序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
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1 | 一种供电单元 | CN201480038817.6 | 2014-06-04 | CN105359372A | 2016-02-24 | S.A.林德曼 |
本发明涉及一种供电单元和一种用于操作供电单元的方法,该供电单元包括连接到激励电路的变压器,该激励电路被适配为连接到电源,该次级绕组连接到至少一个第一供电单元。根据现有技术的是基于已知的反激技术的开关模式供电单元。待决申请的目的是具有功率入口、具有多个单独的功率出口的供电单元。如果连接到初级绕组的线路之一进一步连接到放电控制电路,该放电控制电路进一步连接到至少一个第二供电单元,则能够实现该目的。待决申请中,初级绕组进一步连接到至少一个另外的供电单元所连接的放电电路。 | ||||||
2 | 将光导纤维用于基于太阳能的发电厂的阴影检测器件 | CN201210197515.6 | 2012-06-15 | CN102832847A | 2012-12-19 | Y.N.门德斯埃尔南德斯; O.迈尔; M.策特尔; O.斯特恩; T.费伦奇; M.施米德特 |
本发明将光导纤维用于基于太阳能的发电厂的阴影检测器件,基于太阳能的发电系统(10)可以包含响应太阳辐射率的部件(12)的阵列。部件可以放置于场(11)上的各个位置上。该系统还可以包含具有耦合到该部件阵列并且安排为接收太阳辐射率的各个第一端(18)的多个光纤(16)。多个光纤(16)可以具有安排为输出指示在场(11)的各个位置上的各个太阳辐射率水平的各个光信号的各个第二端(20)。可以耦合光电电路(22)以接收来自该多个光纤(16)的各个光信号并且产生指示呈现在场(11)的各个位置的至少一个或多个上的阴影状况的各个信号。 | ||||||
3 | 基于交流调压电子开关的瞬变阻抗变压器 | CN201410034576.X | 2014-01-25 | CN103762599B | 2016-02-17 | 孙崇山 |
发明名称:基于交流调压电子开关的瞬变阻抗变压器摘要:本发明阐述了三个概念—分别为柔性调压、柔性交流变电、柔性输变电,提出了三种新技术—瞬变阻抗技术,柔性无级调压技术和柔性有级调压技术。瞬变阻抗技术是高速调节变压器阻抗或高或低的技术,即在正常情况时该变压器在阻抗、能耗各方面看,只是一台普通阻抗变压器甚或是低阻抗变压器,当突发短路或极端情况发生时,这台普通变压器瞬间变成高阻抗变压器或超高阻抗变压器,当突发情况消除时,又瞬间恢复成一台普通阻抗变压器。本发明主要应用于高压特高压交直流输变电系统,需要高速调压稳流系统、需要控制谐波的大容量无级调压系统,需要智能化控制的及对安全稳定性要求高的电力系统。 | ||||||
4 | 用于根据内部电阻调节负载电流的方法及装置 | CN201410306870.1 | 2014-06-30 | CN104283209A | 2015-01-14 | 温弗里德·默尔 |
本发明涉及用于在负载的操作期间调节负载电流的方法及装置,其中负载经由负载连接而连接至供电系统的供电线。供电系统的在负载连接上有效的内部电阻被确定并且用于调节负载电流。本发明的基本思想是基于对供电网的内部电阻的确定和监视,以便及早识别潜在风险并且开始适当的测量。根据所确定的内部电阻值,可以对关于供电系统例如建筑设施的从对供电电缆出口中的供电线的主电力分配到负载连接的品质做出说明。 | ||||||
5 | 基于交流调压电子开关的瞬变阻抗变压器 | CN201410034576.X | 2014-01-25 | CN103762599A | 2014-04-30 | 孙崇山 |
本发明详细阐述了基于波形连续和消谐波观点的波形叠加原理,提出了三个概念分别为柔性交流变电、柔性输变电、柔性调压。提出了三种新技术分别为瞬变阻抗技术,柔性无级调压技术和柔性有级调压技术。提出了三种新产品为交流调压电子开关、瞬变阻抗变压器、高速调压变压器。提出了六种高压电网联结方式为瞬变阻抗变压器型的电网联结方式,瞬变阻抗升压自耦变压器型的电网联结方式等。提出了一种新的无功补偿联结方式为无功补偿装置可以串并联在串变调压变压器主变压器二次出线的端口处。本发明可应用于高压特高压交直流输电和其他需要安全、高效、同步控制系统,需要大容量无级调压的系统。 | ||||||
6 | 直列変換調圧変圧器 | JP2018134438 | 2018-07-17 | JP2018191510A | 2018-11-29 | ▲孫▼崇山 |
【課題】高圧・特別高圧電力システムの安定性と確実性の増加する直列変換調圧変圧器を提供する。 【解決手段】調圧原理は、一つの定電圧(または調整が可能な電圧で、交流調圧器が位相制御時の電圧は一定である)の正弦波の交流電源(習慣によると定電圧の電源と呼ぶ)に交流調圧器により制御される一つの交流電源(調圧電源)を直列接続する。二つの電源は、波形重畳原理により一つの電圧波形が連続している同周波数の周期波を出力する。高調波を発生させる容量は、従来の交流電力制御回路におけるすべての容量を調整して発生する高調波から調圧範囲(調圧電源の容量)の容量により発生する高調波の量のみ残るようになり、高調波の含有量は大幅に低下する。 【選択図】なし |
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7 | 交流電圧網に接続するための配電システム | JP2017548184 | 2016-03-31 | JP2018518006A | 2018-07-05 | フイッシャー エーリッヒ; ハラー フーベルト; トーマス リーガル; ファム タン フィ; ジーベル ユルゲン |
本発明は、交流電圧網(4)に接続するための配電システム(1)であって、途切れることなく電源供給を行うUSV電源部(2)を備え、USV電源部(2)は、電圧網側の入力部(EAC)と少なくとも1つの出力部(AAC)とを有し、出力部(AAC)には、並列の負荷回路(Lm)において多数の負荷(10)が接続されている、または、接続可能である、配電システム(1)に関する。前記負荷回路(Lm)または各負荷回路(Lm)において、電気機械式、特に熱磁気式の引外し装置(12)と、評価および引外しユニット(17)とを備える保護装置(GSm)が接続されており、前記評価および引外しユニット(17)は、電子的過負荷および/または短絡特性曲線(KE,KUE,KK)に基づき、および、USV電源部(2)の出力電圧(UAC,Uist)に応じて、前記引外し装置(12)を作動させる。 | ||||||
8 | 電力システムの改善された安定性のためのシステム及び方法 | JP2016080776 | 2016-04-14 | JP2016208826A | 2016-12-08 | チャイタニヤ・アショク・バオーネ; ナレッシュ・アチャリヤ; ニランジャン・レイ・チョウドリー |
【課題】発電システムの発電再ディスパッチを使用して電力システム振動安定性を強化するのに適した技法を提供する。 【解決手段】プロセッサ38を含む発電再ディスパッチ最適化(GRDO)システム10であって、プロセッサは、複数のグリッドシステム偶発事故から少なくとも1つのグリッドシステム偶発事故を選択するように構成される。プロセッサは、少なくとも1つのグリッドシステム偶発事故に基づいて1つ又は複数の固有感度値を導出するように更に構成される。プロセッサはまた、固有感度値に少なくとも部分的に基づいて1つ又は複数の制御アクションを導出するように更に構成される。プロセッサは、電力グリッドシステムの発電再ディスパッチのために1つ又は複数の制御アクションを適用するように更に構成される。 【選択図】図1 |
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9 | POWER SUPPLY | EP14731148.4 | 2014-06-04 | EP3008789B1 | 2018-10-31 | LINDEMANN, Stig Alnøe |
A power supply and a method for operating the power supply in which a transformer connected to an excitation circuit which is adapted to be connected to a power source, which secondary winding is connected to at least one first power supply. From prior art. switch mode power supply based on fly back technology is well known. Here a power supply with a power inlet is provided with a plurality of separated power outlets. One of the lines connected to the primary winding is further connected to a discharge control circuit, which discharge control circuit is further connected to at least one second power supply and the primary winding is further connected to a discharge circuit where at least one further power supply is connected. | ||||||
