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Please do not offer the downloaded file for sell only use it for personal usage. Looking for other manual? For this no need registration. May be help you to repair. You could suffer a fatal electrical shock. Instead, contact your nearest service center. Note! To open downloaded files you need acrobat reader or similar pdf reader program. In addition, Also some files are djvu so you need djvu viewer to open them. These free programs can be found on this page: needed progs If you use opera you have to disable opera turbo function to download file. If you cannot download this file, try it with CHROME or FIREFOX browser. Translate this page: Relevant OTHER forum topics: Aixam 400 moped autoba feszultseg szabalyozo kapcsolas Sziasztok! A cimbeli autorol van valakinek rajza. Tovabba mi adja a delejt benne dinamo vagy generator. Allitolag mechanikus feszszabalyzo van benne ami rossz es ezt kellene kivaltani elektronikussal.(meg nem lattam) Valami egyszeru rajz kellene.Van egy BENQ MP610 DLP-s projektorom, es egy szamomra eleg komoly hibaval szembesultem. A vetitett kepen egy fuggoleges csik van, a kozepetol kicsit jobbra. Eloszor a DLP chipre gyanakodtam, de homogen hatteren van hogy teljesen eltunik(leginkabb kek hatteren nem latszik), illetve ha a projektor PAUSE funkciojaval kimerevitem a kepet, akkor a csik is az eppen aktualis allapotaban kimerevedik.Ez szerintem kizarja a szinkerek hibat is, mert tartja a szinet. Fuggetlen az eppen hasznalt bemenettol, a boot kepernyon is jelen van. Nagyon megkoszonnem ha valaki tudna valami hasznos tanacsot adni. LED lampak fenyeroszabalyzasa udv:kivancsisagbol kerdezem.Balint If you want to join us and get repairing help please sign in or sign up by completing a simple electrical test or write your question to the Message board without registration. You can write in English language into the forum (not only in Hungarian).
http://logenamerica.com/userfiles/ezon-2320-manual.xml
In this page you find schematic, users and instructions manuals, service manuals, technical supplement, leaf leads and other good stuff. If you have some stuff that not is listed here you can donate this by contact mods.dk. And when you click on the file or icon it will count as a download. If you want to see manuals from other manufactories you can click on the manufactory menu in the left side. You can also click here to see all the manufactories that mods.dk have manuals, schematics or other files from. It is much more versatile than an internal filter. It really pulls signals out of the mud. Buy one if you can find one! When used for SSB operation the auto-notch will lock on and track almost instantaneusly. For CW operation the bandwidth can be wound down to around 50Hz with no sign of ringing (a common problem with cheaper AF filters) and there is even an AFC facility to track the change in pitch of the signal. Overall extremely easy to use. There is also a front panel headphone socket. Datong uk no longer manufacture amateur radio products. A great loss in my opinion as they made some really excellent products. Prior to its acquisition, I owned an Autek QF-1A. The FL1 is superior to the QF-1A in every respect. Dr. David Tong of the UK designed some exceptional products in the '70s and '80s. I prefer the FL1 for CW use over all the other filters currently on the market, including all of the external DSP filters. The FL1 controls are smooth, large enough to easily control with normal-sized fingers, and it simply works. The filter bandpass is easily adjustable and the filter provides sufficient stop band rejection without any ringing. I've used every external DSP audio filter, and I keep coming back to the FL1 and the later Datong FL3. No doubt, both are the pinnacle of analog op amp audio filter design. Some of the connectors on the back panel are UK-type connectors, but they are easy to find, or change out if necessary.They should fire it's designer for this.
