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Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | UP-0994869 (2004-11-22) |
등록번호 | US-7767169 (2010-08-24) |
발명자 / 주소 |
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 | 피인용 횟수 : 4 인용 특허 : 424 |
Systems in accordance with embodiments of the present invention can include an air transporter-conditioner having a housing with an inlet and an outlet. An ion generator is disposed within the housing, the ion generator being adapted to create an airflow between the inlet and the outlet. The ion gen
Systems in accordance with embodiments of the present invention can include an air transporter-conditioner having a housing with an inlet and an outlet. An ion generator is disposed within the housing, the ion generator being adapted to create an airflow between the inlet and the outlet. The ion generator can comprise a emitter electrode array and a collector electrode array, with a voltage generator electrically connecting the arrays. A grid having a photocatalytic coating can further be disposed within the housing such that the grid is upstream of the arrays, and within an airflow generated by the ion generator. An activator, for example a UV lamp, can still further be disposed within the housing and upstream of the arrays, and positioned such that the grid is irradiated by UV light from the UV lamp, activating the photocatalyst and causing VOCs to breakdown in the presence of the photocatalyst.
The invention claimed is: 1. An air transporter-conditioner, comprising: an ion generator adapted to create an airflow, the ion generator including one or more emitter electrodes, one or more collector electrodes, and a voltage generator coupled between the one or more emitter electrodes and one or
The invention claimed is: 1. An air transporter-conditioner, comprising: an ion generator adapted to create an airflow, the ion generator including one or more emitter electrodes, one or more collector electrodes, and a voltage generator coupled between the one or more emitter electrodes and one or more collector electrodes; one or more of driver electrodes located between the one or more collector electrodes, the driver electrodes being at least partially coated with a photocatalytic material; a grid structure at least partially coated with photocatalytic material located between the one or more emitter electrodes and one or more collector electrodes; and an activator being adapted to emit radiation onto the one or more coated driver electrodes and the grid structure, so that the photocatalytic material is activated. 2. The air transporter-conditioner of claim 1, wherein the photocatalytic material comprises a metal oxide. 3. The air transporter-conditioner of claim 2, wherein the photocatalytic material is at least one of titanium dioxide, cuprous oxide, zinc oxide, and silicon dioxide. 4. The air transporter-conditioner of claim 2, wherein the metal oxide comprises a metal selected from a group including manganese, copper, cobalt, chromium, iron, titanium, zinc and nickel. 5. The air transporter-conditioner of claim 2, wherein the photocatalytic material further comprises one or both of palladium and platinum. 6. The air transporter-conditioner of claim 1, wherein the radiation emitted by the activator has a wavelength less than 385 nm. 7. The air transporter-conditioner of claim 1, wherein the radiation emitted by the activator is in the ultraviolet spectrum. 8. The air transporter-conditioner of claim 7, wherein the activator is an ultraviolet lamp. 9. The air transporter-conditioner of claim 1, wherein the one or more coated driver electrodes are coupled to the ground. 10. The air transporter-conditioner of claim 1, wherein the one or more coated driver electrodes are coupled to a positive terminal of the voltage generator. 11. The air transporter-conditioner of claim 1, wherein the ion generator is enclosed in a housing having an inlet and an outlet. 12. The air transporter-conditioner of claim 11, further comprising a means for directing the radiation away from the inlet and the outlet. 13. The air transporter-conditioner of claim 11, wherein the housing further has an interior surface, the interior surface being a diffusing surface to minimize deflection of the radiation emitted from the activator. 14. The air transporter-conditioner of claim 13, wherein the inlet and the outlet are covered with vertically oriented fins. 15. The air transporter-conditioner of claim 1, further comprising a means to control the airflow rate. 16. The air transporter-conditioner of claim 11, wherein the housing is elongated and upstanding. 