| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 一种厨房废气净化处理装置 | CN201610047544.2 | 2016-01-14 | CN105688563A | 2016-06-22 | 刘胜; 刘岳 |
| 一种厨房废气净化处理装置,所述净化处理装置包括净化箱和设置在净化箱两端的进气口和出气口,还包括循环泵;所述净化箱内设置有第一通道、第二通道和第三通道;所述第一通道、第二通道和第三通道依次连通;所述第一通道与进气口相连;所述第三通道与出气口相连;所述第一通道、第二通道、第三通道分别设置有第一喷淋嘴;第二喷淋嘴和第三喷淋嘴;本发明提供一种厨房废气净化处理装置,可以有效净化厨房废气。 | ||||||
| 2 | 空气净化器 | CN200980114588.0 | 2009-03-06 | CN102015064A | 2011-04-13 | 乔斯林·兰福德; 埃伦·皮尔西; 史蒂夫·沃尔什 |
| 描述一种空气净化器,该空气净化器包括:壳体,该壳体具有穿过其延伸的进气口和排气装置;替换部,该替换部用于容纳液体的贮存器,该替换部可从所述壳体松脱;位于所述壳体内的雾化器,该雾化器被构造成在使用时与液体源相流体接触,以产生液滴薄雾,所述雾化器被构造成在使用时向上喷射所述薄雾;所述壳体内的腔室,所述薄雾基本被保持在该腔室中;所述壳体内的风扇,该风扇被构造成在使用中形成通过所述进气口并进入所述腔室的空气流,使得所述空气流中的污染物中的至少一些被所述薄雾驱出所述空气流,并且驱向所述替换部。还描述了一种用于空气净化器的替换部以及所述空气净化器的用途。 | ||||||
| 3 | 纳米颗粒分离 | CN201080064573.0 | 2010-08-25 | CN102770193A | 2012-11-07 | 伊齐基尔·J·J·克鲁格利克 |
| 本公开总体上涉及气体中悬浮的纳米颗粒的气旋分离或过滤。可以使用超声波发生器或其他发生器来产生液滴的羽流。气体可以与该液滴的羽流混和,以促进纳米颗粒优先粘附到液滴,在混和前该液滴的羽流可能已接收到静电电荷。具有悬浮的纳米颗粒和悬浮的液体颗粒的气体可以流过迅速旋转的气旋分离器,使得经清洁的气体流出过滤器,同时可以在羽流产生器中释放、收集和/或再使用具有粘附的纳米颗粒的液体。通过使纳米颗粒粘附到较大的液体颗粒,过滤器可以允许在空气气压下过滤和收集比当前系统能过滤的颗粒小得多的颗粒。 | ||||||
| 4 | 一种干渣喷水降温抑尘装置 | CN201710945753.3 | 2017-10-12 | CN107520084A | 2017-12-29 | 李跃民; 王宏伟; 王瑞奇; 刘庚强; 王磊; 邵长琪; 仝学峰 |
| 本发明公开了一种干渣喷水降温抑尘装置,包括斗提机和固定在其底部的支腿,斗提机的上部贯通连接有碎渣机,碎渣机的一侧连接有进料斗,所述碎渣机的顶部贯通连接有工作箱。本发明结构简单,水泵抽水并从喷头喷出,进行降温抑尘,同时,电机带动第一齿轮转动,第一齿轮与第二齿轮啮合,带动空心轴转动,利用第一磁铁和第二磁铁之间的排斥力,带动连接杆和扇形齿盘转动,扇形齿盘与齿条啮合,并在弹簧弹力作用下,实现齿条上下移动,进而带动喷头摆动,扩大喷洒范围,进行无死角,主动式抑尘降温,避免粉尘飞扬,污染作业环境,通过改变调节螺栓,改变喷水量,既能实现抑尘降温的目的,又能防止含水量过大导致系统积渣及碎渣机内结块。 | ||||||
| 5 | 基于电-高频振动转化的超声波强化雾化喷淋灭火降烟装置 | CN201410817394.X | 2014-12-25 | CN104524724A | 2015-04-22 | 李春龙; 胡杨; 孙英 |
| 本发明提供了基于电-高频振动转化的超声波强化雾化喷淋灭火降烟装置,属于消防安全设备的技术领域。本装置主要包括烟雾感应模块、控制/通讯模块、电磁阀、超声波发生器、超声波换能器、水泵、胁迫振动室、通讯线路及所需管路和组成零件。本发明的主要技术特征是,利用本装置产生的水雾的受热快速汽化效应、窒息作用和阻断热辐射作用控制火灾和扑灭火灾。同时强化喷雾过程,形成喷雾直接喷射至各种消防环境中,经装置强化的喷雾液滴与高温烟尘颗粒进行碰撞、团聚、吸附、降温、沉降等物理过程,喷雾液滴与火灾中高温有毒气体进行接触、吸附、降温过程,在辅助灭火的同时,将烟气中高温有毒有害颗粒和气体高效脱除,保障消防安全。 | ||||||
| 6 | 纳米颗粒过滤 | CN201080064573.0 | 2010-08-25 | CN102770193B | 2015-03-25 | 伊齐基尔·J·J·克鲁格利克 |
| 本公开总体上涉及气体中悬浮的纳米颗粒的气旋分离或过滤。可以使用超声波发生器或其他发生器来产生液滴的羽流。气体可以与该液滴的羽流混和,以促进纳米颗粒优先粘附到液滴,在混和前该液滴的羽流可能已接收到静电电荷。具有悬浮的纳米颗粒和悬浮的液体颗粒的气体可以流过迅速旋转的气旋分离器,使得经清洁的气体流出过滤器,同时可以在羽流产生器中释放、收集和/或再使用具有粘附的纳米颗粒的液体。通过使纳米颗粒粘附到较大的液体颗粒,过滤器可以允许在空气气压下过滤和收集比当前系统能过滤的颗粒小得多的颗粒。 | ||||||
| 7 | Devices and methods for removing nano-particulates from gases | US14427037 | 2012-09-10 | US09744495B2 | 2017-08-29 | Juan Tu; Han Lin; Bin Liang |
| Systems and methods are disclosed for removing nano-particulates from a gas. The systems may include a chamber to contain the particulate-containing gas, a source of the gas, a source of water vapor, a source of a supersonic gas, and at least one ultrasonic transducer in contact with the chamber. The chamber may also include one or more receptacles to receive the particulates. The methods may include introducing the particulate-containing gas and the water vapor into the chamber. A gas may be introduced into the chamber at supersonic speeds thereby cooling the water vapor to form nucleating ice crystals. The ultrasonic transducers may then introduce ultrasonic power into the chamber thereby causing the particulates to contact the ice crystals. The nucleating crystals, with their attached particulates, may then fall under gravity to be captured in the receptacles. | ||||||
| 8 | Nanoparticle filtration | US12714078 | 2010-02-26 | US08317901B2 | 2012-11-27 | Ezekiel Kruglick |
