Elevator Drives Energy Consumption & Savings New York City May 11, 2011 Don Vollrath Magnetek Basics - What is Energy? Energy is the ability to do work Work k = Force x Distance moved Force = Rope Tension, Torque, Voltage Power = Rate of doing work = Force x Speed Energy Consumption = Sum of all work accomplished over a measured period of time Ft-Lbs, kg-m, Joules, Watt-Sec, BTUs, KiloWatt-Hours 1 1
Basics - What is Energy? The flow of energy is bi-directional Potential Energy is added to mass as it is raised against gravity (Force x Distance) Kinetic Energy is added to mass as it accelerates (1/2 x M x v 2 ) Energy is removed as the elevator is stopped or the payload is lowered Ft-Lbs, kg-m, Joules, Watt-Sec, BTUs, KiloWatt-Hours 2 What Affects Energy Consumption? Elevator mass & payload Elevator speed & distance traveled Frequency of use Hoist way efficiency Motor efficiency Power conversion efficiency Idle losses Regeneration Vs. resistor braking 3 2
Where Does the Energy Go? 1 Car Controller & Drive - Losses 2 Lift motor (& gearbox) - Losses 3 Traction sheave - Losses 4 Ropes / Cables - Losses 5 Car or Cab Inertia absorption & PASSENGER MOVEMENT! 6 Rails & Guides - Losses 7 Counterweight Inertia absorption Air column - Losses 4 Other Wasteful Effects Current harmonics Causes voltage distortion, acoustic noise and extra heating in distribution lines & equipment Heat release Must be removed by HVAC system Includes that from resistor braking Low Power factor Uses up distribution capacity 5 3
Regeneration Recovery or reuse of energy that would have been lost Every motor can act like a generator Some motor drive power converters can push energy back into the utility line Regeneration Exception Lower cost inverters with rectifier (diode) front-ends Important energy savings feature for high speed, high duty elevators 6 Regeneration Where does the regenerated energy go? Braking resistor Poor choice Other elevators in operation Other connected building loads Slows down the utility meter 7 4
Typical Building Distribution OTHER MACHINERY HVAC EQUIPMENT UTILITY MAINS UTILITY SUB-STATION STEP-DOWN TRANSFORMER UTILITY POWER METERING LOCAL BUILDING METERING INTERNAL POWER DISTRIBUTION BUS DOMESTIC STEP-DOWN ELEVATOR POWER RISER WALL OUTLET DISTRIBUTION PANEL LIGHTING CONTROL PANEL SAFETY DISCONNECTS WALL OUTLETS ROOM LIGHTING ADJ SPEED ELEVATOR DRIVE ADJ SPEED ELEVATOR DRIVE ELEVATOR MOTOR 1 ELEVATOR MOTOR 2 8 Basics - What is Efficiency? Efficiency = Useful work output Actual work input Being efficient minimizes energy waste 9 9 5
Elevator Efficiencies Car Controller A few 100 watts of continuous consumption Solid State Motor Drive 90-95% Power Conversion Motor - 75-92% Gearbox - 85% Motoring, 50% Regen Traction Sheave & Ropes, Rail Guides, Windage, etc. - 85-90% 10 Efficiencies of Motor Drives For DC Motors M-G Set, 60-80% SCR-DC, 85-90% PWM-DC, 90-94% DC Motor, 88-92% For AC Motors Variable Voltage, 40-60% V V V F Inv., 92-95% Induction Motor, 75-90% PM Motor, 89-92% Gearbox 85% motoring, 50% regenerating 11 6
Energy Efficiency Net Energy Consumption Generator Filter / Transformer Drive Motor Gear Hoistway M-G Gearless DC 103 61 81 90 100 Regenerating 0.75 Line Elevator 0.75 164 123 111 100 Motoring 73 73 79 81 90 100 SCR-DC Gearless DC 64 Line 2 2 8 8 Elevator 137 137 126 123 111 100 Quattro Gearless DC 76 76 81 90 100 4 55 Line Elevator 4 131 131 123 111 100 12 Energy Efficiency Net Energy Consumption Generator Filter / Transformer Drive Motor Gear Hoistway M-G Gearless DC 103 61 81 90 100 Regenerating 075 0.75 09 09 Line Elevator 0.75 164 123 111 100 Motoring 73 73 78 83 90 100 Regenerating Regen Gearless PM 58 Line 4 8 4 4 2 2 Elevator 131 131 128 121 111 100 Motoring Quattro Gearless DC 76 76 81 90 100 4 55 Line Elevator 4 131 131 123 111 100 13 7
