Jobs! Jobs! Jobs! The Maintainence Procedure For Your Pet Wind Farms in Wilderness.

Sequence of events:
1. Overview of procedure and safety briefing
a. Be aware of the whole process as it unfolds
b. Do not stand under tower
c. Be sure that you have an escape route if things go wrong
d. When working near conductors, always check to see if they are energized
e. Do not push on gin pole to lower tower
2. Crew assignment, issue and activate radios, channel 10
3. Check torque on tower anchors.
4. Check grounding cables and tighten
5. Check block and tackle gear
6. Detach breaker box from tower to allow cable slack while lowering.
7. Furl the turbine
8. Check position and condition of jack stand (50’ from tower center)
9. Unspool wire rope – IMPORTANT: do not allow rope to unroll off to the sides as this will kink and twist the rope.
10. Attach clevis to vehicle and wire rope to clevis
11. Remove slack from wire rope
12. Check integrity of wire rope and loop, thimble and wire clips
13. Tighten wire clips on wire rope loop
14. Check security of clevis and hitches and wire rope loop
15. Unhitch turnbuckle to gin pole on front pad
16. Set breaker to “off” position on tower
17. Check surge arrestor with multimeter
18. Check conductors on building breaker box to be sure it is deactivated
19. Disconnect input lines on building breaker box
20. Short 3 wires together on building breaker with wire nut, insulate with electrical tape.
21. Trip tower breaker “on”
22. Be sure turbine breaks within 60 secs.
23. If breaker doesn’t break with 1 min. tip breaker on tower to “off,” wait for wind speed to drop and try again
24. .Backup hoist vehicle slowly about 10 ft
25. While vehicle is backing up, pull back upper guy wire on rear footer to begin tipping tower
26. Monitor tension on side guy wires and loosen with levers if necessary. Keep track of adjustment so it can be easily returned to original condition.
27. As turbine approaches the ground, check position of jack stand and prepare to put wood pole into tail section
28. Monitor blade position and be ready to adjust blades to prevent impact with ground
29. Set turbine on jack stand
30. Check guy wires, thimbles and wire clips for integrity
31. Check torque on tower bolts
32. Remove spinner
33. Front bearing seal integrity (look for grease loss)
34. Check torque on blade attachment bolts (150 ftlbs)
35. Check for cracks on blades.
36. Condition of leading edge protection tape, especially outboard of pitch weight
37. Inspect blade tips
38. What caused the white patch on the one blade?
39. Attach spinner
40. Open nacelle hatch
41. Inspect flanged connection
42. Check torque on turbine mainframe bolts (80 ftlbs)
43. Check rear alternator bearing for seal integrity and grease loss
44. Inspect turbine mainframe for cracks
45. Remove slip ring cover plate.
a. Check brushes for movement in brush holder
b. Check slip rings for arcing damage
c. Look for grease leaking from yaw bearings onto slip rings
d. Inspect electrical connections
e. Reattach cover plate
46. Check tail damper. Some leakage is OK
47. Inspect furling cable, especially at ball end/fork attachment to tail boom
48. Check for cracks or loose hardware on tail boom and fin
49. Check tail pivot pin and its snap ring fasteners
50. Close and secure nacelle
51. Check tower wiring
52. Check furling cable
53. Check furling winch
54. Inspect electrical connections in breaker box
55. Appropriately attach surge arrestor leads
56. Raise tower
57. Slowly raise tower
58. Carefully monitor blades near ground level
59. Monitor guy wire tension on side footers
60. When raised, fasten front footer turnbuckle
61. Disconnect wire rope from vehicle
62. Respool wire rope
63. Switch “off” tower disconnect breaker
64. Reattach wire leads at building breaker box
65. Switch “on” tower breaker box
66. Observe turbine spin-up
67. Check balance of phases with multimeter
68. Check insulation with Megger at controller (Gridtek 10) (500 v; R should be > 50 mega-ohms)
69. Switch “off” building breaker
70. Check wiring connections into and out of Gridtek 10
71. Dust off heat sink on Gridtek 10
72. Switch “on” building breaker
73. Safety loops for turnbuckles
Crew:
4 students, 3 instructors
Position 1: Hoisting vehicle driver
Tools: Radio
Attach wire rope
Check wire clips, thimble
Inspect wire rope
Position 2: Gin pole attachment footer
Observe block and tackle, gin pole
Carefully watch breaker box on tower
Position 3: Riverside footer
Crowbar or lever, radio
Watch tension in guy wire
As tower approaches jack stand retreat to jack stand position and be ready to wrangle the tower onto jack stand
Position 4: Lot-side footer
Crowbar or lever, radio
Watch tension in guy wire
As tower approaches jack stand position, retreat to back tower to help wrangle blades
Position 5: Back of tower, alternator
As machine approaches ground, be ready to position blades to prevent ground contact
Position 6: Jack stand position
Wrangle tower onto stand
Position 7: Back of tower, tail
As turbine approaches ground, position 2x4 under tail
All positions:
Once turbine is down retreat to alternator to begin maintenance review...