| The present disclosure generally relates to cyclonic separation or filtering of nanoparticles suspended in a gas. A plume of liquid droplets may be generated using an ultrasound or other generator. The gas may be mixed with the plume of liquid droplets, which may have received an electrostatic charge prior to mixing, to promote preferential adhesion of the nanoparticles to the liquid droplets. The gas with suspended nanoparticles and suspended liquid particles may flow through a cyclonic separator that spins rapidly, causing the cleaned gas to flow out of the filter while the liquid with adhered nanoparticles may be discharged, collected, and/or re-used in the plume generator. By causing nanoparticles to adhere to larger liquid particles, the filter may allow the filtering and collection of much smaller particles than current systems may filter under atmospheric pressure. | ||||||
| 9 | Air Cleaner | US12921258 | 2009-03-06 | US20110048232A1 | 2011-03-03 | Jocelin Langford; Ellen Piercy; Steve Walsh |
| An air cleaner is described comprising a housing having an air inlet and an air exhaust extending therethrough, a refill for containing a reservoir of liquid which is releasable from the housing, a nebuliser within the housing configured, in use, to be in fluid contact with the source of liquid to generate a mist of liquid droplets, said nebuliser being configured, in use, to eject the mist upwardly, a chamber within the housing in which the mist is retained, a fan within the housing configured, in use, to generate a flow of air through the air inlet and into the chamber such that at least some of the contaminants in the air flow are urged by the mist out of the flow of air and toward the refill. A refill for the air cleaner is also described as well as the use of said air cleaner. | ||||||
| 10 | Air purification system and method using an ultrasonic wave | US14310034 | 2014-06-20 | US09403114B2 | 2016-08-02 | Takahisa Kusuura |
| An air purification system comprises a chamber having an air inlet and an air outlet, a plurality of flexible wires hanging from a ceiling of the chamber, a spray mechanism configured to spray droplets in the chamber, and a sound wave generator configured to generate a standing sound wave in the chamber. During operation of the air purification system, the plurality of flexible wires are elastically deformed by the standing sound wave generated by the sound wave generator such that portions of the plurality of flexible wires converge at nodes of the sound wave, and also the droplets move to the nodes of the standing sound wave, while trapping particles in the air during the movement to the nodes. The droplets collide against and are adsorbed to the plurality of flexible wires at the nodes of the sound wave. | ||||||
| 11 | DEVICES AND METHODS FOR REMOVING NANO-PARTICULATES FROM GASES | US14427037 | 2012-09-10 | US20150298042A1 | 2015-10-22 | Juan TU; Han LIN; Bin LIANG |
| Systems and methods are disclosed for removing nano-particulates from a gas. The systems may include a chamber to contain the particulate-containing gas, a source of the gas, a source of water vapor, a source of a supersonic gas, and at least one ultrasonic transducer in contact with the chamber. The chamber may also include one or more receptacles to receive the particulates. The methods may include introducing the particulate-containing gas and the water vapor into the chamber. A gas may be introduced into the chamber at supersonic speeds thereby cooling the water vapor to form nucleating ice crystals. The ultrasonic transducers may then introduce ultrasonic power into the chamber thereby causing the particulates to contact the ice crystals. The nucleating crystals, with their attached particulates, may then fall under gravity to be captured in the receptacles. | ||||||
| 12 | AIR PURIFICATION SYSTEM AND METHOD USING AN ULTRASONIC WAVE | US13262898 | 2010-11-26 | US20120132071A1 | 2012-05-31 | Takahisa Kusuura |
