Advanced Lighting Solutions Ben Koyle, LC, LEED Green Assoc. April 20, 2017 Learning Objective Gain a better understanding of the energy savings potential of LED luminaires and networked lighting control systems. 1
Learning Objective Review the quality features that should accompany a well designed networked lighting control system. How easy is it? Learning Objective Gain a better understanding of the strategies and techniques of a well designed networked lighting control system. What can it do? 2
Learning Objective Understand the DLC and AEP requirements for well designed networked lighting control systems 3
% of Initial Light Output 5/31/2017 MH Lamp Info (Installed) (.65 LLD) 32,000 Initial Lumens HID Initial Lumens LED 400W MH Hours of Operation (in 1,000s) * Data from National Lighting Bureau 4
HID Input Watts * Type II Distribution HID Luminaire Efficiency (%) 32,000 x 0.66 = 21,120 5
% of Initial Light Output 5/31/2017 HID Delivered Efficiency (%) 21,120 x 0.83 = 17,530 83% HID Mean Lumens HID lamp lumen depreciation (65% at 6,000 hr.)) Hours of Operation (in 1,000s) * Data from National Lighting Bureau 6
MH Lamp Info (Installed) (.65 LLD) 17,530 x 0.65 = 11,394 400W MH Lumen Breakdown Initial Lamp Lumens Initial Fixture Lumens Initial Delivered Lumens Mean Delivered Lumens 32,000 21,120 66% Luminaire Efficiency 17,530 83% Delivered Efficiency 11,394 65% Lamp Lumen Depreciation 7
LED Input Watts & Lumens * Type II Distribution 8
% of Initial Light Output 5/31/2017 LED Delivered Efficiency (%) 14,038 x 0.96 = 13,476 96% A Fair Comparison LED luminaire lumen depreciation (~100% at 6,000 hr.) (99.64% per TM-21) HID lamp lumen depreciation (65% at 6,000 hr.) LED (Calculated per IES-TM-21) 13,476 x 0.9964 = 13,428 Hours of Operation (in 1000s) * Data from National Lighting Bureau 9
% of Initial Light Output 5/31/2017 A Better Comparison! LED luminaire lumen depreciation (99.13% at 40,000 hr.) LEDs Dead LED (Calculated per IES-TM-21) Hours of Operation (in 1000s) * Data from National Lighting Bureau 150W LED Lumen Breakdown LED Lamp Lumens (per IES LM-79, irrelevant) Initial Fixture Lumens 14,038 100% Luminaire Efficiency Initial Delivered Lumens 13,476 96% Delivered Efficiency Mean Delivered Lumens 13,428 99.64% Lamp Lumen Depreciation 10
Less Energy and More Light! 450 Input Watts 11,394 Mean, delivered lumens at 6,000hrs 66% energy savings! 18% more light at task! 9 times the life! 154 Input Watts 13,428 Mean delivered lumens at 6,000 hrs What are the quality features of a well designed networked lighting control system? 11
Controls should be straightforward. An advanced degree in order to understand how should not be required. Lighting Control Design An overwhelming number of design options, components, work-arounds and should not be required. 12
Controls should have a simple cost breakdown. Fighting to understand the various component costs and what service is included in should not be required. 25 Controls should have a quick sales pitch. Hours to explain the basic system concept should not be required. 13
Controls should have inexpensive setup. Complicated pages of instructions and hours of should not be required. Controls should have simple wiring. 28 2-wire, 3-wire, 4-wire, Ethernet, twisted-shielded pair or DALI, WiFi, DMX, other complicated protocol interfaces to make one system should not be required. 14
Controls should not require software. Controls should have inexpensive programming. Complex coding languages and should not be required. 15
Controls should have quick commissioning. Years of training classes should not be required. Controls should have uncomplicated maintenance. Frantically searching for someone who is close by and qualified to make simple should not be required. 16
Controls should offer reliable energy savings. Calculations, spreadsheets, and guesses should not be required. Controls should be Future Proof. Endlessly searching to find the original designer to upgrade or make changes should not be required. 17
Controls should have a trouble-free warranty. A hard to find and hard to understand should not be required. Straightforward Intuitive to design Simple cost breakdown Quick sales pitch Inexpensive setup Simple wiring No software installation No programming Quick commissioning Uncomplicated maintenance Reliable energy monitoring Future proof Trouble-free warranty 18
What are the strategies and techniques of a well designed networked lighting control system? Occupancy/ Vacancy Sensing Lighting control strategies and techniques. Daylight Harvesting Scheduling Demand Response (aka Load Shedding) Personal Control Energy Management User Interface Scene and Zone Control Continuous Dimming Device Addressability Energy Monitoring 19
User Interface The tool used to read and adjust the system settings during start-up, commissioning and/or operation. Zone Control* The ability to group luminaires and create a unique lighting control zone. * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities 20
Scene Control The ability to adjust the light levels in one or more zones and then group them to create unique aesthetic effects. Continuous Dimming* The ability to provide 100+ steps of dimming so that it is perceived as smooth. * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities 21
High/Low Trim* maximum light output that is lower than its true capability. * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities Device Addressability* The ability to uniquely identify each luminaire and/or device in the lighting control system. * Requirement DLC Listed system capabilities 22
