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Practical Flow Assurance: Phase Behavior, Multiphase Flow, and Organic Solids

為了解決UK plug的問題，作者Aman, Zachary Mark,May, Eric Freemantle,Pickering, Paul Frederic 這樣論述：

Dr. Zachary M. Aman received his PhD in Chemical Engineering from the Center for Hydrate Research at the Colorado School of Mines in 2012, led by Professors Dendy Sloan and Carolyn Koh. His graduate research focused on the interfacial phenomena of clathrate hydrate systems, specifically in the inter

action of surfactants with the hydrate-lipophilic boundary. In 2013, Zach joined the University of Western Australia as a Research Assistant Professor, focusing on high-pressure experiments and modelling for hydrate blockage in gas-dominant systems. Much of his work is targeted at experimental metho

ds to quantify both hydrate surface free energy and surfactant adsorption in multiphase systems, which provide a context for particle aggregation and plug formation. In 2015, he was appointed as an Associate Professor of Mechanical and Chemical Engineering at UWA. In addition to work on gas hydrates

, Zach also works in high-pressure measurements of droplet size and hydrate film growth to support the modelling of deepwater blowout. Dr. Eric F. May has been conducting research in fluid science for over a decade and was awarded the Malcolm McIntosh Prize for Physical Scientist of the Year as part

of the 2012 Prime Minister’s Prizes for Science. He is now the Director of the Australian Centre for LNG Futures, funded by the Australian Research Council through the Industrial Transformation Hub program. Eric completed his Bachelor of Science (Hons) and PhD at UWA where he developed new technolo

gies to measure gas condensate phase behaviour with microwave cavities. He was then an American Australian Association Fellow at the National Institute of Standards and Technology in Maryland where he helped develop next-generation standards for gas metrology. In 2005 Eric returned to Australia and

a lecturing position in oil & gas engineering. He teaches undergraduate and industry courses in thermodynamics and gas processing, and has helped to build a new Chemical Engineering degree at UWA. His research group works closely with industry and is conducting projects in LNG production, flow assur

ance, CO2 sequestration and fluid property prediction. In 2013, he was seconded to industry during his sabbatical, spending several months in Richmond, California. He won the Australian National Metrology Institute prize in 2009 and was awarded the 2010 Western Australian Early Career Scientist of t

he Year. Eric was appointed the inaugural Chevron Chair in Gas Process Engineering at UWA which, in 2011, was endowed in perpetuity.Dr. Paul F. Pickering has spent the majority of his 25 year career working in engineering design, mainly focussed in the areas of multiphase flow and heat transfer. He

holds MEng and PhD degrees from Imperial College. His doctoral research work was completed under the auspices of Professor Geoff Hewitt on the nature of flow instabilities in low pressure boiling systems. For this work he received the Newitt Prize for the best theoretical PhD thesis and the Mike Akr

ill Trophy from the UK Heat Transfer Society. Paul Pickering’s first position after graduation was with British Nuclear Fuels where he worked in the Process Simulation Section on the transient modelling of process systems. After this, he joined the oil and gas industry working for the design contrac

tor Granherne Ltd in the UK. He then worked for several engineering companies before founding the company FEESA Ltd in 2001. In FEESA he set about developing the new multiphase network simulation software Maximus. This was successfully commercialised before he moved to Western Australia in 2011 to t

ake up his present post with Woodside Energy Ltd in Perth. At Woodside he continues his work in the areas of multiphase flow and heat transfer in the role of Principal Flow Assurance Engineer.