| An air purification system comprises a chamber having an air inlet and an air outlet, a plurality of flexible wires hanging from a ceiling of the chamber, a spray mechanism configured to spray droplets in the chamber, and a sound wave generator configured to generate a standing sound wave in the chamber. During operation of the air purification system, the plurality of flexible wires are elastically deformed by the standing sound wave generated by the sound wave generator such that portions of the plurality of flexible wires converge at nodes of the sound wave, and also the droplets move to the nodes of the standing sound wave, while trapping particles in the air during the movement to the nodes. The droplets collide against and are adsorbed to the plurality of flexible wires at the nodes of the sound wave. | ||||||
| 13 | Method and apparatus for encapsulating particulates | US706217 | 1996-08-30 | US5878355A | 1999-03-02 | Robert O. Berg; William F. Rigby; John P. Albers |
| An improved method and device for decontamination of a contaminated process area is provided whereby a fine aerosol of an encapsulant for use in encapsulating the contaminants within the contaminated environment is generated. The aerosol is generated by a plurality of ultrasonic transducers located below the surface of a reservoir containing a capture liquid. The output of the transducers is focused to a point near the surface of the liquid to cause a surface disturbance which results in the formation of an aerosol of encapsulant from the capture liquid. A pressurization fan is used to force ambient air through the pressurization chamber to transport the aerosol to the process area to be treated. The aerosol forms a thin coating of encapsulant over the hazardous material thereby allowing the hazardous material to be safely removed from the process area or permanently adhered to the walls of the process area. If a chemically hazardous material is found in the process area, a capture liquid can be selected to neutralize the hazardous material. The process is especially effective at recovering radioactive dust from a contaminated process area. | ||||||
| 14 | air purifier | JP2010549193 | 2009-03-06 | JP2011514253A | 2011-05-06 | スティーヴ ウォルシュ; エレン ピアシー; ジョセリン ラングフォード |
| 空気入口とハウジングを通って延びる空気排出口とを有するハウジングと、ハウジングから解除可能な液体のリザーバを収容するためのリフィルと、使用時に液体供給源と流体接触して液滴の霧を発生させるように構成され、かつ使用時に霧を上方に放出するように構成されたハウジング内の噴霧器と、霧が保持されたハウジング内のチャンバと、空気流内の汚染物質の少なくとも一部が、空気流からリフィルの方向に霧によって強く押し出されるように、使用時に空気入口を通ってチャンバ内に入る空気流を発生させるように構成されたハウジング内のファンとを含む空気清浄器を説明する。 空気清浄器のためのリフィル、並びにこの空気清浄器の使用方法も説明する。
【選択図】図1 |
||||||
| 15 | ナノ粒子分離 | JP2012553869 | 2010-08-25 | JP5671068B2 | 2015-02-18 | ジェイ.ジェイ. クルグリック,エゼキエル |
| 16 | AIR PURIFICATION SYSTEM AND METHOD USING AN ULTRASONIC WAVE | US14310034 | 2014-06-20 | US20140360363A1 | 2014-12-11 | Takahisa KUSUURA |
| An air purification system comprises a chamber having an air inlet and an air outlet, a plurality of flexible wires hanging from a ceiling of the chamber, a spray mechanism configured to spray droplets in the chamber, and a sound wave generator configured to generate a standing sound wave in the chamber. During operation of the air purification system, the plurality of flexible wires are elastically deformed by the standing sound wave generated by the sound wave generator such that portions of the plurality of flexible wires converge at nodes of the sound wave, and also the droplets move to the nodes of the standing sound wave, while trapping particles in the air during the movement to the nodes. The droplets collide against and are adsorbed to the plurality of flexible wires at the nodes of the sound wave. | ||||||
| 17 | Air purification system and method using an ultrasonic wave | US13262898 | 2010-11-26 | US08845785B2 | 2014-09-30 | Takahisa Kusuura |
