1. ENME808W Advanced Topics in Mechanical Engineering: Energy Efficiency/Energy Audit and Conservation Week Eleven Lecture I: Dr. Michael Ohadi Class: Mon. 4:00 – 6:40 PM Office: 4164C Glenn L. Martin Hall Office hours: As Per the Syllabus Light System Audit

2. Lighting Terminology

3. Illumination - The distribution of light on a horizontal surface. The purpose of all lighting is to produce illumination. Lumen - A measurement of light emitted by a lamp. As reference, a 100-watt incandescent lamp emits about 1750 lumens. Footcandle - A measurement of the intensity of illumination. A footcandle is the illumination produced by one lumen distributed over a 1- square-foot area.

4. 4 Lighting Power Density (LPD):  It is a measurement of the watts per square foot consumed by the lighting system. “Total system wattage / total square footage = LPD”  In Maryland state Codes are based on lighting power allowances based on the type of building or space type and are used as a basis for design.  LPD is how most utility programs measure and qualify new construction lighting projects.

5. Lighting Terminology, cont. Efficacy – The amount of visible light (lumens) produced for the amount of power (watts) expended Color Temperature – Measure of the color of a light source relative to a black body at a particular temperature (K) – Incandescents have low color temperature (~2800K) – Daylight has a high color temperature (~6000K)

6. Lighting Color Temperature

7. Lighting Terminology, cont. Color Rendering – Describes how a light source renders a set of colored surfaces with respect to a black body light source at the same color temperature – Color Rendering Index (CRI)  0 – 100

8. Lighting Terminology, cont. Blast Factor (BF)  BF is the ratio of lamp lumens produced when lamp(s) are operated on a given ballast versus equivalent lamps on a “reference” ballast.  Higher BF will increase wattage consumed as well as lumen output

9. Optimum Lighting Efficiency  The energy efficiency of the lighting system in a project is measured by the LPD (watts / square foot).  Energy codes may contain maximum LPDs based on the type of building or the type of space.  Keep in mind the optimum goal is to provide quality lighting at the lowest possible lighting power density.

10. Lighting System Audit Lighting accounts for a significant portion of electrical energy consumed in a building – Typically, more of an issue in commercial buildings as opposed to residential buildings – Contributes to cooling loads Methods of reducing lighting energy – Reducing illumination levels – Improving lighting system efficiency – Curtailing operating hours – Taking advantage of daylighting

11. Lighting Audit Steps 1.Asses what you have – Room Classification: Office, warehouse, storage, etc. – Room Characteristics: Height, width, length, color and condition of surfaces – Fixture Characteristics – Lamp type, number of fixtures, lamp wattage, condition, etc. 2.Evaluate lighting levels and lighting quality – Measure foot-candles using a light meter – Sketch luminaries types and layout in room – Check for excessive glare or contrast – Talk to occupants about lighting levels, controls, and quality – Compare foot-candle measurements to IES recommendations for the task performed

12. Illuminating Engineering Society (IES) Recommending Lighting Levels

13. Lighting Audit Steps, cont. 3.Estimate electrical consumption – Calculate total watts (watts/fixture × # of fixtures) – Calculate power density (watts/sq. ft) – Compare existing power density to code of design guidelines – Estimate annual hours of use – Estimate annual lighting energy cost 4.Calculate energy savings – Determine new total wattage after retrofit – Determine change in annual operating hours if lighting controls are changed – Calculate energy savings – Calculate energy cost savings

14. Secondary Effects Reduction in lighting energy can also – Increase heating energy consumption – Decrease cooling energy consumption Heat of light is often an expensive and inefficient heating source General rules of thumb – If a building is heated only  Decrease energy savings by 20% – If a building is heated and cooled  Increase energy savings by 20% If cooling system is being replaced in conjunction with lighting upgrades, often cooling capacity can be reduced

15. Lighting Design Considerations

16. 16 Design Guidelines Several factors can contribute to energy efficiency:  Choose the most efficacious source you can afford  Select high-efficiency luminaires – Advanced, low-glare fixtures for offices!  Consider new technologies as an alternative – Consider LED downlights vs. Halogen

17. 17 Go with the right Light Levels  Under-lighting spaces can cause safety issues and hinder productivity.  Over-lighting spaces simply wastes energy!  “Dial it in” the first time; don’t be afraid of multiple light levels for multiple spaces

18. Lighting Sources

19. Incandescent Lamps Have lowest lamp efficacies of the commonly used lamps Most common type of lighting in homes (~85%) Light up instantly and are dimmable Provide warm color Short life span Most expensive to operate