UK plug進入發燒排行的影片

倂網型電動車充電站系統規劃與控制

為了解決UK plug的問題，作者官大右 這樣論述：

電動車因具備高能源效率及低排碳特性已成為未來車輛發展的主流趨勢，而規劃先進的充電站系統與發展可行的電能控制方案以降低對電網的衝擊則是加速實現車輛全面電動化的重要基礎。本文針對整合再生能源發電及混合式儲能系統的併網型充電站提出了一個以直流匯流排為基礎的系統電能控制方案並分析系統中各組件的容量規劃與運轉成本的關係。所提電能控制方案中規劃有三個充電站運轉模式，即獨立運轉、併網充電及併網放電模式。系統工作時是以混合式儲能系統的電量狀態作為充電站運轉模式之切換依據。所提電能控制方案之目標是達到最大程度降低充電站對配電系統的負面衝擊。本文首先回顧了文獻中已提出之充電站系統架構與控制方法，接著針對有關充電

站系統中各組件的容量規劃問題，探討了系統中各組件的建模與成本估算方法，並以一個典型的充電站系統規劃案例進行量化分析。 最後針對所提電能控制方案所需之電力轉換器及相關控制器設計提供了詳細的說明並以電腦軟體進行系統建模及情境模擬以證明所提電能控制方案之可行性及有效性。

BSA Sunbeam & Triumph Tigress Scooter 1959-1965 Workshop Manual

為了解決UK plug的問題，作者 這樣論述：

190 pages, and more than 120 illustrations and charts, size 8.25x10.75 inches. This manual is a compilation of three factory publications including the owner’s instruction manual, the parts/spares manual and a set of service sheets. These publications cover all three variations of the 175cc two-s

troke and the 250cc four-stroke and electric start models manufactured from 1959-1965. Neither BSA nor Triumph ever published a workshop manual for these models, however, the combination of these three publications provides the most comprehensive maintenance and repair information that was ever made

available from the manufacturer.MANUALS & TECHNICAL PUBLICATIONS: Maintenance, repair and service information was issued under both the BSA and Triumph name. However, as the machines were identical in all aspects, any technical documentation can be applied to either manufacturer without hesitat

ion.SERVICE SHEETS: Beginning in December 1959, both BSA and Triumph began publishing repair, overhaul and technical information in the form of individual (dealer only) ’Service Sheets’. It should be noted that it was never intended that these service sheets would be distributed to the general publ

ic. However, they were eventually combined into a single publication and released under both the BSA and Triumph names, the contents being identical in either case. INSTRUCTION MANUAL: Both BSA and Triumph published an identical ’Instruction Manual’ the only difference being the name on the front c

over. These publications were somewhat more detailed than typical ’owner’s manuals’ as they included overhaul information in addition to general maintenance and adjustments. As these instruction manuals were included with each new scooter purchased, there were a number of ’editions’ published during

the lifetime of the model, however, the contents remained basically unchanged. When combined with the ’Service Sheets’ they are a reasonable substitute for a workshop manual. PARTS (or) SPARES MANUAL: The parts manuals are also identical and include exploded component diagrams that are extremely h

elpful in the rebuilding or restoration process.ADDITIONAL DATA: There is an addendum to the rear of this manual that contains a number of communications that were sent from the UK factory to their US distributors. These documents are somewhat rare and they may be of help in assisting in the mainte

nance of one of these machines.DESIGN & GENERAL SPECIFICATIONS: Designed by Edward Turner (Triumph) and sold under both BSA and Triumph brand names to take advantage of established distribution networks, this badge engineering was one of the last uses of the Sunbeam name. The differences between

the BSA Sunbeam and Triumph Tigress were entirely cosmetic-the former in polychromatic green paint, also two-tone red and cream, with a BSA badge; the latter in a shell blue or mimosa and ivory (two-tone) with a Triumph badge.Introduced in late 1959, the scooter was available with a 250 cc four-str

oke twin (10hp), or 175cc two-stroke single cylinder engine (7.5hp). Both engines were forced-air-cooled. The two-stroke was a development of the BSA Bantam engine but the four-stroke was a completely new parallel-twin with a gear drive to the gearbox. The contact-breaker fed two separate ignition c

oils, each of which connected directly to its own spark plug without the need for a distributor. Drive to the rear wheel was by a fully enclosed chain in an oil bath. Both versions had four, foot-operated gears. Some of the 250 twins were fitted with an electric starter and a 12 volt (not 6 volt) el

ectrical system, they were identified as either B2S (Sunbeam) or TW2S (Triumph). The 250 cc four-stroke model was discontinued in 1964 and the 175cc two-stroke model in 1965.

