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Instrument Ground Training Module 8

Randy Schoephoerster www.airtreknorth.com. Instrument Ground Training Module 8. Agenda. Weather Causes of Weather Wind Atmosphere Jetstream Clouds Thunderstorms Wind Shear Icing Microbursts. CAUTION………………….

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Instrument Ground Training Module 8

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  1. Randy Schoephoersterwww.airtreknorth.com Instrument Ground Training Module 8

  2. Agenda • Weather • Causes of Weather • Wind • Atmosphere • Jetstream • Clouds • Thunderstorms • Wind Shear • Icing • Microbursts

  3. CAUTION………………….. • The sole purpose of this class is to expedite your passing the FAA knowledge test. With that said, all extra material not directly tested on the FAA knowledge test is omitted, even though much more information and knowledge is necessary to fly safely. Consult the FAR/AIM (CFR) and other FAA Handbooks for further information along with a Flight Instruction course. • Instrument Knowledge Test is good for 24 calendar months. • FAA-G-8082-13D • www. sportys.com/faatest • AC 00-6A Weather Advisory Circular http://www.faa.gov/regulations_policies/advisory_circulars/index.cfm/go/document.information/documentID/22268

  4. CFR 61.65 (d) Instrument Practical Test Requirements • (d) Aeronautical experience for the instrument-airplane rating. A person who applies for an instrument-airplane rating must have logged: • (1) Fifty hours of cross country flight time as pilot in command, of which 10 hours must have been in an airplane; and • (2) Forty hours of actual or simulated instrument time in the areas of operation listed in paragraph (c) of this section, of which 15 hours must have been received from an authorized instructor who holds an instrument-airplane rating, and the instrument time includes: • (i) Three hours of instrument flight training from an authorized instructor in an airplane that is appropriate to the instrument-airplane rating within 2 calendar months before the date of the practical test; and • (ii) Instrument flight training on cross country flight procedures, including one cross country flight in an airplane with an authorized instructor, that is performed under instrument flight rules, when a flight plan has been filed with an air traffic control facility, and that involves— • (A) A flight of 250 nautical milesalong airways or by directed routing from an air traffic control facility; • (B) An instrument approach at each airport; and • (C) Three different kinds of approacheswith the use of navigation systems.

  5. Causes of Weather • Every physical process of weather is accompanied by, or is the result of, heat exchanges. • Unequal heating of the Earth's surface causes differences in pressure and, thus, altimeter settings. • On weather maps, the lines drawn to connect points of equal pressure show pressure contours called isobars.

  6. Uneven Heating of the Earth’s Surface

  7. Winds • Three of the forces at work on winds are discussed below. • The pressure gradient force causes wind to flow from an area of high pressure to one of low pressure • This flow is thus perpendicular to the isobars. • Coriolis force deflects winds to the right in the Northern Hemisphere. Coriolis force is a result of the Earth's rotation. • The Coriolis force is at a right angle to wind direction and directly proportional to wind speed. Its effect is more forceful at greater altitudes (above approximately 2,000 ft. AGL) because surface winds are slowed by friction. • It deflects winds so strongly that they flow parallel to isobars. • Friction with the Earth's surface weakens the wind. • Since these winds are slower, they are less affected by Coriolis force. The pressure gradient becomes stronger than Coriolis force, and the wind flows across, rather than parallel to, the isobars. • An air mass is an extensive body of air having uniform moisture and temperature properties.

  8. Isobars

  9. Coriolisvs Pressure Gradient

  10. 7.1 Causes of Weather • Every physical process of weather is accompanied by, or is the result of, heat exchanges • Unequal heating of the Earth’s surface causes differences in pressure and altimeter settings • The Coriolis force deflects winds to the right in the Northern Hemisphere. It is caused by the Earth’s rotation • The deflections caused by Coriolis force are less at the surface due to the slower wind speed • The wind speed is slower at the surface due to friction between wind and the Earth’s surface

  11. Winds

  12. Winds

  13. Winds

  14. Jet Stream • The jet stream is a narrow, disjointed, wandering "river" of maximum winds. • It moves with pressure ridges and troughs in the upper atmosphere near the tropopause. • It blows from a generally westerly direction and, by definition, has a speed of 50kts or more. • The jet stream is normally weaker and farther north in the summer. • The jet stream is normally stronger and farther south in the winter.

  15. Jet Stream

  16. Fronts • A front is the zone of transition between two air masses of different temperature, humidity, and wind. • There is always a change in wind when you fly across a front. • The threat of low-level wind shear occurs just before the warm front passes the airport. • With a cold front, the most critical period for wind shear occurs just as or just after the cold front passes the airport. • Frontal waves and cyclones (and areas of low pressure) usually form in slow-moving cold fronts or in stationary fronts. • Squall lines usually develop ahead of a cold front.

  17. Fronts

  18. Fronts/Wind Shear

  19. 7.4 Thunderstorms • The most severe thunderstorm conditions are generally associated with squall line thunderstorms • Heavy hail • Destructive winds • Tornadoes, etc • A squall line is a non-frontal narrow band of thunderstorms usually ahead of a cold front

  20. Squall Lines

  21. Randy Schoephoersterwww.airtreknorth.com Instrument Ground Training Module 8

  22. Agenda • Weather • Causes of Weather • Wind • Atmosphere • Jetstream • Clouds • Thunderstorms • Wind Shear • Icing • Microbursts

  23. Atmosphere • The average height of the layer of the Earth's atmosphere called the troposphere is about 37,000 ft. in mid-latitudes. It varies between approximately 25,000 ft. at the poles to 65,000 ft. at the equator. • The boundary between the troposphere and the stratosphere is the thin layer called the tropopause. • Temperature and wind vary greatly in the vicinity of the tropopause. • It is associated with an abrupt change in the temperature lapse rate. • The stratosphere is the layer of atmosphere above the tropopause. • It is characterized by low moisture content and absence of clouds. • It has relatively small changes in temperature with an increase inaltitude.

