Controlling Campus Energy Consumption via the IP Network:

A Feasibility Study for Achieving Energy

Efficiency with Cisco EnergyWise

Hunt Briggs Tim Haines

Bryan Hogle Sarah Howie

Behind the Curtain

2

Root Question What is the potential for network-based

technologies to collect, aggregate and communicate building energy data to enable informed, coordinated management by key decision makers?

Why is this important to us? We want to see resources (energy, money, time,

people) used as efficiently as possible.

3

Overview

I. Energy Management II. Network-Based Energy Management III. University Energy Management IV. University of Michigan Case Study V. Conclusions & Recommendations

4

I. ENERGY MANAGEMENT

5

Conclusions & Recommendations

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Energy

Management

Systematic tracking and planning of energy use

What is Energy Management?

– Metering & Monitoring consumption – Identifying & Implementing saving measures – Verifying Savings With Proper Measurements

-ACEEE

6

Conclusions & Recommendations

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Energy

Management

Energy Matters to Industry

Johnson Controls Energy Efficiency Indicator

7

0%

20%

40%

60%

80%

100% Not at all Important

Not Very Important

Important

Very Important

Extremely Important

Source: JCI EEI 2010

How Important Is Energy Management at your

organization?

0 1

2

3 4 5 6

7

8

9 10

6.5

Average: 6.6

Min: 1 Max: 8 Std. Dev: 2.8

Conclusions & Recommendations

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Energy

Management

Drivers of Commercial Energy Management

8

Regulatory

• Existing Regulation • Utility EERS • Building Codes

• Anticipated Regulation • ISO 50001

• GHG Management

Strategic

• Enhancing Public Image

• Attract & Retain Customers, Employees & Tenants

• Achieve Sustainability Goals

• Risk Management

Operational

• Energy Cost Savings • Improve Overall

Operational Efficiency • Demand Side

Management

Conclusions & Recommendations

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Energy

Management

Demand Side Management & Utility Billing

9

Charge Type Amount Used Rate Charge

Total Amount Due: = $6,480

Power Demand 248 kW $10.00/ kW = $2,480

Electricity Consumption 50,000 kWh 8¢/kWh = $4,000

0

100

200

300

02/01 02/06 02/11 02/16 02/21 02/26

kW

Power Demand

248 $avings Can Be Achieved by Reducing Consumption

or Limiting Demand Spikes

Conclusions & Recommendations

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Energy

Management

Commercial Building Systems

10 *Actual Values will depend on geography, building function, etc.

AC & Central Chillers Boilers & Heating Plumbing Electrical Security Lighting Building Envelope Building Automation Air Handling & Distribution

Source: EIA

Space Heating 36%

Cooling 8%

Ventilation 7%

Water Heating

8%

Lighting 20%

Cooking 3%

Refrigeration 6%

Office Equipment

1%

Computers 2%

Other 9%

Conclusions & Recommendations

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Energy

Management

II. NETWORK-BASED ENERGY MANAGEMENT

11

Conclusions & Recommendations

University Energy

Management

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

Cisco EnergyWise

12

Conclusions & Recommendations

University Energy

Management

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

Converging Systems- Smart Buildings

13

Features • Integrated Building

Controls • Remote Web-based

Management • Better Demand

Response Capabilities

Drivers • Open Control

Protocols (BACnet) • Software, Web • Analysis & Reporting • Sensor Networks

Smart Buildings

Information Technologies

Operations Technologies

Conclusions & Recommendations

University Energy

Management

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

Existing Building Control Infrastructure

ENTERPRISE APPLICATIONS Facility Management

Maintenance Management IT Network Management

Wireless

IP Telephony

BMS

VAV

FCU

Heat Pump

Chilled Beam

Boilers

Chillers

AHU

Building Mgmt

IP Camera

Lighting Control

General Lighting Channel Controllers

DSI/DALI Interface

Occupancy Detectors

VAV

FCU

Heat Pump

Chilled Beam

BMS

Building Mgmt

Lighting Control

General Lighting

DSI/DALI Interface

Occupancy Detectors

Access Control

Access Control

CCTV

DVR

*Illustration by Cisco Systems

Conclusions & Recommendations

University Energy

Management

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

A Converged

Solution

Energy & Power Metering

CCTV

DVR

Fire Alarm System

Smoke Sensor

Break Glass

Sounder

ENTERPRISE APPLICATIONS

Energy Management Building Management Facility Management Security Management Maintenance Management IT Network Management

Door Controllers

Access Control

Reader Technology

Intruder Panels

VAV

FCU

Heat Pump

Chilled Beam

Boilers

Chillers

BMS

AHU

Lighting Control

General Lighting Channel

Controllers

DSI/DALI Interface

Occupancy Detectors

UPS Monitoring

IP Camera IP Telephony

Wireless

Mediator

Switch Router

*Illustration by Cisco Systems

Conclusions & Recommendations

University Energy

Management

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

Platform to Analyze Data (Trends, etc)

Data Warehouse

Operational Data Energy-Related Data (From EnergyWise, for

example)

What Should Be Collected? Operational Data

– Occupancy – Utility Billing Data – Interval Data For All Points

Within The BAS Energy-Related Data

– Meter Data – Utility Interval Data – Weather

• Enterprise Energy Management Systems (EEMS)

16

Energy Data Management

Conclusions & Recommendations

University Energy

Management

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

III. ENERGY MANAGEMENT AT UNIVERSITIES

17

Conclusions & Recommendations

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

University Energy

Management

Key Traits of the University

• Thought leadership • Stakeholders • Diversity of missions within the university • Economics

