
The material is made of metal such as galvanized steel plate and color steel plate, and prevents the material from being deteriorated by the ultraviolet light emitted from the irradiation source 48. Here, a galvanized steel plate, a coated steel plate such as a color steel plate, and a coated steel plate are given, but other materials may be used as long as they are materials that are not easily deteriorated by the ultraviolet light emitted from the irradiation source 48. Good. Considering the case of looking through the exhaust port 33, if a color steel plate having a color close to the color of the main body is used, the color becomes a protective color and there is no problem in appearance.

Further, the material of the upper protective cover 59 and the lower protective cover 57 may be formed of a material obtained by adding an ultraviolet absorber to a synthetic resin. In that case, the material for the ultraviolet light emitted from the irradiation source 48 may be changed. Deterioration is prevented by adding an ultraviolet absorber, and because it is a synthetic resin,
The processing of the protective cover upper part 59 and the protective cover lower part 57 is generally a resin molding process using a mold, which facilitates the processing and molding and can be provided at a low cost. Polycarbonate, acrylic, etc. are suitable as the material of the synthetic resin.

The photoelectron emitting material 47 is made of a cylindrical metal material, phosphor bronze in this case, and the entire surface including the cylindrical inner surface is surface-treated with an Au (gold) layer. Further, the photoelectron emitting material 47 is integrally formed with a terminal connecting portion 54, and the terminal 5 is electrically connected to the control circuit 40.
5 is connected.

Then, according to the above, the surface of the ultraviolet lamp 50, which is the irradiation source 48, is wrapped in a cylindrical shape at a uniform distance, and the surface having the Au layer on the inner surface separated from the surface of the ultraviolet lamp 50 by a uniform distance. By irradiating the treated cylindrical photoelectron emitting material 47 with ultraviolet rays having a uniform irradiation intensity, a large number of negative ions 66 can be stably generated.

Further, although phosphor bronze is used for the photoelectron emitting material 47, phosphor bronze is excellent in conductivity and has a feature that it is easy to perform a surface treatment having an Au layer such as plating and vapor deposition. In order to stably obtain a large amount of the negative ions 66, it is most important that the photoelectron emitting material 47 conducted to the control circuit 40 has excellent conductivity and always emits photoelectrons. Therefore, materials such as brass, bronze, phosphor bronze and the like having excellent conductivity are suitable for the photoelectron emitting material 47, and these materials also have excellent adhesion at the time of plating and vapor deposition, and a surface having an Au layer. Processing can be performed easily.

Further, the photoelectron emitting material 47 is a plate material before being bent into a cylindrical shape, that is, a sheet shape, since the plate material before being bent into a cylindrical shape is subjected to surface treatment such as plating or vapor deposition. Therefore, the surface treatment such as plating and vapor deposition can be easily performed, and the workability thereof is good and can be easily performed.

Of course, the surface may be plated or vapor-deposited after being bent into a cylindrical shape. In that case, the bending or bending is performed after the surface is subjected to plating or vapor deposition after being bent into a cylindrical shape. Photoelectron emission material 47 that is often surface-treated with dies and jigs
There is no risk of scratching the surface, and scratches during bending can be prevented.

In addition, the photoelectron emitting material 47 has a terminal connecting portion 5
4 is integrally formed, and the terminal 55 which is electrically connected to the control circuit 40 is connected to the control circuit 40. Therefore, it is not necessary to provide a terminal connecting portion as a separate component, and thus it can be formed at low cost.

In connection with the control circuit 40, since the negative ion generating section 49 is arranged between the control circuit 40 and the exhaust port 33, the wiring from the negative ion generating section 49 to the control circuit 40 is shortened. Therefore, the wiring work can be easily performed, and the negative ions 66 can be diffused and released in the entire room by being placed in the air flow.

The irradiation source 48 for irradiating the ultraviolet rays is connected to the control circuit 40 and the irradiation of the irradiation source 48 is turned ON-O.
The FF intermittent, the ultraviolet irradiation intensity of the irradiation source 48 is changed, or the ON-OFF intermittent irradiation of the irradiation source 48 or the ultraviolet irradiation intensity is detected by the ion detection sensor 68 provided in the negative ion outlet 41. However, when the irradiation of the irradiation source 48 is intermittently turned on and off, the ultraviolet lamp 50, which is the irradiation source 48, is turned on and off intermittently. As a result, the total life of the ultraviolet lamp 50 which is the irradiation source 48 can be extended, and the negative ion 6
It is possible to adjust and control the excess of 6 and to generate negative ions close to the natural world.