我國2050淨零政策下電動自用小客車發展對減碳及環境衝擊之影響

為了解決UK plug的問題，作者張簡健利 這樣論述：

為因應2050年淨零排放目標，臺灣已於2022年3月正式公告國家淨零轉型路徑圖，推動能源、產業、生活及社會四大轉型策略，並提出十二項關鍵策略，其中第七項即為運具電動化及無碳化，然而電動汽車之減排效果在國內尚未獲致完整的論述，因此本研究將依據油井到車輪 (Well-to-Wheel, WTW) 理論，針對以電動汽車取代燃油車並進行生命週期評估 (Life Cycle Assessment, LCA) 之探討。雖然 LCA 是常用的環境衝擊評估工具，但時間因素一直是其發展的挑戰與限制，而系統動力學 (System Dynamics, SD) 能用來模擬具時間變化且複雜性的問題，因此本研究將結合S

D與LCA，以動態生命週期評估法來推估以電動汽車取代燃油車至2050年之減排潛力及降低之環境衝擊。本研究以能源局公告之能源平衡熱值表 (2020) 及溫室氣體排放係數管理表 (6.0.4版) ，計算出臺灣各發電廠之排放係數，以非核家園政策及國家淨零排放路徑據以推估2050年前我國之能源結構變化，並推估出各年度之電力排放係數，進行電動汽車取代燃油車減碳及環境衝擊之計算。在數據蒐集與預測部分是使用系統動力學軟體STELLA來建構系統動力學模型，以推估未來用電量及用油量之變化，配合前述本研究推估之電力排放係數，以及環保署碳足跡資料平台之燃料係數及SimaPro之環境衝擊係數，計算電動汽車之減排潛力及

環境衝擊，並使用openLCA進行蒙地卡羅分析，對其結果進行不確定性分析。此外，本研究亦比較不同再生能源，以及碳捕獲儲存及再利用(CCUS)技術發展情境與結構，探討各情境之減排潛力及環境衝擊。本研究結果顯示，依據我國淨零排放路徑圖之規劃以及本研究能源結構改變之推估，電力排放係數至2050年會下降至0.139 kg CO2e/kWh，較目前0.504 kg CO2e/kWh，顯著下降72%。推動電動汽車有助於臺灣減少碳排放，自2039年後電動汽車的GHG排放量將會隨電力排放係數之降低而逐年降低，總自小客車(含燃油車及電動車)GHG排放將逐年下降，由2020年的1.45×107 tCO2e降至20

50的1.97×106 tCO2e，下降約86%。經本研究生命週期衝擊評估計算得知，電力環境衝擊係數會從2020年的20.2 mPt/kWh降至2050年的5.67 mPt/kWh，減少約72%，但因電動車數量增加而使電力使用量增加之電力環境衝擊會從2020年的1.67×107 Pt提高至2050的2.6×107 Pt，提高約55%。根據不確定性分析結果，在95%信賴區間內，2050年時電動汽車的GHG排放量介於6.359×105 ~ 1.068×106 tCO2e，燃油汽車的GHG排放量介於1.441×106 ~ 3.36×106 tCO2e，電動汽車之減排潛力則介於1.925×106 ~

8.433×106 tCO2e。在本研究以再生能源 (30%~70%) 及CCUS (5%~25%)比例為主要變數之能源情境假設中發現，對環境衝擊最大之情境為再生能源30%且CCUS 5%。當再生能源70%且 CCUS 在25%時電力排放係數最低，所計算出之電動汽車GHG排放亦為最低，減排潛力最大。在總環境衝擊部分，最佳情境為再生能源60%且CCUS 25%。本研究針對電動汽車取代燃油車減碳及環境衝擊之研究結果，可提供國內政府機關、電動車業者及利害關係人，未來制定相關政策、商業決策及研究方向等之參考。