Predicting Consumption Equipment efficiency is only part of the issue What is the magnitude of the Power demand? The car is not always loaded to capacity How long will it last? Runs are variable length Express vs Local How many times will it happen? Hospital vs Hotel vs Office vs Condo, etc. Reducing Energy Consumption is what we are after Find a way to predict consumption with variable loads and variable elevator cycling 14 Consumption Calculations Estimate the average load, system mass, run distance and the number of runs per day / month / year Fact: Whatever goes up eventually comes down Mechanical + electrical losses ARE the consumption Averaged data yields the same consumption answer as the kwhr meter 15 8
Energy Consumption Calculator Click on Energy Savings Calculator Sign up to be a registered user Energy Consumption Calculator 9
Energy Consumption Calculator Drive / Mtr Type QUICK COMPARISON -- GEARLESS kwh / day estimate Heat Release BTU / day (1,000's) $ per Year estimate Relative kwh Consumption m-g DC (Regen) 132 451 $4,136 1.000 Savings SCR-DC (Regen) 123 420 $3,855 32 6.8% Quattro PWM-DC(regen) 69 236 $2,167 0.524 47.6% Ind. AC non-regen 146 497 $4,562 1.103-10.3% Ind. AC w/ Regen 123 420 $3,855 32 6.8% PM AC non-regen 109 371 $3,402 0.823 17.7% PM AC w/ Regen 65 221 $2,025 0.490 51.0% 18 780 3 rd Ave, NYC Hi-Rise, 1,200 fpm, 3,000lbs, DC Gearless, (each of 3 cars) Lobby express to floors 35-48 M-G-DC consumption: 131 kwhr/day, 446 BTU/day Quattro-DC consumption est: 65 kwhr/day, 221 BTU/day 51% Energy Savings with Quattro! 19 10
780 3 rd Ave, NYC Mid-Rise, 1,000 fpm, 3,000lbs, DC Gearless, (each of 3 cars) Lobby express to floors 19-35 M-G-DC consumption: 91.8 kwhr/day, 313 BTU/day Quattro-DC consumption est: 37.9 kwhr/day, 129 BTU/day 59% Energy Savings with Quattro! 20 780 3 rd Ave, NYC Low-Rise, 800 fpm, 3,000lbs, DC Gearless, (each of 3 cars) Lobby to floor 19 M-G-DC consumption: 69.5 kwhr/day, 237 BTU/day Quattro-DC consumption est: 25.2 kwhr/day, 86 BTU/day 64% Energy Savings with Quattro! 21 11
780 3 rd Ave, NYC Total Energy Savings (all 9 cars) 492 kwhr/day or 128,000 kwhr/year! 22 Energy Monitoring Best way to capture real energy savings Need before and after modernization data Measure total energy consumption to each elevator or a whole elevator bank Must be same average duty cycle KiloWatt-Hrs Input KiloWatt-Hrs Returned (Regenerated) kva-hrs Run Cycle & Elapsed Time counters Minimum of 14 days of continuous operation, 24/7 23 12
Modernization Why keep a DC machine? Large gearless DC machines cannot be easily replaced with AC equivalents DC Motors and Machines are in Good Working Order to Provide Excellent Ride Quality and Years of Additional Service Difficult Machine Room Access 24 Elevator Machines 99 High St., Boston Hi-Rise Otis 219HT 1,000 fpm 3,500 lbs. 25 13
Emily Morgan Hotel San Antonio, TX GE Type 722 (1927) 35 hp 65 rpm 600 fpm 2,500 lbs. 26 Conclusions Regenerative Drives will save the most d hi th t LEED i t energy and achieve the most LEED points Contact the local utility about energy saving incentives and rebates Investigate state or city incentives Look also for tax incentives 14
Conclusions Use the Energy Consumption Calculator to Compare Motor & Drive Systems Measure energy consumption to gain confidence of calculated estimates Energy savings alone will not pay for elevator modernization, but using more efficient equipment makes a large impact on energy use with a relatively small incremental cost 28 Incentive Rebate Programs Will require application paperwork p Separate or custom category for elevators Will require an energy savings estimate May require third party verification including a baseline measurement 29 15
Energy Monitoring What s next? Interest developing in monitoring elevator consumption via the Building Management System (BMS) Siemens, Johnson Controls, et al 30 Questions? Please visit www.elevatordrives.com for Magnetek s Energy Savings Calculator and additional product information. 31 16