17. The air transporter-conditioner of claim 11, wherein the housing is adapted to be located on a desk. 18. The air transporter-conditioner of claim 1, wherein the ion generator is electrically connected with a power source by one of a wall plug and a car plug. 19. An air transporter-conditioner, comprising: a housing having an inlet and an outlet; means for creating an airflow between the inlet and the outlet wherein said means for creating comprises an emitter electrode array and a collector electrode array; a first electrode array at least partially coated with photocatalytic material for reducing a level of volatile organic compounds within the airflow, said first electrode array being disposed within the housing; and a grid structure at least partially coated with photocatalytic material, located between the emitter electrode array and the collector electrode array. 20. The system of claim 19, wherein a voltage potential between the emitter electrode array and the collector electrode array creates said airflow. 21. The system of claim 20, wherein said first electrode array includes one or more driver electrodes located between one or more collector electrodes. 22. The system of claim 21, wherein one or more driver electrodes are coupled to the ground. 23. The system of claim 19, further comprising means for activating disposed within the housing and arranged such that said means for activating irradiates said first electrode array. 24. The system of claim 19, wherein the photocatalytic material comprises a metal oxide. 25. The air transporter-conditioner of claim 24, wherein the photocatalytic material is at least one of titanium dioxide, cuprous oxide, zinc oxide, and silicon dioxide. 26. The air transporter-conditioner of claim 24, wherein the metal oxide comprises a metal selected from a group including manganese, copper, cobalt, chromium, iron, titanium, zinc and nickel. 27. The air transporter-conditioner of claim 24, wherein the photocatalytic material further comprises one or both of palladium and platinum. 28. The system of claim 23, wherein said means for activating irradiates said first electrode array with radiation having a wavelength less than 385 nm . 29. The system of claim 23, wherein said means for activating irradiates said first electrode array with radiation having a wavelength in the ultraviolet spectrum. 30. The system of claim 23, wherein said means for activating is an ultraviolet lamp. 31. The system of claim 23, wherein said first electrode array is located downstream from said means for activating. 32. An air transporter-conditioner system adapted to reduce volatile organic compounds within an airflow, comprising; a housing having an inlet and an outlet; means for generating said airflow between the inlet and the outlet, said means for generating said airflow being disposed within the housing wherein said means for creating comprises an emitter electrode array and a collector electrode array; a first electrode array at least partially coated with photocatalytic material, said first electrode array being disposed within the housing; a grid structure at least partially coated with photocatalytic material, located between the emitter electrode array and the collector electrode array; and means for activating the photocatalytic material, said means for activating being arranged to irradiate said first electrode array. 33. The system of claim 32, wherein a voltage potential between the emitter electrode array and the collector electrode array generates said airflow. 34. The system of claim 33, wherein said first electrode array includes one or more driver electrodes located between one or more collector electrodes. 35. The system of claim 32, wherein the photocatalytic material comprises a metal oxide. 36. The system of claim 35, wherein the photocatalytic material is at least one of titanium dioxide, cuprous oxide, and zinc oxide. 37. The system of claim 32, wherein said means for activating irradiates said first electrode array with radiation having a wavelength less than 385 nm . 38. The system of claim 32, wherein said means for activating irradiates said first electrode array with radiation having a wavelength in the ultraviolet spectrum. 39. The system of claim 38, wherein said means for activating is an ultraviolet lamp. 40. The system of claim 32, wherein said first electrode array is located downstream from said means for activating. 41. An air transporter-conditioner, comprising; a housing having an inlet and an outlet; an ion generator adapted to create an airflow between the inlet and the outlet, the ion generator including an emitter electrode array, a collector electrode array, and a driver electrode array, a portion of the driver electrode array having a photocatalytic material; a grid structure at least partially coated with photocatalytic material located between an emitter electrode array and a collector electrode array; and an activator disposed within the housing, the activator being adapted to emit radiation onto the driver electrode array and the grid structure, so that the photocatalytic material is activated; wherein a voltage potential between the emitter electrode array and the collector electrode array creates the airflow. 42. The air transporter-conditioner of claim 41, wherein the photocatalytic material comprises a metal oxide. 