In FIG. 15, a plurality of ultraviolet lamps 50 serving as irradiation sources 48 are provided, and ultraviolet rays are alternately emitted from the plurality of ultraviolet lamps 50.
By alternately turning on 0, the irradiation source 4
It is possible to extend the total life of the ultraviolet lamp 50 which is 8.

Next, when the ultraviolet irradiation intensity of the irradiation source 48 is varied, the generation amount of negative ions 66 increases as the irradiation intensity of ultraviolet rays increases, and the generation amount of negative ions 66 decreases as the irradiation intensity decreases. Irradiation source 48
The amount of negative ions 66 generated can be controlled by varying the ultraviolet irradiation intensity of the ultraviolet lamp 50, which is used, and the detection of the use environment such as temperature and humidity, the odor detection sensor 38, and the particle detection sensor 39. By changing the ultraviolet irradiation intensity of the irradiation source 48 according to the usage state such as the degree of contamination of the indoor air, the negative ions 66
It is possible to variably control the generation amount of the negative ions 66, and it is possible to generate the negative ions 66 close to the natural world.

At that time, the amount of the generated negative ions 66 is detected by the ion detection sensor 68, and the generated amount of the negative ions 66 is controlled in response to the detected value, so that the usage environment and the usage state The amount of negative ions 66 that change can be controlled more finely,
Alternatively, the amount of negative ions 66 generated can be kept constant regardless of the use environment and use state.

Further, by forming the rear intake port 26 opening toward the rear of the main body, in addition to the front intake air 25, intake is made from the rear part of the main body as well, so that three-dimensional intake can be achieved, and it can be combined with the air flow from the exhaust port 33. By the intake air flow, the air circulation in the indoor space can be made three-dimensional, and the negative ions 66 can be three-dimensionally diffused and released into the room. Further, since the front air intake port 25 is provided in the concave central portion 20a on the front surface of the main body, and the opening 25a of the front air intake port 25 is cut out toward the left and right sides from the center of the main body. Airflow enters the front air intake port 25 of the concave central portion 20a from both left and right sides of the main body to allow three-dimensional intake, three-dimensional air circulation in the indoor space, and three-dimensional diffusion and release of negative ions 66 into the room. You can do it.

The negative ions 66 generated in large numbers in the negative ion generating portion 49 tend to collide with the wall surface of the main body or the structure and decrease, but the negative ion generating portion 4
Since 9 is arranged on the blowout air side close to the exhaust port 33 on the downstream side of the blower without the electric blower including the filter 32, the motor 28, and the fan 29, the reduction of the negative ions 66 can be suppressed to the maximum. A larger number of negative ions 66 can be emitted from the negative ion outlet 41.

(Second Embodiment) FIG. 16 is a side sectional view showing an air conditioner having a negative ion generating portion according to a second embodiment of the present invention.

The second embodiment is different from the first embodiment in that the negative ion generating portion 49 is arranged on the upstream side of the filter 32 and on the front intake port 25 side. The same reference numerals as those in the first embodiment have the same structure, and the description thereof will be omitted.

The negative ion generator 49 is replaced by the filter 3
By arranging on the side of the front intake port 25 on the upstream side of 2,
The dirty air particles sucked in through the front air intake port 25 and the rear air intake port 26 are charged by the negative ions 66 generated in the negative ion generation unit 49, so that the dust collecting performance in the downstream filter 32 is improved. .

(Third Embodiment) FIG. 17 is a side sectional view showing an air conditioner having a negative ion generating portion according to a third embodiment of the present invention.

The third embodiment differs from the first embodiment (or the second embodiment) in that the negative ion generator 49 is on the suction wind side, which is the upstream side of the electric blower composed of the motor 28 and the fan 29, and is electrically connected to the filter 32. It is placed between the blowers. The same reference numerals as those in the other embodiments have the same structure, and the description thereof will be omitted.

Next, the operation and action will be described. Since the dirty air sucked in through the front intake port 25 and the rear intake port 26 is purified and deodorized by the filter 32, the filter 3
The photo-electron emission material 47 of the negative ion generation part 49 and the irradiation source 48 for irradiating the ultraviolet rays in the downstream of the filter 2 are provided with the filter 3
The air that has been purified and deodorized in 2 hits and does not become dirty. The ultraviolet lamp 50, which is the irradiation source 48, generates heat when it is irradiated with ultraviolet rays and therefore needs to be cooled. However, the motor 28 of the electric blower including the motor 28 and the fan 29.
The UV lamp 50 is cooled effectively because the UV lamp 50 is exposed to the air current before being heated.