http://www.salmododia.com.br/imagens/imagens_usuarios/ezpro-610h-manual.xml
The sharp skirts of the Timewave filtering looks great on paper, but it makes listening rather unpleasant in SSB. That's why on very expensive transceivers, you can set the DSP skirts to steep or gradual (gradual - like the FL1 - hi). That's for instance the reason why the TS570 sounds so good (gradual DSP filtering). The Timewave is nice for cw although it produces more ringing than the FL1 on very narrow filter settings. The Datong is not for sale. When you subscribe, you receive only messages forOther useful informationThe site will be something of which everyone involved can be proud to say they were a part. Contact the site with comments or questions. Learn more - opens in a new window or tab This amount is subject to change until you make payment. For additional information, see the Global Shipping Programme terms and conditions - opens in a new window or tab This amount is subject to change until you make payment. If you reside in an EU member state besides UK, import VAT on this purchase is not recoverable. For additional information, see the Global Shipping Programme terms and conditions - opens in a new window or tab Delivery times may vary, especially during peak periods. Learn More - opens in a new window or tab Learn More - opens in a new window or tab Learn More - opens in a new window or tab Learn More - opens in a new window or tab Learn More - opens in a new window or tab Learn more The item may have some signs of cosmetic wear, but is fully This item may be a floor model or an item that has been returned to the seller after a period of use. See the seller’s listing for full details and description of any imperfections. Contact the seller - opens in a new window or tab and request a postage method to your location. Please enter a valid postcode. Please enter a number less than or equal to 0. All Rights Reserved. User Agreement, Privacy, Cookies and AdChoice Norton Secured - powered by Verisign.
For example, the grantee code for FCC ID: 2AMBSTWX5G02-1 is 2AMBS. The remaining characters of the FCC ID, TWX5G02-1, are often associated with the product model, but they can be random. These letters are chosen by the applicant. In addition to the application, the FCC also publishes internal images, external images, user manuals, and test results for wireless devices. Purchase on Amazon:The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operated in conjunction with any other antenna or transmitter. The antenna installation and operating configurations of this transmitter, including any applicable source-based time-averaging duty factor, antenna gain and cable loss must satisfy MPE categorical Exclusion Requirements of part 2.1091. Users must be provided with instructions and transmitter operating conditions for satisfying RF exposure compliance. This device contains functions that are not operational in U.S. Territories. This filing is only applicable for U.S. operations. See 47 CFR 1.2002(b) for theAll of the statements herein and theIn accepting a Grant of Equipment Authorization as a result of the representations made in thisIf the applicant is not the actual manufacturer of the equipment, appropriate arrangementsIt is understood that the letter of authorization must be submitted to the FCC upon request,The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operated in conjunction with any other antenna or transmitter. Users must be provided with instructions and transmitter operating conditions for satisfying RF exposure compliance. See 47 CFR 1.
2002(b) for theAll of the statements herein and theIn accepting a Grant of Equipment Authorization as a result of the representations made in thisIf the applicant is not the actual manufacturer of the equipment, appropriate arrangementsIt is understood that the letter of authorization must be submitted to the FCC upon request,Click an above application to view details The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operated in conjunction with any other antenna or transmitter. Users must be provided with instructions and transmitter operating conditions for satisfying RF exposure compliance. North 4th Ring Road West,Haidian District Beijing, ChinaThe antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operated in conjunction with any other antenna or transmitter. Users must be provided with instructions and transmitter operating conditions for satisfying RF exposure compliance. The antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operated in conjunction with any other antenna or transmitter. This device contains functions that are not operational in U.S. Territories. This filing is only applicable for U.S. operations. North 4th Ring Road West,Haidian District Beijing, ChinaThe antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operated in conjunction with any other antenna or transmitter. This device contains functions that are not operational in U.S. Territories. This filing is only applicable for U.S. operations. Click an above grant to view details. This does not affect the rights licensed or assigned from any third party in this book.
