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公开(公告)号:US20210215761A1
公开(公告)日:2021-07-15
申请号:US16744109
申请日:2020-01-15
Inventor: Wei-Min Hsiao , Shih-Chang Tseng , Kuo-Kuang Jen , Gwo-Huei You , Chih-Hsien Chung
IPC: G01R31/364 , G01R31/36 , H01M10/42 , H01M10/48
Abstract: The present invention discloses an external battery short-circuit testing device, configured to perform short-circuit test on a battery pack under test. The external battery short-circuit testing device comprises a plurality of fuses; a Hall current transducer, coupled to the plurality of fuses; a current meter, coupled to the Hall current transducer and the battery pack under test; a voltmeter, coupled to the battery pack under test; a variable resistor, coupled to the Hall current transducer; an electromagnetic switch, coupled to the variable resistor and the battery pack under test; and an operation unit, comprising a voltage measurement unit, a current measurement unit, a temperature measurement unit and a switch control unit.
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公开(公告)号:US20210156956A1
公开(公告)日:2021-05-27
申请号:US16695118
申请日:2019-11-25
Inventor: SHIH-CHE TSAI , JER-LONG CHEN , MIN-CHING LIN , RUEI-SHEN WANG , YOU-HENG WEI
Abstract: A continuous wave radar system comprises a substrate, a transmitter disposed on the substrate, a receiver disposed on the substrate, and an isolating device comprising a plurality of metal plates parallelly disposed on the substrate between the transmitter and the receiver for isolating leakage signal transmitted from the transmitter to the receiver. The metal plates are grounded with the transmitter and the receiver via electrical connection between the metal plates and the substrate. The metal plates are so arranged that an eddy current induced in each of the metal plates is directed away by grounding when the leakage signal passes through the metal plates.
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公开(公告)号:US10913553B2
公开(公告)日:2021-02-09
申请号:US15813343
申请日:2017-11-15
Inventor: Mau-Yi Huang , Ren-So Deng , Geng-Wen Chang , Dar-Ping Juang , Cheng-Huan Wang
Abstract: An integrated heat shield which encloses a frame structure comprises a leading edge component, a left side component, a right side component, an optionally top component, an optional bottom component and an optional trailing edge subassembly, wherein the leading edge component and the left and right side components are directly, integrally co-cured on the frame structure while in a B-stage. The leading edge component and the left and right side components are shingle laminated to form ply angles to air flow. The leading edge component and the side components are scarf-jointed or step-jointed. The side components and trailing edge subassembly are also scarf jointed or step-jointed. The co-curing as well as the scarf or step joints makes the heat shield an integrated assembly. A method of manufacturing the integrated heat shield is further introduced.
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公开(公告)号:US20200310538A1
公开(公告)日:2020-10-01
申请号:US16367266
申请日:2019-03-28
Inventor: Po-Lei Lee , Hao-Teng Hsu , Shyh-Jian Tang , Chia-Lung Yeh , Yun-Ru Chen , Yi-Ju Chiang
IPC: G06F3/01 , A61B5/0484
Abstract: A method for recognizing brainwave signals of a brain-computer interface (BCI), includes determining a steady-state visual evoked potential (SSVEP) corresponding to an Oz electrode channel according to the brainwave signals when in a rest state; determining the SSVEPs respectively corresponding to the Oz electrode channel, an O1 electrode channel and an O2 electrode channel according to the brainwave signals when in a stimulating state; and determining a stimulus source of a glance attention according to the SSVEPs of the O1 electrode channel and the SSVEP of the O2 electrode channel; wherein the glance attention stimulates the brainwave signals when in the stimulating state.
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公开(公告)号:US10780504B2
公开(公告)日:2020-09-22
申请号:US15815728
申请日:2017-11-17
Inventor: Yi-Lun Xiao , Li-Tsung Sheng , Shu-San Hsiau , Kuo-Kuang Jen , Chih-Peng Chen , Po-Shen Lin , Chung-Chun Huang
Abstract: A powder recycling system includes a supply tank, a continuous loss-in-weight module, a pneumatic module, a transfer channel, a recycle module, and a refilling tank. The supply tank accommodates recycling powder. The continuous loss-in-weight module includes a storage tank receiving the recycling powder from the supply tank and a rotary output pipe connected to the storage tank to output the recycling powder. The continuous loss-in-weight module controls the mass flow rate of the output of the recycling powder according to the weight change of the storage tank. The pneumatic module enables the recycling powder to float and move in the transfer channel. The recycle module is connected to the transfer channel to receive the recycling powder, sieves the recycling powder, provides virgin powder, and mixes the virgin powder with the recycling powder. The refilling tank is connected to the recycle module to receive the recycling powder and the virgin powder.
