公开(公告)号：US09067789B2

公开(公告)日：2015-06-30

申请号：US14110828

申请日：2011-04-13

Applicant: Shinichi Nishimura ,  Yoichiro Tabata

Inventor： Shinichi Nishimura ,  Yoichiro Tabata

IPC: C01B13/11

CPC classification number: C01B13/11 ,  C01B2201/12 ,  C01B2201/64 ,  C01B2201/66 ,  C01B2201/76 ,  C01B2201/90

Abstract: A gas pipe integrated block includes a plurality of internal pipe paths. The plurality of internal pipe paths are connected to a nitrogen-free ozone generator in which a photocatalytic material for generating ozone is applied to a discharge surface, a controller (an MFC, a gas filter, and an APC), a raw material gas supply port, and an ozone gas output port. Thereby, a raw material gas input pipe path extending from the raw material gas supply port through the APC to the nitrogen-free ozone gas generator, and an ozone gas output pipe path extending from the nitrogen-free ozone generator through the gas filter and the MFC to the ozone gas output port, are formed in an integrated unit.

Abstract translation: 燃气管一体化块包括多个内管道。 多个内部管道连接到无氮臭氧发生器，其中用于产生臭氧的光催化材料被施加到排放表面，控制器（MFC，气体过滤器和APC），原料气体供应 港口和臭氧气体输出口。 由此，从原料气体供给口通过APC向无氮臭氧气体发生器延伸的原料气体输入管路和从无氮臭氧发生器通过气体过滤器延伸的臭氧气体输出管路， MFC到臭氧气体输出口，形成在一体的单元中。

公开(公告)号：US08961471B2

公开(公告)日：2015-02-24

申请号：US12000374

申请日：2007-12-12

Applicant: David M. Hooper ,  Thomas Foster ,  Noel Henson

Inventor： David M. Hooper ,  Thomas Foster ,  Noel Henson

IPC: A61M5/32 ,  A61M37/00 ,  A61M5/00 ,  A61M5/315 ,  A61M39/16 ,  A61M5/31 ,  C01B13/11

CPC classification number: A61M5/002 ,  A61K9/0019 ,  A61K33/00 ,  A61M5/001 ,  A61M5/3129 ,  A61M39/16 ,  A61M2005/006 ,  A61M2005/3117 ,  A61M2039/167 ,  A61M2202/0216 ,  A61M2205/7536 ,  A61M2209/06 ,  C01B13/11 ,  C01B13/115 ,  C01B2201/10 ,  C01B2201/64

Abstract: In accordance with at least one exemplary embodiment, a syringe device, a method and a system for delivering a therapeutic amount of ozone are disclosed. A sterility case can enclose a syringe portion and can maintain sterility while the syringe device is interfaced to an ozone generator. A valvably-controlled fluid channel can extend from a barrel of the syringe portion through the case. Conducting elements can be attached to the case and can breach the case. The conductive elements can be connected to electrodes. The electrodes can be attached to the syringe portion. The syringe portion can be filled with oxygen gas via the valvably-controlled fluid channel. An electric current can be provided to the conductive elements from the ozone generator resulting in a corona discharge from at least one of the electrodes. The therapeutic amount of ozone can be produced from the oxygen gas and the syringe portion delivered into a sterile field without compromise.

Abstract translation: 根据至少一个示例性实施例，公开了一种用于输送治疗量的臭氧的注射器装置，方法和系统。 无菌情况可以包围注射器部分，并且可以在注射器装置与臭氧发生器连接时保持不育。 可控制的流体通道可以从注射器部分的筒体延伸通过壳体。 传导元件可以附在案件上，并可以违反案件。 导电元件可以连接到电极。 电极可以附接到注射器部分。 注射器部分可以通过可调节控制的流体通道填充氧气。 可以从臭氧发生器向导电元件提供电流，从而从至少一个电极进行电晕放电。 可以从氧气和注射器部分产生处理量的臭氧，而不损害地将其输送到无菌区域中。

公开(公告)号：US08900540B2

公开(公告)日：2014-12-02

申请号：US13176154

申请日：2011-07-05

Applicant: Yoshiki Nishiwaki ,  Hidetoshi Oota

Inventor： Yoshiki Nishiwaki ,  Hidetoshi Oota

IPC: C01B13/11 ,  D06M23/10 ,  D06M11/34 ,  B22F1/00 ,  D06M101/40

CPC classification number: C01B13/11 ,  B22F1/0088 ,  C01B2201/64 ,  D06M11/34 ,  D06M23/10 ,  D06M2101/40

Abstract: An oxidation treatment method of the present invention includes the step of bringing a solution having an ozone concentration of 120 to 500 mg/L into contact with a substance to be treated made of a combustible substance, thereby subjecting the substance to be treated and the surface thereof to an oxidation treatment. An oxidation treatment apparatus of the present invention includes: a dissolving means that dissolves an oxygen-ozone mixed gas in a fluorine-based solvent to form mixed fluid; an undissolved gas removal means that removes an undissolved gas from the mixed fluid to form a solution; and an oxidation treatment means that brings the solution into contact with a substance to be treated made of a combustible substance, thereby subjecting the substance to be treated and the surface thereof to an oxidation treatment.