10 | TRANSIENT IMPEDANCE TRANSFORMER BASED ON AC VOLTAGE ADJUSTMENT ELECTRONIC SWITCH | EP14879717 | 2014-01-25 | EP3098925A4 | 2017-10-11 | SUN CHONGSHAN |
11 | Shadow detection apparatus using fiber optics for solar-based power generation plants | EP12171480.2 | 2012-06-11 | EP2544015B1 | 2017-08-09 | Mendez Hernandez, Yaru Najem; Mayer, Oliver; Zettl, Marcus; Stern, Omar; Ferenczi, Toby; Schmidt, Michael |
12 | Apparatus of sliding submodule | US15869975 | 2018-01-12 | US10141724B2 | 2018-11-27 | Teag Sun Jung; Woong Hyeob Song |
An apparatus of sliding a submodule includes a sliding rail part installed on one side of a cabinet; a submodule capable of being entered into or withdrawn from the cabinet; and a sliding guide part installed at one side of the submodule and slidingly moved by the sliding rail part. The sliding rail part may include a rail body, first and second extending parts extending from opposite ends of the rail body, and first and second sliding rails connected to the first and second extending parts respectively and protruding toward the sliding guide part. | ||||||
13 | Power supply | US14898169 | 2014-06-04 | US09991708B2 | 2018-06-05 | Stig Alnøe Lindemann |
A power supply and a method for operating the power supply in which a transformer connected to an excitation circuit which is adapted to be connected to a power source, which secondary winding is connected to at least one first power supply. From prior art. switch mode power supply based on fly back technology is well known. Here a power supply with a power inlet is provided with a plurality of separated power outlets. One of the lines connected to the primary winding is further connected to a discharge control circuit, which discharge control circuit is further connected to at least one second power supply and the primary winding is further connected to a discharge circuit where at least one further power supply is connected. | ||||||
14 | UNINTERRUPTIBLE POWER SUPPLY DEVICE | US15568895 | 2015-06-02 | US20180102647A1 | 2018-04-12 | Keisuke OHNISHI |
An uninterruptible power supply device is basically a device that performs a full-time inverter feeding system using a first semiconductor switch, and when a second semiconductor switch, which is an optional item, is connected in parallel to the first semiconductor switch and a full-time bypass feeding system is selected, serves as a device that performs the full-time bypass feeding system using the second semiconductor switch. This leads to a low device cost compared with the case in which an uninterruptible power supply device employing the full-time inverter feeding system and an uninterruptible power supply device employing the full-time feeding system are designed and manufactured separately. | ||||||
15 | RECONFIGURABLE POWER CONTROL SYSTEM | US15600298 | 2017-05-19 | US20170288411A1 | 2017-10-05 | Matthew Wootton; John Wootton; Justin McKinney; Lloyd Herbert King, JR. |
Systems and methods for the creation of a centrally controlled DC and AC power rail system within a structure. The rails utilize a centralized controller along with a plurality of distributed controllers to allow for power in the rails to be selectively distributed or not distributed to outlets attached to the rails. This allows for power to be distributed without the need for users to utilize hardwired switches, but to instead utilize generally wireless switch modules, which may be implemented in hardware and/or software to control the outlets. It also allows for devices designed to utilize DC power to be directly supplied with such power from the DC power rail without the need to include onboard AC-DC converters with each device. | ||||||