The chapter is from the book Best Practice Guide on the Control of Arsenic in Drinking Water, Prosun Bhattacharya, David A. Polya and Dragana Jovanovic (Eds.). Besides the large number of important papers, reports and reviews already available on various aspects of arsenic occurrence in environment, water and food and related human exposure, this book fills a gap in the field concerning assessment of risks, implications, challenges, and actions required by public health managers. It focuses only on the key aspects of risk assessment, management and communication relevant to higher levels of arsenic in drinking water, which are geological factors, the extent of arsenic occurrence, total exposure of arsenic and the role of drinking water, including regulatory aspects as well as technical (treatment) issues. The Best Practice Guide on the Control of Arsenic in Drinking Water tries to raise public awareness on this subject, which seems to be low and risks are being underestimated in a number of regions. This is especially valid for Europe although less for other regions which are typically more contaminated with arsenic. The referred practices conform to the recommendations of the World Health Organisation (WHO), the European Food Safety Authority (EFSA) and the U.S. Environmental Protection Agency (EPA). It is a useful guide for drinking water suppliers, experts of municipalities, public health authorities, drinking water regulators and non-governmental organisations. ISBN: 9781843393856 (Paperback) ISBN: 9781780404929 (eBook) By continuing to use our website, you are agreeing to our privacy policy. UK For BC-220 UK For BC-119N For BP-206 For BP-217 For IC-M87 Input 12-16 VDC. Output 6 VDC, 1.5 A. Input 12-16 VDC. Output 6 VDC, 1.5 A. Can also be used in a wired fashion Can also be used in a wired fashion Waterproof For IC-F61M and IC-M87 For IC-2300, IC-3200A and IC-3200E English or japanese voice Non-rolling type. 32 codes Rolling type.
1020 codes Notch, bandpass, CW peaking and noise reduction For VR-5000 Up to 16 seconds of audio For VR-5000 Requires NC-7 or NC-8 North America 10 W Outside North America 10 W Requires SAD-20 For SBR-25LI, SBR-26LI and SBR-28LI Radio-to-radio KHz) IF: 455 KHz Front panel bracket and 6 m remote cable For FT-8800R and FT-8900R Recording and PC control Analog 157 steps Room for accessories High profile Low profile Rack mount For NC-240D (R) Table top For NC-240D (T) With WWV 10 MHz RX QRO version For CNB-151 or CBT-151 For CNB-152 or CNB-153 For CNB-151 or CBT-151 For CNB-152 or CNB-153 For CNB-150, CNB-151 and CNB-153. As an option, an optical cable failover is built inside the modules by adding a second connector. In case of fiber break the equipment automatically select the other cable. HD and PAL video ports are on BNC connectors. Optical and remote power access is done through a Neutrik OpticalCon DUO or LEMO 3K socket. Koscielna Droga, nr 105D, 05092, poczta Lomianki, Poland Vasile Lascar nr. 18, Etaj 3, Apt 24, sector 2, 020501 Bucuresti, Romania. Please upgrade your browser or activate Google Chrome Frame to improve your experience. On this page, you can download low-resolution PDFs of our Huawei specials, to be read online and on the go, at your convenience. 2020 pv magazine has partnered with Huawei for the fifth consecutive year with our 2020 Special Edition. This year’s publication highlights the PV industry’s movement into the Era of Artificial Intelligence, which is quickly advancing through information and communication technologies (ICT). View and read the entire 2020 publication online or download the PDF. 2019 Another year, and another Huawei special edition, ready for Intersolar Europe. View and download the entire 2019 pv magazine Huawei special here. 2018 Once again, we teamed up with Huawei to bring you a 44-page special edition, just in time for Intersolar Europe. View and download the 2018 pv magazine Huawei Special.