43. The air transporter-conditioner of claim 42, wherein the photocatalytic material is at least one of titanium dioxide, cuprous oxide, and zinc oxide. 44. The air transporter-conditioner of claim 41, wherein the radiation emitted by the activator has a wavelength less than 385 nm. 45. The air transporter-conditioner of claim 41, wherein the radiation emitted by the activator is in the ultraviolet spectrum. 46. The air transporter-conditioner of claim 45, wherein the activator is an ultraviolet lamp. 47. The air transporter-conditioner of claim 41, wherein the driver electrode array is removably connected with the housing. 48. The air transporter-conditioner of claim 41, further comprising a means for directing the radiation away from the inlet and the outlet. 49. The air transporter-conditioner of claim 41, further comprising a means to control the airflow rate. 50. The air transporter-conditioner of claim 41, wherein the airflow rate passing the activator is slower than the airflow rate exiting the outlet. 51. The air transporter-conditioner of claim 41, wherein the housing further has an interior surface, the interior surface being a diffusing surface to minimize deflection of the radiation emitted from the activator. 52. The air transporter-conditioner of claim 51, wherein the inlet and the outlet are covered with vertically oriented fins. 53. An air transporter-conditioner, comprising; a housing having an inlet and an outlet; an ion generator adapted to create an airflow between the inlet and the outlet, the ion generator including an emitter electrode array, a collector electrode array, and a driver electrode array, wherein one or more driver electrodes being coated with a photocatalytic material; a grid structure at least partially coated with photocatalytic material located between an emitter electrode array and a collector electrode array; and an activator disposed within the housing, the activator being adapted to emit radiation onto the driver electrode array and the grid structure, so that the photocatalytic material is activated. 54. The air transporter-conditioner of claim 53, wherein a voltage potential between the emitter electrode array and the collector electrode array creates the airflow. 55. The air transporter-conditioner of claim 53, wherein the photocatalytic material comprises a metal oxide. 56. The air transporter-conditioner of claim 55, wherein the photocatalytic material is at least one of titanium dioxide, cuprous oxide, and zinc oxide. 57. The air transporter-conditioner of claim 53, wherein the radiation emitted by the activator has a wavelength less than 385 nm . 58. The air transporter-conditioner of claim 53, wherein the radiation emitted by the activator is in the ultraviolet spectrum. 59. The air transporter-conditioner of claim 58, wherein the activator is an ultraviolet lamp. 60. The air transporter-conditioner of claim 53, wherein the driver electrode array is removably connected with the housing. 61. The air transporter-conditioner of claim 53, further comprising a means for directing the radiation away from the inlet and the outlet. 62. The air transporter-conditioner of claim 53, further comprising a means to control the airflow rate. 63. The air transporter-conditioner of claim 53, wherein the airflow rate passing the activator is slower than the airflow rate exiting the outlet. 64. The air transporter-conditioner of claim 53, wherein the housing further has an interior surface, the interior surface being a diffusing surface to minimize deflection of the radiation emitted from the activator. 65. The air transporter-conditioner of claim 64, wherein the inlet and the outlet are covered with vertically oriented fins. 66. A method for air conditioning, comprising: providing an ion generator adapted to create an airflow, the ion generator including one or more emitter electrodes, one or more collector electrodes, one or more of driver electrodes located between the one or more collector electrodes, and a grid structure located between the one or more emitter electrodes and one or more collector electrodes, wherein the driver electrodes and the grid structure being at least partially coated with a photocatalytic material; and activating said ion generator such that a voltage potential exists between the one or more emitter electrodes and the one or more collector electrodes so that an airflow is created; and emiting radiation onto the one or more coated driver electrodes and the grid structure, so that the photocatalytic material is activated. 67. The method of claim 66, further comprising activating said ion generator such that a voltage potential exists between the one or more emitter electrodes and the one or more driver electrodes. 68. The method of claim 66, further comprising activating said ion generator such that a voltage potential exists between the one or more collector electrodes and the one or more driver electrodes.
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