16 | CLAMPING CIRCUITRY | US15212077 | 2016-07-15 | US20170149326A1 | 2017-05-25 | David L. Mackey; James R. Newton; Matthew T. Long |
The present disclosure relates generally to a power source, a clamping device in electrical communication with the power source, wherein the clamping device is configured to redistribute a current generated by the power source, and a load in electrical communication with the clamping device and the power source. | ||||||
17 | Shadow detection apparatus using fiber optics for solar-based power generation plants | US13160762 | 2011-06-15 | US08395279B2 | 2013-03-12 | Yaru Najem Mendez Hernandez; Oliver Mayer; Marcus Zettl; Omar Stern; Toby Ferenczi; Michael Schmidt |
A solar-based power generation system may include an array of components responsive to solar radiance. The components may be disposed over respective locations on a field. The system may further include a plurality of optical fibers having respective first ends coupled to the array of components and arranged to receive solar radiance. The plurality of optical fibers may have respective second ends arranged to output respective optical signals indicative of respective levels of solar radiance over the respective locations of the field. Opto-electrical circuitry may be coupled to receive the respective optical signals from the plurality of optical fibers and generate a respective signal indicative of a shadow condition present over at least one or more of the respective locations of the field. | ||||||
18 | Constant current class 3 lighting system | US10799741 | 2004-03-12 | US20050200308A1 | 2005-09-15 | Philip Rimmer; Carole Sherrington |
A lighting system having a power supply and at least one luminaire. The power supply includes a power supply input to receive a first signal having a first frequency and a circuit for converting the first signal to a second signal. The power supply also includes at least one power supply output to output a second signal having a substantially constant current and a second frequency distinctly higher than the first frequency. The luminaire includes a lamp coupled to a lamp driver circuit, which has an input for receiving the output signal from the power supply and which is configured to use the received output signal to operate the lamp. The lamp driver input and the power supply output may be connected by a flexible cable. | ||||||
19 | Electrical [arrangement] distribution system for vehicle | US68972 | 1993-05-28 | US5465010A | 1995-11-07 | Philip J. Rimmer |
An electrical arrangement is disclosed for use in supplying electrical power to the units in a motor vehicle. The arrangement comprises a battery, and an inverter to receive power from the battery and to generate a high frequency signal at an intermediate voltage higher than the voltage of the battery. There is a distribution network to distribute the high frequency signal to the units in the vehicle. At least some of the units supplied with electrical power are provided with step-up transformers to step-up the intermediate voltage to a higher voltage, that higher voltage being used by the units. | ||||||
20 | Supply source for electrical plants, furnishing a current the magnitude of which is independent of load impedance | US11864471 | 1971-02-25 | US3703643A | 1972-11-21 | ILINSKY NIKOLAI FEDOTOVICH; GUTTERMAN KIRILL DAVIDOVICH; MIKHAILOV VADIM VLADIMIROVICH |
Supply source for electrical plants, providing a current the magnitude of which is independent of load impedance, wherein the supply source is characterized in that it includes two voltage sources which are arranged whereby each may be regulated relative to the other, and wherein each is connected between one of two reactances and star connected with the load. The supply source enables the load current to be varied in any pre-determined manner for zero to a definite maximum value.
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