2017 This pv magazine special, developed in partnership with Huawei, made its debut at the Intersolar Europe exhibition on May 31. View and download the entire 40-page special edition. Articles produced in partnership with Huawei for the pv magazine special publications The evolution of solar intelligence Artificial intelligence (AI) is already transforming a range of industries, from the automation of trading decisions in the financial sector to the deployment of smart robots in factories. Solar has jumped on the AI bandwagon. In the PV industry, AI is now being used to help push solar toward grid parity in markets throughout the world. The International Renewable Energy Agency (IRENA) asserts that such technologies are already playing a “transformative” role in pushing the global energy transition forward, even while acknowledging that some people may already view terms such as AI, big data, the Internet of things (IoT), cloud computing, and blockchain as hackneyed buzzwords. However, these terms are part of the growing digitalization of electricity generation, distribution, and consumption. Powerful potential The potential of AI in energy has been known for years, and digitalization of the transmission sector is at an advanced stage, the International Renewable Energy Agency says in its report, Innovation Landscape for a Renewable-Powered Future. Although sensors have been installed in solar arrays from almost day one, the digitalization of generation and consumption is still at a relatively early stage. The next step, IRENA argues, will be to modernize power plants and further automate control of the grid. The role of AI in power systems is rapidly becoming a “necessity,” IRENA asserts, as it can help to more effectively integrate variable renewables into the grid by predicting generation and consumption patterns.
“Reductions in uncertainty in power production forecasts and power demand forecasts enable smarter operations,” agrees Elizabeth Traiger, senior researcher at energy consultancy DNV GL. “Unexpected curtailment can be reduced, and planned maintenance can be scheduled at optimal times.” Investors in new solar projects can use sensor data to provide an accurate picture of the generation possibilities at proposed sites, opening up financing potential. Solar arrays provide enormous amounts of data that are already being used in meteorology applications. “AI and machine learning algorithms are being proven in forecasting to improve the accuracy of short-term forecasts, up to 48 hours ahead,” explains Traiger. “By combining the wealth of meteorological ground station data, satellite weather data, and local cloud cover imagery, the irradiance, or available solar resource, can be more accurately estimated. The resulting reduction in uncertainty in solar power production helps to ensure a balanced and reliable electrical grid. Variability can be anticipated and alternate dispatch or adjustments to generation can be made more smoothly.” Scratching the surface Solar manufacturers are also starting to deploy AI in their factories to streamline production. JinkoSolar, for example, recently revealed plans to use AI at its 400 MW module factory in Florida, starting with electroluminescence inspections. However, the industry is still just scratching the surface of AI’s potential to push solar closer toward grid parity. Image: Huawei “The integration of AI will enhance the ability of solar to integrate in the dynamic energy mix,” says Traiger. “AI enables accurate, informed decisions in all data- heavy areas. For solar, this encompasses the entire value chain: feasibility, development, operations, and decommissioning. Making smart decisions ensures the best outcomes by adding reliability and reducing the variability inherent in renewable resources such as solar.
” That said, the solar industry still has a long way to go in more effectively exploiting data, she adds. “AI and machine learning is based on data. As we gather more data, from historical sources, past weather and production patterns, different spatial resolutions of new satellites, as well as new data from increased ground sensor installations, the tools will evolve,” Traiger says. Smarter storage As the global cost of solar continues to fall, developers increasingly struggle to reduce risks and improve returns on distributed generation PV projects. The ongoing decline in the cost of energy storage provides a ray of hope, but in order to truly leverage the power of storage, project operators need to utilize AI to provide new sources of value. These value streams include lower demand charges and the provision of higher revenue from virtual power plants (VPPs). California-based storage specialist Stem, for example, announced plans in late 2017 to install AI-backed storage solutions in Japan, a global hotbed for VPP deployment. Other recent AI-backed storage pilots noted by IRENA include French utility RTE’s Ringo Project, which aims to ease grid congestion without the need for new power lines, by using AI to facilitate dispatch. Image: Huawei Intelligent i nverters IHS Markit expects an uptick in the use of AI in the solar sector this year, and it sees inverters as playing a “critical role” in this shift. Sensors in inverters facilitate predictive maintenance, and many companies have taken notice of AI’s potential. Huawei, for example, has been exploring smart PV solutions for the past five years, as part of its efforts to accelerate grid parity with AI. Huawei’s AI-driven FusionSolar 1500V Smart PV Solution also boasts a number of features aimed at supporting the push toward grid parity. Many companies have long used automated drones for inspections to identify defects in advance. But inverters show promise to provide faster, better intelligence.