Abstract translation: 本发明的氧化处理方法包括使臭氧浓度为120〜500mg / L的溶液与可燃性物质的待处理物质接触，使被处理物和表面 进行氧化处理。 本发明的氧化处理装置包括：溶解在氟系溶剂中的氧 - 臭氧混合气体以形成混合流体的溶解装置; 未溶解的气体去除装置，从混合流体中除去未溶解的气体以形成溶液; 以及将溶液与可燃性物质的待处理物质接触的氧化处理装置，对被处理物及其表面进行氧化处理。

公开(公告)号：US20140246364A1

公开(公告)日：2014-09-04

申请号：US13782874

申请日：2013-03-01

Applicant: EON LABS LLC

Inventor： Chris Hruska ,  Walter Buchanan ,  David Forsee

IPC: C02F1/46 ,  H02M7/44 ,  C02F1/78

CPC classification number: H02M1/12 ,  C01B13/11 ,  C01B2201/22 ,  C01B2201/32 ,  C01B2201/64 ,  C01B2201/90 ,  C02F1/727 ,  C02F1/78 ,  C02F2209/40 ,  C02F2303/04 ,  C02F2305/023 ,  H02M2007/4815

Abstract: A system for performing ozone water treatment comprises a voltage supply circuit and a plasma eductor reactor. The voltage supply circuit includes an H-bridge controller and driver, a transformer, and an output port. The H-bridge controller and driver are configured to switch the electrical polarity of a pair of terminals. A primary of the transformer is connected to the H-bridge driver and controller. A secondary of the transformer connects in parallel with a first capacitor and in series with an inductor and a second capacitor. The output port connects in parallel with the second capacitor. The plasma eductor reactor includes an electric field generator, a flow spreader, and a diffuser. The electric field generator includes a pair of electrodes that generate an electric field. The flow spreader supplies a stream of oxygen. The diffuser supplies a stream of water. The streams of water and oxygen pass through the electric field.

Abstract translation: 用于进行臭氧水处理的系统包括电压供应电路和等离子体喷射反应器。 电源电路包括H桥控制器和驱动器，变压器和输出端口。 H桥控制器和驱动器配置为切换一对端子的电极性。 变压器的主要连接到H桥驱动器和控制器。 变压器的次级与第一电容器并联连接，并与电感器和第二电容器串联。 输出端口与第二电容器并联连接。 等离子体喷射器反应器包括电场发生器，扩散器和扩散器。 电场发生器包括产生电场的一对电极。 散流器提供氧气流。 扩散器供应一束水。 水和氧气流穿过电场。

公开(公告)号：US20130291794A1

公开(公告)日：2013-11-07

申请号：US13980263

申请日：2012-01-25

Applicant: Wataru Sanematsu ,  Akihiko Saitoh ,  Kenji Narita ,  Masaharu Machi

Inventor： Wataru Sanematsu ,  Akihiko Saitoh ,  Kenji Narita ,  Masaharu Machi

IPC: H05H1/24

CPC classification number: H05H1/24 ,  A45D27/46 ,  A61L2/14 ,  B08B7/0035 ,  C01B13/11 ,  C01B2201/64 ,  C01B2201/90 ,  C02F1/78 ,  H05H1/2406 ,  H05H2001/2412

Abstract: A plasma generator 1 includes a first electrode 12 provided in a gas storage section 5; and a second electrode 13 separated from the first electrode 12 and provided in a manner such that at least the portion coupled with the first electrode 12 is in contact with a liquid 17 in a liquid storage section 4. Electric discharge is caused between the first electrode 12 and the second electrode 13 so as to produce plasma in a gas region in the liquid 17 in the liquid storage section and produce hydroxyl radical from water contained in the liquid 17 and oxygen contained in the gas. A voltage controller 60 controls a voltage applied by a plasma power source 15 depending on conditions.