Energy Monitoring The ability to measure the power consumption of a lighting system accurately over a specific period of time. Occupancy Sensing* The ability to detect the presence or absence of occupants in a space. (Auto on, Auto off) 46 * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities 23
Vacancy Sensing* The ability to detect the absence of occupants in a space. 47 (Manual on, Auto off) * Potential requirement AEP Ohio ALC program Daylight Harvesting* (Open Loop) The ability to detect the amount of daylight entering a space. * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities 24
Daylight Harvesting* (Closed Loop) The ability to detect the amount of daylight and electric light in a space. * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities Task Tuning* light output for what the task requires. * Potential requirement AEP Ohio ALC program Requirement DLC Listed system capabilities 25
Personal Control* The ability for individual users to adjust the light level to their personal preference. * Potential requirement AEP Ohio ALC program Scheduling* The ability to set custom on/off/dim levels for lighting based upon the time of day, day of week, etc. * Potential requirement AEP Ohio ALC program 26
Demand Response* (aka Load Shedding*) The ability for a utility to contact a building manager and put the facility into a demand response scene for a set period of time. * Potential requirement AEP Ohio ALC program Energy Management The ability to monitor, diagnose and report operational performance. 27
Occupancy and Vacancy Sensing* Open-loop Daylight Harvesting* Closed-loop Daylight Harvesting* Task Tuning* Personal Control* Scheduling* Demand Response* Load Shedding* Energy Management User Interface Zone Control* Scene Control Continuous Dimming* High/Low Trim* Device Addressability* Energy Monitoring * AEP Ohio Incentive or DLC requirement What are the DLC and AEP requirements of a well designed networked lighting control system? 28
Networked Lighting Control Systems Technical Requirements for interior systems only Version 1.02 December 2, 2016 Required Networking of Luminaire & Devices Occupancy Sensing Daylight Harvesting High End Trim (Task Tuning) Zoning Luminaire and Device Addressability Continuous Dimming 29
Reported Type of User Interface Luminaire Level Control (non-integrated) Luminaire Level Control (integrated) Localized Processing/Distributed Intelligence Scheduling Personal Control Load Shedding (Demand Response) Plug Load Control BMS/EMS/HVAC Integration Energy Monitoring Device Monitoring/Remote Diagnostics Operational and Standby Power Consumption Networked Lighting Control Systems Technical Requirements for interior and exterior systems Version 2.0 June 1, 2017 30
Required DLC Listed System Capabilities Networking of Luminaire & Devices Occupancy/Traffic Sensing Daylight Harvesting/Photocell Control High End Trim (Task Tuning) Programmable Zoning Luminaire and Device Addressability Continuous Dimming Scheduling (only for exterior) Required DLC Listed System Capabilities Networking of Luminaire & Devices Occupancy/Traffic Sensing Daylight Harvesting/Photocell Control High End Trim (Task Tuning) Programmable Zoning Luminaire and Device Addressability Continuous Dimming Scheduling (only for exterior) 31
Reported Control Persistence Scheduling (only for interior) Energy Monitoring Device Monitoring/Remote Diagnostics Type of User Interface Luminaire Level Control (integrated, non-integrated removed) Personal Control Load Shedding (Demand Response) Plug Load Control External Systems Integration Emergency Lighting Security Color Changing/Tuning Start-up and Configuration Party Advanced Lighting Controls January 2017 32
Required Only LED Technology Master Control Interface Programming Devices and Luminaires Control Devices and Luminaires Occupancy Reporting Operational Reporting Energy Usage Reporting ( Required Strategies and Techniques (3 minimum) Occupancy/vacancy sensing Dimming (continuous/step) Task tuning High-end trimming Daylight harvesting User set preference (aka personal control) Exterior photocell control Demand response Zone control Load shedding Time scheduling 33
What about Code Compliance of a well designed networked lighting control system? As of 2016, the DOE estimates that the use of lighting controls in commercial buildings will save $10.4 billion annually! 34
Comply with all Energy Codes. Several Energy Codes (like ASHRAE 90.1 and Title 24) now offer lighting power adjustment factors for using controls in spaces! (above and beyond their mandatory code requirements) 35
ASHRAE 90.1-2013 What is the Energy Saving Potential of a well designed networked lighting control system? 36
Energy Saving Study A study by LBNL in 2012 concluded the following energy savings Occupancy sensing 24% Daylight Harvesting 28% Personal control 31% Task Tuning 36% Scheduling 24% Layering Strategies enables individual lighting control strategies to be layered to save up to 68% in energy costs. 37
Best Practice #2 Ensure your system has the lighting control strategies and techniques to comply with all local energy code needs. 38
Save energy! Save money! 39
What are some Applications of a well designed networked lighting control system? 40
Institutional Office Occupancy sensors, Personal control and Energy monitoring Scene control for Flexibility Recreation Center 41
Hospitality Scene control, Scheduling and Energy savings Retail Scene control, Scheduling and Energy Savings 42
Retail Scheduling simplified Scene control for Flexibility Educational 43
What about other applications? Sports Fields Labor savings 44
University Reliability and Less labor Office Safety and Security 45
Advanced Lighting Solutions Ben Koyle, LC, LEED Green Assoc. April 20, 2017 46