[0073]

According to the present invention, dirty air and odorous air in a room are sucked in, purified and deodorized, safety and cost reduction are promoted, and ozoneless negative (negative) ions are generated in the indoor space. By doing so, it is possible to create a space that does not impair the metabolic function and physiological function of the living body, and to generate negative (negative) ions to electrically neutralize the fine particles or give a negative charge to provide a stable space. .

[Brief description of drawings]

FIG. 1 is a side sectional view of an air conditioner having a negative ion generation unit according to a first embodiment of the present invention.

FIG. 2 is a side view of the air conditioner.

FIG. 3 is a front view including a partial cross section of the air conditioner.

FIG. 4 is a plan view of the air conditioner.

FIG. 5 is a rear view of the air conditioner with the main body rear removed.

FIG. 6 is a cross-sectional plan view of the air conditioner.

FIG. 7 is a view showing the unit part of the negative ion generation unit.

FIG. 8 is a view showing the unit portion of the negative ion generation unit.

FIG. 9 is a front view of the air conditioner with the front grill removed.

FIG. 10 is a sectional view showing a claw portion of a front grill of the air conditioner.

FIG. 11 is a perspective view showing a photoelectron emission material of the negative ion generation unit.

FIG. 12 is a cross-sectional view showing the unit part of the negative ion generation unit.

FIG. 13 is a sectional view showing the unit part of the negative ion generation unit.

FIG. 14 is a cross-sectional view showing the unit part of the negative ion generating unit.

FIG. 15 is a cross-sectional view showing the unit part of the negative ion generation unit.

FIG. 16 is a cross-sectional view of an air conditioner having a negative ion generating portion according to the second embodiment of the present invention.

FIG. 17 is a cross-sectional view of an air conditioner having a negative ion generating portion according to the third embodiment of the present invention.

FIG. 18 is a perspective view of a main body of an air conditioner having a conventional negative ion generation unit.

FIG. 19 is a side sectional view of the air conditioner.

FIG. 20 is a sectional view of the air conditioner.

[Explanation of symbols]

28 motors 29 fans 33 exhaust port 46 Negative ion generator unit 47 Photoemissive material 48 irradiation source 49 Negative ion generator 50 UV lamp

Front page continuation (51) Int.Cl. ⁷ Identification code FI theme code (reference) B03C 3/43 B03C 3/43 (72) Inventor Nobuhiro Hayashi 1006 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Industrial Co., Ltd. F Term (reference) 4C080 AA09 BB02 CC02 MM40 QQ20 4D054 AA11 BA17 BA19 EA01 EA11

Claims (12)

[Claims] 1. A photoelectron emission material and an irradiation source are provided, and the photoelectron emission material is irradiated with ultraviolet rays from the irradiation source to generate negative ions, and at the same time, an exhaust port of the device main body for discharging air to the atmosphere. Negative ion generation part provided in the vicinity. 2. The apparatus main body is provided with an electric blower having a suction action, and is arranged upstream of the electric blower.
Negative ion generator described. 3. The device body is provided with an electric blower having a suction action, and is arranged on the downstream side of the electric blower.
Negative ion generator described. 4. The photoelectron emission material is made of a metal material,
The negative ion generating part according to any one of claims 1 to 3, which has been subjected to a surface treatment having an Au layer on at least an inner surface thereof. 5. The negative ion generating part according to claim 4, wherein the photoelectron emitting material is made of one of materials selected from brass, bronze and phosphor bronze. 6. The photoelectron emission material is cylindrical and is made of Au plating or vapor deposition, and the plate material before being bent into a cylindrical shape is subjected to the surface treatment of plating or vapor deposition. Negative ion generator. 7. The photoelectron emission material is cylindrical and is made of Au plating or vapor deposition, and is subjected to the surface treatment of plating or vapor deposition after being bent into a cylindrical shape.
Negative ion generator described. 8. The photoelectron emission material has a cylindrical shape, a polygonal tube,
The negative ion generating part according to any one of claims 1 to 7, comprising one of a shape selected from a mesh tube, a fibrous (cotton) tube, and a bellows tube. 9. The negative ion generation unit according to claim 1, wherein the ultraviolet irradiation intensity of the irradiation source is varied to control the negative ion generation amount. 10. The negative ion generation unit according to claim 1, wherein the negative ion generation amount is controlled in response to a value detected by an ion detection sensor that detects the negative ion generation amount. 11. The negative ion generation unit according to claim 1, further comprising a plurality of irradiation sources, and the ultraviolet rays are alternately irradiated from the plurality of irradiation sources. 12. The negative ion generation unit according to claim 1, wherein the irradiation of the irradiation source is an ON-OFF intermittent operation.