http://www.rsc.org/publishing/journals/EE/article.asp?doi=b809990c

Energy Environ. Sci., 2009, 2, 148 - 173, DOI: 10.1039/b809990c
Review of solutions to global warming, air pollution, and energy security

Mark Z. Jacobson

This paper reviews and ranks major proposed energy-related solutions to global warming, air pollution mortality, and energy security while considering other impacts of the proposed solutions, such as on water supply, land use, wildlife, resource availability, thermal pollution, water chemical pollution, nuclear proliferation, and undernutrition.

Nine electric power sources and two liquid fuel options are considered. The electricity sources include solar-photovoltaics (PV), concentrated solar power (CSP), wind, geothermal, hydroelectric, wave, tidal, nuclear, and coal with carbon capture and storage (CCS) technology. The liquid fuel options include corn-ethanol (E85) and cellulosic-E85. To place the electric and liquid fuel sources on an equal footing, we examine their comparative abilities to address the problems mentioned by powering new-technology vehicles, including battery-electric vehicles (BEVs), hydrogen fuel cell vehicles (HFCVs), and flex-fuel vehicles run on E85.

Twelve combinations of energy source-vehicle type are considered. Upon ranking and weighting each combination with respect to each of 11 impact categories, four clear divisions of ranking, or tiers, emerge.

Tier 1 (highest-ranked) includes wind-BEVs and wind-HFCVs.
Tier 2 includes CSP-BEVs, geothermal-BEVs, PV-BEVs, tidal-BEVs, and wave-BEVs.
Tier 3 includes hydro-BEVs, nuclear-BEVs, and CCS-BEVs.
Tier 4 includes corn- and cellulosic-E85.

Wind-BEVs ranked first in seven out of 11 categories, including the two most important, mortality and climate damage reduction. Although HFCVs are much less efficient than BEVs, wind-HFCVs are still very clean and were ranked second among all combinations.

Tier 2 options provide significant benefits and are recommended.

Tier 3 options are less desirable. However, hydroelectricity, which was ranked ahead of coal-CCS and nuclear with respect to climate and health, is an excellent load balancer, thus recommended.

The Tier 4 combinations (cellulosic- and corn-E85) were ranked lowest overall and with respect to climate, air pollution, land use, wildlife damage, and chemical waste. Cellulosic-E85 ranked lower than corn-E85 overall, primarily due to its potentially larger land footprint based on new data and its higher upstream air pollution emissions than corn-E85.

Whereas cellulosic-E85 may cause the greatest average human mortality, nuclear-BEVs cause the greatest upper-limit mortality risk due to the expansion of plutonium separation and uranium enrichment in nuclear energy facilities worldwide. Wind-BEVs and CSP-BEVs cause the least mortality.

The footprint area of wind-BEVs is 2–6 orders of magnitude less than that of any other option. Because of their low footprint and pollution, wind-BEVs cause the least wildlife loss.

The largest consumer of water is corn-E85. The smallest are wind-, tidal-, and wave-BEVs.

The US could theoretically replace all 2007 onroad vehicles with BEVs powered by 73000–144000 5 MW wind turbines, less than the 300000 airplanes the US produced during World War II, reducing US CO2 by 32.5–32.7% and nearly eliminating 15000/yr vehicle-related air pollution deaths in 2020.

In sum, use of wind, CSP, geothermal, tidal, PV, wave, and hydro to provide electricity for BEVs and HFCVs and, by extension, electricity for the residential, industrial, and commercial sectors, will result in the most benefit among the options considered. The combination of these technologies should be advanced as a solution to global warming, air pollution, and energy security. Coal-CCS and nuclear offer less benefit thus represent an opportunity cost loss, and the biofuel options provide no certain benefit and the greatest negative impacts.

I have then used this data and the Excel MEAN function - not to be mean but to make a serious point - to determine what the mean lifetime of decomissioned Danish windmills is. It is 15.9 years, carrying one insignificant figure, or 15 years and 10 months.

I have used the MEDIAN function to determine that half of the windmills lasted less than 16 years and that half lasted more than 16 years.

I have used the MAX function to determine that the longest surviving windmill lasted for 28 years.

There was only ONE windmill that lasted 28 years, the 22 kW unit manufactured by Kongsted described on Row 188 of the spreadsheet for decommissioned units.

Now.