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Patent Agency Ranking
公开(公告)号:US10773270B2
公开(公告)日:2020-09-15
申请号:US16116891
申请日:2018-08-29
Inventor: Yi-Rong Zeng , Kuan-You Liu , Yu-Ping Wang , Chin-Cheng Wu , Min-Han Chiu , Yew-Shyang Lay
Abstract: A fluid cleaning apparatus includes a driving assembly including a motor, a gear clutching assembly, a moving assembly, a swaying spray assembly, a sensing assembly, and a controlling module. The fluid cleaning apparatus integrates functions of movement actuation and spraying angle adjustment with the motor and achieves versatile spraying angles for spray-cleaning with apparatus configuration convertible between swaying motion and ceased swaying motion and/or between moving motion and ceased moving motion. Besides, self-propelled movement, spraying pressure modulation, and spraying angle adjustment can be controlled by the control module or manually remotely controlled by a user. Since the fluid cleaning apparatus of the present application saves the conventional installation cost and space needed, as well as resources consumed, for cleaning the bottom of an object to be cleaned, the fluid cleaning apparatus can be extensively applied to multiple fields.
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17.发明申请公开(公告)号:US20200273626A1
公开(公告)日:2020-08-27
申请号:US16283833
申请日:2019-02-25
Inventor: Chien-Liang Chang , Wu-Ching Hung , Jeng-Kuei Chang , Bo-Rui Pan
IPC: H01G9/042 , H01G9/035 , C01B32/194
Abstract: In this patent, a high energy and power density supercapacitor was invented. A coin cell with supercapacitor includes a spring lamination, a working electrode, a counter electrode, a separator, and an Organic electrolyte. The working and counter electrodes were Activated carbon/N-doping porous graphene/binder coated on Aluminum substrate. The separator was from Nippon Kodoshi Corporation. The Organic electrolyte was 1M TEABF4/PC. The method of producing N-doping porous graphene included the following steps: Step 1: Graphite oxide (GO) was transferred into the furnace. Step 2: Inject 50 c.c./min gas flow of Nitrous oxides for one hour. Step 3: Intensify 40 Celsius degrees/min to 900 Celsius degrees and after holding for one hour, lower the temperature naturally to the room temperature, it can be prepared into N-doping porous graphene. In this patent, the capacitance of the supercapacitor is 122 F/g and the power density is 31 kW/Kg.
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公开(公告)号:US20200219655A1
公开(公告)日:2020-07-09
申请号:US16239500
申请日:2019-01-03
Inventor: Shao-Wei Peng , Hung-Ting Chou , Chien-Te Yu
Abstract: A capacitor array with staggered-layer structure includes a plurality of capacitor units. Each of the plurality of capacitor units comprises a plurality of odd layers formed with a first slot; a first via formed in the first slot; a plurality of first connecting portion configured to connect the first via and the plurality of odd layers; a plurality of even layers formed with a second slot; a second via formed in the second slot; a plurality of second connecting portion configured to connect the second via and the plurality of even layers; wherein one of the plurality of odd layers is adjacent to one of the plurality of even layers to form a staggered-layer structure.
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19.发明授权公开(公告)号:US10598778B2
公开(公告)日:2020-03-24
申请号:US15825338
申请日:2017-11-29
Inventor: Chia-Yu Yao , Shao Chen , Chien-Te Yu
Abstract: A phase controller for an antenna array includes a determination circuit, determining a direction index of the antenna array, and calculating a phase index according to the direction index according to a congruence modulo equation; a switching box, selecting L first frequency signals with L different first phases among K first frequency signals with K different first phases according to the phase index, wherein L and K are integer larger than 1, and L is not larger than K; and a frequency synthesizing module, comprising L phase-coherent PLL frequency synthesizers for receiving the L first frequency signals with the L different first phases to generate L second frequency signals with L different second phases to L antennae of the antenna array, wherein a second frequency of the second frequency signals is larger than a first frequency of the first frequency signals.
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公开(公告)号:US10573182B2
公开(公告)日:2020-02-25
申请号:US15839101
申请日:2017-12-12
Inventor: Li-Feng Yang , Chien-Jung Chiu
IPC: G08G1/16 , G01S13/93 , G01S13/34 , B60W30/09 , B60W50/14 , G08G5/00 , B60W30/095 , G08G5/04 , G01S13/931
Abstract: A collision avoidance apparatus for a vehicle includes a data collection module, collecting first automatic dependent surveillance broadcast (ADS-B) data of the vehicle itself, second ADS-B data of at least other one vehicle and a detection result related to a radar reflection wave reflected from an object within a first range; and a possible collision determination/avoidance module, electrically connected to the data collection module, determining whether the other one vehicle will collide with the vehicle according to the first and second ADS-B data and whether the object will collide with the vehicle according to the detection result, so as to generate a determination result, wherein the signal processing module generate a control signal to control the vehicle perform a corresponding action according to the determination result. Thus, collision avoidance can be achieved.
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