“Algorithms that can give early warning of faults such as inverter failures, or indicate any deviations from normal operating behavior will be instrumental in maintaining even higher levels of reliability for long-term reliance on consistent solar production,” says Traiger. A key aspect of this shift is the optimization of data collection, integration, and management. While companies such as Solarig have long used sensors to assess the impact of weather conditions on contractual performance requirements, Sureda argues that the challenge ahead is to further integrate such information with weather forecast- ing models to predict the output of PV plants. “AI applied to this analysis is crucial and will definitely help to improve plant operations in the near future by increasing the reliability of electricity generation models,” Sureda says. The growth of distributed-generation PV and technological advancements in AI have fuelled the proliferation of smart devices and demand-management services in recent years, contributing to significant changes in the global power sector, IRENA says. But the organization believes that developers need to launch more pilot projects in the years ahead to fully grasp the potential of digital solutions. “The disruptive potential is only beginning to be understood,” IRENA concludes. “It is far from being fully exploited.” Grid parity’s hackathon In October 2018, Huawei released its AI strategy and a full-stack, all-scenario AI portfolio solution. The company’s full-stack capabilities are based on a cloud-pipe-device strategy which connects enterprise intelligence, equipment, and intelligent terminals integrated with AI. Huawei has not only incorporated AI into its internal production, logistics, and processes, but has also joined with partners to promote the development of intelligent solutions across industries. In the energy sector, Huawei has been working with its industry partners to explore digital practices for smart PV since 2014.
Collectively, the companies are promoting artificial intelligence and digital technologies such as cloud computing, big data, Internet of things (IoT), and edge computing to work in synergy for further reduction in PV plant costs across the industry. The PV industry is embracing grid parity globally. Regions particularly rich in solar irradiation resource such as India, Spain, Latin America, and the Middle East, have ushered in the new era. By 2020, most parts of the world will be able to achieve full grid parity. Advancing the global energy transition is crucial to addressing climate change, and bringing LCOE down for grid parity will be the key element and driving force to a clean energy future across all markets. And Huawei is turning to AI to accelerate grid parity. Image: Huawei Taking the lead In the intelligent era, innovation has become the core competency among leading enterprises. According to IHS Markit, Huawei has been ranked number one in global PV inverter shipments for four consecutive years. The company attributes its successes to customer-oriented innovations that simplify complex problems through fully digital technologies in its electronics, chips, computing, and artificial intelligence. “Each inverter of Huawei is a smart sensor. AI auto-learning enables trackers and bifacial modules to be optimized using the tracking algorithm, which can provide an additional 0.5 to more than 1 in energy gains, according to Huawei. Informatization of PV devices for building smarter plants By combining digital components with AI algorithm controls, the solution enables the collection of high-precision digital information to improve energy yields. PV strings can be monitored with the precision of 0.5. Big data and AI algorithms are oriented to component-level monitoring and refine management to locate old and faulty devices. The Smart I-V Curve Diagnosis and AI recognition enable the smart diagnosis for multiple components in various scenarios.