Abstract translation: 等离子体发生器1包括设置在气体存储部分5中的第一电极12; 以及与第一电极12分离并且以至少与第一电极12耦合的部分与液体存储部分4中的液体17接触的方式设置的第二电极13在第一电极12之间产生放电 12和第二电极13，以便在液体储存部分中的液体17中的气体区域中产生等离子体，并且从包含在液体17中的水和包含在气体中的氧产生羟基自由基。 电压控制器60根据条件控制由等离子体电源15施加的电压。

公开(公告)号：US20130224084A1

公开(公告)日：2013-08-29

申请号：US13884441

申请日：2011-11-09

Applicant: Joon-Hyung Lim ,  Jae-Sune Jun

Inventor： Joon-Hyung Lim ,  Jae-Sune Jun

IPC: C01B13/11

CPC classification number: C01B13/11 ,  B01J19/087 ,  B01J2219/0809 ,  B01J2219/0871 ,  B01J2219/0875 ,  C01B2201/64 ,  C01B2201/70 ,  C02F2201/782

Abstract: An ozone generating device includes three or more cooling channels each having a through-hole formed in a central region thereof and a coolant flow path formed therein. The cooling channels are arranged side by side such that the through-holes thereof overlap with one another. The ozone generating device further includes electric discharge units interposed between the cooling channels adjoining each other and configured to generate electric discharge when applied with a high voltage. Each of the electric discharge units has a central hole formed in alignment with the through-hole. The ozone generating device is configured such that, when the electric discharge units are applied with a high voltage with the cooling channels kept grounded, oxygen supplied to the electric discharge units is decomposed into ozone which in turn is discharged through an internal space defined by the through-hole and the central hole.

Abstract translation: 臭氧发生装置包括三个或更多个冷却通道，每个冷却通道都具有形成在其中心区域中的通孔和形成在其中的冷却剂流动路径。 冷却通道并排布置，使得其通孔彼此重叠。 臭氧发生装置还包括放置在彼此相邻的冷却通道之间并且被配置为当施加高电压时产生放电的放电单元。 每个放电单元具有与通孔对准形成的中心孔。 臭氧发生装置被配置为使得当放电单元被施加高电压而冷却通道保持接地时，供给到放电单元的氧气分解成臭氧，臭氧又通过由 通孔和中心孔。

公开(公告)号：US20130142705A1

公开(公告)日：2013-06-06

申请号：US13312333

申请日：2011-12-06

Applicant: David M. HOOPER ,  Robert T. REICHENBACH ,  Roland SCHNEIDER

Inventor： David M. HOOPER ,  Robert T. REICHENBACH ,  Roland SCHNEIDER

IPC: B01J19/08

CPC classification number: C01B13/11 ,  C01B2201/22 ,  C01B2201/64

Abstract: In accordance with at least one exemplary embodiment, a syringe, method and system for delivering a therapeutic amount of ozone are disclosed. An exemplary syringe can have a gas chamber and one or more electrodes. A portion of at least one electrode can be within the gas chamber. Alternatively, singularly or in conjunction, one or both electrodes can be attached to the outside of an exemplary syringe. One or more electrical contact points can be outside the gas chamber. Each electrical contact point can be connected to an electrode. Oxygen gas can provided within the gas chamber of the exemplary syringe. A medical ozone generator can be connected to the syringe via the electrical contact points. Corona discharge can be effectuated via the electrodes, which can result in an amount of ozone gas can being produced from the oxygen gas.

Abstract translation: 根据至少一个示例性实施例，公开了一种用于递送治疗量的臭氧的注射器，方法和系统。 示例性的注射器可以具有气体室和一个或多个电极。 至少一个电极的一部分可以在气体室内。 或者，单独地或联合地，一个或两个电极可以附接到示例性注射器的外部。 一个或多个电接触点可以在气室外部。 每个电接触点可以连接到电极。 氧气可以设置在示例性注射器的气室内。 医用臭氧发生器可以通过电接点与注射器连接。 可以通过电极实现电晕放电，这可以导致从氧气产生臭氧气体的量。

公开(公告)号：US08241563B2

公开(公告)日：2012-08-14

申请号：US12615350

申请日：2009-11-10

Applicant: Michael P. Kolve ,  Nathan W. Provance ,  Dennis L. Wagner

Inventor： Michael P. Kolve ,  Nathan W. Provance ,  Dennis L. Wagner

IPC: A61L9/00 ,  A61L2/00 ,  A62B7/08 ,  B01L1/04 ,  C01B13/10

CPC classification number: C01B13/10 ,  A61L2209/11 ,  A61L2209/111 ,  A61L2209/212 ,  C01B2201/64 ,  C01B2201/90

Abstract: An air sanitization system including a housing having an inlet and an outlet, an ozone generator disposed in the housing and positioned between the inlet and outlet, at least one fiber optic cable positioned in visible proximity to the ozone generator, a visible light detector, and a controller. The housing is configured to receive a flow of an oxygen-containing gas through the inlet, and the ozone generator generates ozone from the flow of oxygen-containing gas. The at least one fiber optic cable is configured to receive and transmit visible light from the ozone generator. The visible light detector detects an amount of visible light transmitted by the at least one fiber optic cable. The controller is in communication with the visible light detector for determining whether the amount of visible light transmitted by the at least one fiber optic cable corresponds to a failure of the ozone generator.