  24. Small changes in temp with altitude 37,000ft Abrupt chg in Temp Lapse rate

  25. Atmosphere

  26. Atmosphere

  27. Stability • The lapse rate is a measure of how much temperature decreases (or possibly increases) with an increase in altitude. This is the actual temperature change associated with increases in altitude and sometimes is referred to as the ambient lapse rate. • In contrast to the ambient or actual lapse rate is the adiabatic lapse rate. The adiabatic, or "expansional cooling" lapse rate, is the temperature decrease due only to expansion of air as it rises. The adiabatic lapse rate means no heat gain or loss - just a decrease in temperature because of expansion. • The dry adiabatic lapse rate is 3°C per 1,000 ft. • The adiabatic lapse rate varies from about 1.1 °C to 2.8°C based on moisture content of the air. • The average adiabatic lapse rate is 2°C per 1,000 ft.

  28. Lapse Rates/Stability • The ambient lapse rate can thus be used by pilots to determine the stability of air masses. • The greater the ambient lapse rate (more than 2°C per 1,000 ft.) and the higher the humidity, the more unstable the air — and the more thunderstorms can be expected. • Moist air is less stable than dry air because it cools adiabatically at a slower rate, which means that moist air must rise higher before its temperature cools to that of the air around it (i.e., cumulus build-up). • Cloud formation after lifting is determined by the stability of the air before lifting. • Turbulence and clouds with vertical development (cumuliform) result when unstable air rises (due to convective currents). • Moist, stable air moving up a mountain slope produces stratiform clouds as it cools. • Unstable air moving up a mountain slope produces clouds with extensive vertical development.

  29. Stable vs Unstable Air • When a cold air mass moves over a warm surface, heating from below provides unstable lifting action, giving rise to cumuliform clouds, turbulence, and good visibility. • The growth rate of precipitation is enhanced by upward air currents carrying water droplets upward where condensation increases droplet size. • Stable air characteristics • Stratiform clouds and fog • Smooth air • Continuous (steady) precipitation • Fair-to-poor visibility in haze and smoke • Unstable air characteristics • Cumuliform clouds • Turbulent air • Showery precipitation • Good visibility

  30. Stable vs Unstable

  31. Stable vs Unstable

  32. Stable Air

  33. Unstable Air

  34. Stability

  35. Unstable air and Dry Adiabatic

  36. Temperature Inversion • Normally, temperature decreases as altitude increases. A temperature inversion occurs when temperature increases as altitude increases. • Temperature inversions usually result in a stable layer of warm air below the inversion. • A temperature inversion often develops near the ground on clear, cool nights when the wind is light. • It is caused by terrestrial radiation. • Smooth air with restricted visibility (due to fog, haze, or low clouds) is usually found beneath a low-level temperature inversion.

  37. Temperature Inversions

  38. Temp, Dew Point & Fog • When the temperature-dew point spread is 3°C (5°F) or less and decreasing, you should expect fog and/or low clouds. • Air temperature largely determines how much water vapor can be held by the air. • Dew point is the temperature at which the air will be saturated with moisture, i.e., 100% humidity. • Frost forms when the temperature of the collecting surface (e.g., the airplane) is below the dew point of the surrounding air and the dew point is below freezing (0°C or 32°F). • Water vapor becomes visible as it condenses into clouds, fog, or dew. • Evaporation is the conversion of liquid water to water vapor. • Sublimation is the conversion of ice to water vapor or water vapor to ice.

  39. Fog • Radiation fog is most likely to occur when there is a clear sky, little or no wind, and a small temperature-dew point spread over a land surface (especially low, flatland areas). • As the ground cools rapidly due to radiation, the air close to the surface cools more quickly than slightly higher air. • This is the most frequent type of surface-based temperature inversion. • As the air reaches its dew point, radiation fog forms. • Advection fog forms as a result of moist air condensing as it moves over a colder surface (i.e., water or ground). • It requires wind to force the movement. • Advection fog is most likely to occur in coastal areas, when air moves inland from the coast in winter.

  40. Fog • Upslope fog results from warm, moist air being cooled as it is forced up sloping terrain. • Precipitation-induced fog results from warm fronts (warmer air over cooler air), i.e., when warm rain or drizzle falls through the cooler air. • Evaporation from the precipitation saturates the cooler air, causing fog. • Fog can also form easily in industrial areas where combustion pollution provides a high concentration of condensation nuclei (tiny particles on which moisture can condense as the air cools).

  41. Temperature Inversion

  42. Radiation Fog • Clear Sky, little to no wind, low temp to dew point spread, over land

  43. Radiation Fog

  44. Advection Fog • Requires wind, usually in coastal areas

  45. 7.8 Temperature/DewPoint & Fog • What types of fog depend upon wind in order to exist? • Radiation fog and ice fog • Steam fog and ground fog • Advection fog and upslope fog C. Advection fog and upslope fog

  46. Fog

  47. Advection Fog

  48. Fog

  49. Fog

  50. Fog & Dew Point

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