| An air purification system comprises a chamber having an air inlet and an air outlet, a plurality of flexible wires hanging from a ceiling of the chamber, a spray mechanism configured to spray droplets in the chamber, and a sound wave generator configured to generate a standing sound wave in the chamber. During operation of the air purification system, the plurality of flexible wires are elastically deformed by the standing sound wave generated by the sound wave generator such that portions of the plurality of flexible wires converge at nodes of the sound wave, and also the droplets move to the nodes of the standing sound wave, while trapping particles in the air during the movement to the nodes. The droplets collide against and are adsorbed to the plurality of flexible wires at the nodes of the sound wave. | ||||||
| 18 | Air cleaner | US12921258 | 2009-03-06 | US08728208B2 | 2014-05-20 | Jocelin Langford; Ellen Piercy; Steve Walsh |
| An air cleaner is described comprising a housing having an air inlet and an air exhaust extending therethrough, a refill for containing a reservoir of liquid which is releasable from the housing, a nebulizer within the housing configured, in use, to be in fluid contact with the source of liquid to generate a mist of liquid droplets, said nebulizer being configured, in use, to eject the mist upwardly, a chamber within the housing in which the mist is retained, a fan within the housing configured, in use, to generate a flow of air through the air inlet and into the chamber such that at least some of the contaminants in the air flow are urged by the mist out of the flow of air and toward the refill. A refill for the air cleaner is also described as well as the use of said air cleaner. | ||||||
| 19 | NANOPARTICLE FILTRATION | US12714078 | 2010-02-26 | US20110209611A1 | 2011-09-01 | Ezekiel Kruglick |
| The present disclosure generally relates to cyclonic separation or filtering of nanoparticles suspended in a gas. A plume of liquid droplets may be generated using an ultrasound or other generator. The gas may be mixed with the plume of liquid droplets, which may have received an electrostatic charge prior to mixing, to promote preferential adhesion of the nanoparticles to the liquid droplets. The gas with suspended nanoparticles and suspended liquid particles may flow through a cyclonic separator that spins rapidly, causing the cleaned gas to flow out of the filter while the liquid with adhered nanoparticles may be discharged, collected, and/or re-used in the plume generator. By causing nanoparticles to adhere to larger liquid particles, the filter may allow the filtering and collection of much smaller particles than current systems may filter under atmospheric pressure. | ||||||
| 20 | Method and apparatus for encapsulating particulates | US191496 | 1998-11-13 | US6102992A | 2000-08-15 | Robert O. Berg; William F. Rigby; John P. Albers |
| An improved method and device for decontamination of a contaminated process area is provided whereby a fine aerosol of an encapsulant for use in encapsulating the contaminants within the contaminated environment is generated. The aerosol is generated by a plurality of ultrasonic transducers located below the surface of a reservoir containing a capture liquid. The output of the transducers is focused to a point near the surface of the liquid to cause a surface disturbance which results in the formation of an aerosol of encapsulant from the capture liquid. A pressurization fan is used to force ambient air through the pressurization chamber to transport the aerosol to the process area to be treated. The aerosol forms a thin coating of encapsulant over the hazardous material thereby allowing the hazardous material to be safely removed from the process area or permanently adhered to the walls of the process area. If a chemically hazardous material is found in the process area, a capture liquid can be selected to neutralize the hazardous material. The process is especially effective at recovering radioactive dust from a contaminated process area. | ||||||
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