20. Tungsten Halogen Incandescent Lamps, cont. A-Type – standard incandescent light bulb Tungsten-Halogen – slightly higher efficacy than A- Type due to halogen gas filling Reflector Lamps – Interior aluminum coating directs light to the front of the bulb A-TypeReflector Lamps

21. Fluorescent Lamps Use 25-35% of the energy used by incandescent lamps Last about 10 times longer as incandescent lamps Require a ballast to regulate operating current and provide a high startup voltage Recent improvements have been made in color temperature and color rendering that compare to incandescent lamps

22. Fluorescent Lamps, cont. Fluorescent Tubes – Second most popular light source – Preferred for ambient lighting in large indoor spaces due to reduced glare – Types: T12, T8, T5

23. Fluorescent Lamps T12’s are obsolete and should be replaced. T12’s are 12/8 = 1.5 inches in diameter (least efficient) T8’s are 8/8 = 1 inch in diameter (more efficient) T5’s are 5/8 inches in diameter (most efficient)

24. Fluorescent Lamps, cont. Compact Fluorescent (CFL’s) – Efficiency of fluorescents – Convenience of incandescent bulbs – ~75% energy savings over incandescent lamps – Require recycling due to mercury

25. CFL vs. Incandescent Assumes $0.113 per kW-hr and 6 hours of use per day.

26. High Intensity Discharge (HID) Highest efficacy and longest service life of any lighting type Require a ballast and take up to 10 minutes to produce light – Most suitable in applications where lights remain on for long periods of time Commonly used outdoors and large indoor arenas

27. HID’s, cont. Mercury Vapor Lamps – oldest HID, commonly used in street lights Metal Halide Lamps – best color rendering amounts HID’s, commonly used in sport arenas High Pressure Sodium Lamps – becoming most common type of outdoor lighting, most efficient HID

28. Light Emitting Diodes (LED’s) One of today’s most energy-efficient and rapidly developing lighting technology Last longer, more durable, and offer better lighting quality than any other light source Near monochromatic light source Directionality makes LED’s ideal for recessed down lights and task lighting LED’s emit almost no heat

29. Light Emitting Diodes (LED’s) The high efficiency and mono-directional structure of LEDs makes them ideal for many industrial uses. LEDs have largely replaced incandescent bulbs in traffic signals. They are also increasingly common in street lights, automobiles (interior and exterior), walkways, computer components, and signs and displays. Because light-emitting diodes provide such strong lighting in one direction, they are ideal for lighting countertops for cooking and reading recipes.

30. Light Emitting Diodes (LED’s) Recessed downlights are commonly used in kitchens, hallways, and bathrooms in homes, and have largely replaced ordinary street lights Decorative light strings such as Christmas tree lights are among the most popular and most affordable LED consumer products on the market. Not only are the LED bulbs far brighter and less yellow in color than incandescent ones, but they save 90% or more in utility costs, operate at cooler temperatures, and have an operational life span of roughly 20,000 hours (enough to last for 40 holiday seasons).

31. LED Uses Recessed Down Lights Kitchen Under-Cabinet Lighting Refrigerated Showcases Holiday Lights

32. Lighting Type Efficacy (Lumen/Watt) Lifetime (hours) CRIColor Temp. (K) Incandescent Type-A10-17750-200098-1002700-2800 Tungsten-Halogen12-222000-400098-1002900–3200 Reflector12-192000-300098-1002800 Fluorescent Straight Tube30-1107000-24,00050-902700-6500 CFL50-7010,00065-882700-6500 Circline40-5012,000 High Intensity Discharge (HID) Mercury Vapor25-6016,000-24,000503200-7000 Metal Halide70-1155000-20,000703700 High Pressure Sodium50-14016,000-24,000252100 Light Emitting Diode (LED) Cool White LED’s60-9235,000-50,00070-905000 Warm White LED’s27-5435,000-50,00070-903300 Low Pressure Sodium60-15012,000-18,000-44

33. Lighting Controls

34. Dimmers Suitable for indoor lighting for incandescent and dimmable fluorescent lamps Reduces lumen output more than wattage – Makes incandescent lamps less efficient Decrease service life significantly

35. Motion Sensors Automatically turn off outdoor lights on when they are needed and turn them off a short while later

36. Occupancy Sensors Detect activity within a certain area Provide convenience by turning on lights when someone enters a room Two types – Ultrasonic – Infrared

37. Timers Programmable Light Switch Preset On Times (10, 20, 30, 60 minutes) Receptacle Timer (for plug-in lights)

38. References Thurman, Handbook of Energy Audits EnergySavers.gov – http://www.energysavers.gov/your_home/lighting _daylighting/index.cfm/mytopic=11980 http://www.energysavers.gov/your_home/lighting _daylighting/index.cfm/mytopic=11980