Abstract translation: 一种空气消毒系统，包括具有入口和出口的壳体，设置在壳体中并定位在入口和出口之间的臭氧发生器，定位在可见的邻近臭氧发生器的至少一根光缆，可见光检测器和 一个控制器 壳体构造成通过入口接收含氧气体的流动，臭氧发生器从含氧气体流中产生臭氧。 所述至少一个光纤电缆被配置为从所述臭氧发生器接收和透射可见光。 可见光检测器检测由至少一根光纤电缆传输的可见光量。 控制器与可见光检测器通信，用于确定由至少一根光纤电缆传输的可见光的量是否对应于臭氧发生器的故障。

公开(公告)号：US20110198209A1

公开(公告)日：2011-08-18

申请号：US13125233

申请日：2009-10-23

Applicant: Junichi Okuyama ,  Yasunori Hamano ,  Takahiro Matsuo ,  Yuka Yoshida ,  Hajime Kuwabara ,  Nobuhiko Kubota ,  Kazuo Uematsu ,  Kouichiro Wazumi

Inventor： Junichi Okuyama ,  Yasunori Hamano ,  Takahiro Matsuo ,  Yuka Yoshida ,  Hajime Kuwabara ,  Nobuhiko Kubota ,  Kazuo Uematsu ,  Kouichiro Wazumi

IPC: F25C1/00 ,  B01J19/08

CPC classification number: A23L3/37 ,  A23B4/08 ,  C01B13/10 ,  C01B2201/64 ,  C01B2201/82 ,  F25C1/00 ,  F25C2400/12 ,  F25D2303/085 ,  Y02E60/366

Abstract: A method for manufacturing ozone ice that is improved for its storage stability is provided. In the method, ice 11 including oxygen gas g2 as gas bubbles b is produced and the produced ice 11 is irradiated with ultraviolet radiation, then the oxygen gas g2 in the ice 11 is ozonized to manufacture ozone ice 1.

Abstract translation: 提供了一种用于制造臭氧冰的方法，其改进了其储存稳定性。 在该方法中，产生包含作为气泡b的氧气g2的冰11，用紫外线照射产生的冰11，然后使冰11中的氧气g2臭氧化，制造臭氧冰1。

公开(公告)号：US07892502B2

公开(公告)日：2011-02-22

申请号：US11482508

申请日：2006-07-07

Applicant: Vitaly J. Berkman ,  Thomas J. Ryan

Inventor： Vitaly J. Berkman ,  Thomas J. Ryan

IPC: B01J19/08

CPC classification number: C01B13/11 ,  C01B2201/40 ,  C01B2201/64 ,  C01B2201/90 ,  G05D11/138 ,  Y10T137/0318

Abstract: An improved system and method for controlling ozone concentration in connection with a multi-chamber tool. The system and method involve a first and a second concentration controller in combination with an ozone generator. The first concentration controller detects an EVENT (i.e., one of the chambers in the multi-chamber tool coming on-line or off-line) and in response provides a power instruction to the ozone generator in accordance with a predictive control algorithm. The first concentration controller has a fast (i.e, about 1 second) response time. The second concentration controller is masked from the ozone generator during the EVENT, but otherwise controls the generator after an interval of time has lapsed after the EVENT. The second concentration controller has a slower response time than the first concentration controller, however the second concentration controller provides the system with long-term stability and can be used to provide updated data to the predictive control algorithm.

Abstract translation: 一种用于控制与多室工具相关的臭氧浓度的改进的系统和方法。 该系统和方法涉及与臭氧发生器组合的第一和第二浓度控制器。 第一集中控制器检测EVENT（即，多室工具中的一个室内进行在线或离线），并且响应于根据预测控制算法向臭氧发生器提供功率指令。 第一个浓度控制器具有快速（即约1秒）响应时间。 在EVENT期间，第二个浓度控制器被从臭氧发生器屏蔽，但是在EVENT之后经过了一段时间后才控制发电机。 第二浓度控制器具有比第一浓度控制器更慢的响应时间，然而第二浓度控制器为系统提供长期稳定性，并且可以用于向预测控制算法提供更新的数据。