Currently, the technology has been applied to more than 3 GW of PV plants worldwide. According to Huawei, one-click scanning of its Smart I-V Curve Diagnosis 3.0 ensures the scanning of all strings in a 100 MW PV plant in just 15 minutes. In the past, faults were cleared manually, which was time-consuming. Some faults might be ignored completely. “With discreteness analysis, a PV plant in the Shanxi province of China accurately had 283 faults located in half a day. After more than 20 days, the PV plant cleared almost all faults with the performance ratio (PR) improved by 2.52,” says Yan, “Traditional PV plants, however, take about two months or more to clear faults before feeding power to the mains power grid.” Grid-tied stability of PV plants based on AI algorithm control Huawei has established a precise mathematical model for different types of grid- tied scenarios and PV plant designs, and imported related data by testing the power grid waveforms of steel mills and electrified railways into the model. The mass of data is used to train the optimal grid-tied control algorithm. By doing this, Huawei ensures stable grid-tied power generation of inverters even if they have poor power grid waveforms. “The power quality meets or even outperforms standard requirements,” adds Yan. Health check reports Image: Huawei Huawei offers PV plant health check reports with customized indicators for controlling the operating status of PV plants in a one-click manner. Operations and maintenance managers can quickly find the causes of low energy yields and laggard PV strings, thereby liberating personnel from time-consuming inspection and data analysis, thus reducing labor costs. “The magic of this feature lies in the perfect combination of expertise and AI,” says Yan. Next generation inverters optimize bifacial boost Inverter makers are under pressure to upgrade performance to accurately measure and manage the boost from bifacial solar panels.
Inverter improvements including greater granularity of maximum power point tracking (MPPT), the marriage of artificial intelligence with more capable algorithms, and string overload safety are ushering in the next generation of inverters redesigned for bifacial systems, according to the development team at Huawei Technologies’ Smart PV Business. The complexity of matching inverters to bifacial panels arises from the dynamic and uneven light capture levels on the rear side of the panel over time. Different sources of reflected light on reflective surfaces with different albedos, or reflected light values, permutate to make bifacial light capture management no less than a symphonic performance for inverters. Huawei Technologies’ FusionSolar Smart PV Solution has refined inverter technology to address these issues, while providing substantial increases in bifacial system yields in the process. The moving target of the energy yield gain from the rear of the bifacial module varies depending on the scenario, but the energy yield can increase anywhere from 5 to 39, according to Huawei research. Beyond that base gain, the bifacial module can further increase the energy yield by 2 to 6 based on its performance in response to low light and low power loss under the working temperature, the researchers point out. Thus, the combined “ energy yield gains of a bifacial module can range from 7 to 45 when compared to a conventional monofacial poly-Si module, a goal the industry is eagerly pursuing. Inverter load flexibility critical Designing inverters for bifacial modules that are capable of managing a large and varying yield gain is a first basic task. If inverters are not upsized to efficiently match and adapt to the dynamically enhanced DC output from bifacial pan- els, then they will suffer from clipping and yield loss. Balancing the need for capability versus size is a delicate design problem.
Industry research on bifacial systems currently focuses on ray-tracing and view-factor models, based on 3D modeling, to narrow down the best targets for design optimization. While more details can be displayed by algorithms, computing is complex and time-consuming, which does not mesh well with improved inverter performance. Huawei has simplified and optimized the two models and launched an industry- leading intelligent design tool for bifacial module systems based on the 2D physical model, according to Shawn Gu, the Chief Scientist for Huawei’s Smart PV Business. Huawei Smart Design is the online design platform for the company’s Smart PV solution. Smart Design is used to assist in plant system design, including component selection and energy yield assessment. The tool can determine the balance point between calculation speed and design details, quickly and accurately calculating the optimal configuration of a bifacial module system. Huawei’s 2D modeling method increases the overall energy yield from a bifacial PV system by more than 3 com- pared with solutions provided by other standard design methods, says Gu. This further compounds the bifacial boost. Resolving overcurrent issues Secure and reliable protection design is another key attribute of the next-gen bifacial inverter. “Every two strings of the Huawei FusionSolar Smart PV Solution string inverter form one MPPT circuit and have a fuseless security protection solution. The design ensures that no risk will occur at overcurrent condition,” says Gu. At the same time, security risks, frequent fuse replacement, and energy yield loss caused by fuse faults are avoided. Inverter anticipation of a fault is another key capability for bifacial system design. Huawei’s latest Smart I-V Curve Diagnosis V3.0 uses a new, intelligent string diagnosis algorithm with a built-in database.