Distribution Equip
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 GE Distribution Equip XJL434400 3 Pole 400A 480VAC  US $2,164.00
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 GE Distribution Equip THKM836F000 US $1,737.50
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 GE Distribution Equip TKM3F US $1,453.00
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 GE Distribution Equip TFJ224175 US $1,360.50
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 GE Distribution Equip THJK636F000 US $1,358.00
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 GE Distribution Equip TJK436Y400 US $1,313.00
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 GE Distribution Equip TKM836F000 US $1,299.50
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 GE Distribution Equip SKHA26AT0800 US $1,289.00
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 GE Distribution Equip TJK636600 US $1,202.50
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 GE Distribution Equip TJJ436200WL US $1,155.50
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 GE Distribution Equip TKMA3T1000 US $1,155.50
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 GE Distribution Equip TKM826F000 US $1,143.50
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 GE Distribution Equip TKMA836Y800 US $874.00
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 GE Distribution Equip TJK436F000 US $866.50
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 GE Distribution Equip TJK636F000 US $841.50
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 GE Distribution Equip TJK436225 US $830.50
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 GE Distribution Equip TFJ236150 US $561.50
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 GE Distribution Equip THQD32225 US $347.00
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 GE Distribution Equip TEC36003 US $212.00
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 GE Distribution Equip THQL2130GF1 US $163.00
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 GE Distribution Equip TQD32200 US $155.00
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 GE Distribution Equip THQB32070ST1 US $146.00
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 GE Distribution Equip THQB32100ST1 US $142.00
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 GE Distribution Equip TED124020 US $118.00
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 GE Distribution Equip TEB132030 US $93.50
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 GE Distribution Equip TED134015 US $93.50
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 GE Distribution Equip TEB122050 US $65.50
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 GE Distribution Equip TEB122020 US $65.00
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 GE Distribution Equip TEB111020 US $22.00
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 GE Distribution Equip TEY120 US $16.00
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 GE Distribution Equip THQB1120 US $4.00
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 GE Distribution Equip THQL1130 US $3.50
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 GE Distribution Equip THQP115 US $2.50
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 GE Distribution Equip THQL1115 US $2.00
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 GE Distribution Equip THQL1120 US $2.00
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Distributed Generation Technologies: Applications and Challenges
The practice of installing and operating electric generating equipment at or near the site of where the power is used is known as "distributed generation" (DG). Distributed generation provides electricity to customers on-site or supports a distribution network, connecting to the grid at distribution level voltages.
The traditional model of electricity generation in the United States, which may be referred to as "central" generation, consists of building and operating large power plants, transmitting the power over distances and then having it delivered through local utility distribution systems.
The practice of installing and operating electric generating equipment at or near the site of where the power is used is known as "distributed generation" (DG). Distributed generation provides electricity to customers on-site or supports a distribution network, connecting to the grid at distribution level voltages. DG technologies include engines, small (and micro) turbines, fuel cells, and photovoltaic systems.
Distributed generation may provide some or all of customers' electricity needs. Customers can use DG to reduce demand charges imposed by their electric utility or to provide premium power or reduce environmental emissions. DG can also be used by electric utilities to enhance their distribution systems. Many other applications for DG solutions exist.
With existing technology, every industrial or commercial facility including factories, campuses, hospitals, hotels, department stores, malls, airports, and apartment buildings can generate enough electricity to meet its power needs under normal conditions, as well as have back-up power during a blackout.
Distributed generation systems can provide an organization with the following benefits:
* Peak Shaving;
* On-site backup power during a voluntary interruption;
* Primary power with backup power provided by another supplier;
* Combined load heat and power for your own use;
* Load following for improved power quality or lower prices;
* To satisfy your preference for renewable energy
In conjunction with combined heat and power (CHP) applications, DG can improve overall thermal efficiency. On a stand-alone basis, DG is often used as back-up power to enhance reliability or as a means of deferring investment in transmission and distribution networks, avoiding network charges, reducing line losses, deferring construction of large generation facilities, displacing expensive grid-supplied power, providing alternative sources of supply in markets, and providing environmental benefits.
Power generation technologies have evolved significantly in the past decade, making DG much more efficient, clean, and economically viable.
Substantial efforts are being made to develop environmentally sound and cost-competitive small-scale electric generation that can be installed at or near points of use in ways that enhance the reliability of local distribution systems or avoid more expensive system additions. Examples of these distributed resources include fuel cells, efficient small gas turbines, and photovoltaic arrays.
This report on Distributed Generation Technologies takes an in-depth look at the industry and analyzes the various technologies that contribute to distributed generation in today's age. The report focuses on these technologies through case studies, examples, and equations and formulas. The report also contains analysis of the leading countries actively promoting distributed generation.
About the Author
About the Publisher: This report is published by Energy Business Reports, an energy industry think tank and leading source for energy industry information and research products. To read more about this topic, see: Distributed Generation Technologies: Applications and Challenges
Prepare the schedule of cost of goods manufactured and income statement for the following data.?
For Speci¯c Date
Direct materials, Jan. 1, 2004 $15
Work in process, Jan. 1, 2004 10
Finished goods, Jan. 1, 2004 70
Direct materials, Dec. 31, 2004 20
Work in process, Dec. 31, 2004 5
Finished goods, Dec. 31, 2004 55
For Year 2004
Purchases of direct materials $325
Direct manufacturing labor 100
Depreciation - plant, building, equip. 80
Plant supervisory salaries 5
Miscellaneous plant overhead 35
Revenues 950
Marketing, distribution, and
customer service costs 240
Plant supplies used 10
Plant utilities 30
Indirect manufacturing labor 60
please give any idea to solve this question
Follow the flow through the factory.
Direct Material Inventory -
Beg Balance 15 + Purchases 325 = 340 less End Balance 20 = 320 to Work in Process
Work in Process Inventory -
Beg Balance 10 + DM transfers 320 + DL 100 + Mfg OH 220 (80 + 5 + 35 + 10 + 30 + 60)
less End Bal 5 = 645 Cost of goods mfd
Finished Goods Inventory -
Beg Bal 70 + 645 Transfer from WiP less 55 End Bal = 660 Cost of Goods Sold
Sales 950 - CGS 660 = Gross Profit 290 - Marketing, etc 240 = 50 Net Income
Annual Prize Distribution Cermony
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