– Non-profit (generally) – Primary revenue generation is student tuition

• Peer organizations – Competition – Trends in planning and reporting

18

Trends: - Importance of Personalization - Desire to be Leaders & Best - Need for Systemic Perspective

Conclusions & Recommendations

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

University Energy

Management

U of M Energy Basics

• Two sources of energy on campus – Steam – Electricity

• Points of energy use measurement – Central Power Plant can see overall campus

demand on a 15-minute scale – Building energy use is generally read only on a

monthly basis 19

Conclusions & Recommendations

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

University Energy

Management

Current Scenario: Data, Dollars and Decision Makers

20

Central Power Plant

• Mission: uninterrupted power

• Financial objective: cover costs of power purchasing and production

• Energy Data: total campus demand every 15 minutes

Facility Manager

• Mission: provide comfortable building environment

• Financial objective: manage overall budget, including operational costs

• Energy Data: monthly bill for building at large

External IT Group

• Mission: provide consistently excellent IT services to all user groups

• Financial objective: cover costs of labor and infrastructure

• Energy Data: at best, minimal tracking; at worst, nothing

Incentive Opportunity

Issue: Power Demand

Power Plant: Unable to see spike sources. Demand charge divided evenly. Facility Manager: Unable to see spike and paying average charge Opportunity: Demand side management + savings from demand stabilization

Incentive Opportunity

Issue: Device Management

Facility Manager: Unable to see energy use sources. External IT: Not charged for energy use. Opportunity: Data transparency + Service agreement standards

How can we use network-based energy management to take advantage of these opportunities?

Conclusions & Recommendations

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

University Energy

Management

21

ENTERPRISE APPLICATIONS Facility Management Maintenance Management IT Network Management

Wireless

IP Telephony

BMS

VAV

FCU

Heat Pump

Chilled Beam

Boilers

Chillers

AHU

Building Mgmt

IP Camera

Lighting Control

General Lighting Channel Controllers

DSI/DALI Interface

Occupancy Detectors

VAV

FCU

Heat Pump

Chilled Beam

BMS

Building Mgmt

Lighting Control

General Lighting

DSI/DALI Interface

Occupancy Detectors

Access Control

Access Control

CCTV

DVR

Conclusions & Recommendations

University of Michigan

Case Study Energy

Management Network-Based

Energy Management

University Energy

Management

IV. UNIVERSITY OF MICHIGAN CASE STUDY

22

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Protocol & Software • Cisco EnergyWise

– Communication & Monitoring Protocol – “Lives” on Network Switches

• Cisco Orchestrator – Control Interface – PC Client

23

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Why EnergyWise?

• Installed Cisco Hardware

• Potential energy savings w/ existing infrastructure

• Case study of university implementation

24

Juniper Switches,

1.6%

Cisco Switches,

98.4%

EW Compatible 53%

Not Compatible 47%

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Implementation Methodology 1. Survey existing IT energy management

initiatives 2. Identify relevant university stakeholders 3. Install EnergyWise & Orchestrator 4. Gather baseline energy data 5. Implement policies 6. Analyze Results

25

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Existing Green IT Initiatives

• Climate Savers – Green computing initiative – Increase awareness

• Big Fix – Central Power & Patch Management (CPPM) suite – Installed on 15,000 out of 50,000 computers

26

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Deployment Scope Natural Resources & Environment Dana Building

Ross School of Business Executive Residence

27

•Office of Academic Programs (OAP) - 11 Computers •Sites Computer Lab & Classroom - 49 Computers

• 214 Devices Total - 153 IP Phones - 47 Wireless Access Points

Stakeholder Discovery

28

Central ITS

Cisco Systems Ross IT

SNRE IT

ITS Sites

ITComm

Dana Dean’s Office

Climate Savers Ross Facilities

SNRE Facilities

Zone Maintenance

Building Automation Services

University CIO Office

Power Plant

What Campus Groups will we need to contact?

Graham Institute

Office of Campus Sustainability

Planet Blue

Coordinating Bodies:

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Baseline - Managed

Snow Day

29

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Baseline - Unmanaged

30

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

20 20 60 0

20

40

60

80

100

Previous Policy New Policy

No

Site B - Unmanaged

Monitor Sleep Computer Sleep

Min

utes

15 15 30 30

0

20

40

60

80

100

Previous Policy New Policy

Site A - Managed

Min

utes

Implement Policies

31

Previous policy met site needs

Note: Business hours only

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Implementation Challenges

32

Organizational

• Time consuming • Coordination issues • Piecemeal approach

Technical

• Lack of converged systems prevents management

• Reliability issues

User Impacts

• User experience is an IT manager’s 1st priority

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

IV. UNIVERSITY OF MICHIGAN CASE STUDY: RESULTS

33

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

Results of Policy Implementation

34

Average 30% Sleep State

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

35

0

2

4

6

8

10

12

14

16

18

20

22

24

0

500

1000

1500

2000

2500

3000

3500

4000

4500

0-3 3-6 6-9 9-12 12-15 15-18 18-21 21-24

Aver

age

time

Activ

e an

d Id

le (h

ours

/day

)

Num

ber o

f Com

pute

rs

Average Time On(hours/day)

Time On and Activity Levels for University Computers

# Computers Ave. Hours Active Ave. Hours Idle/Logged Off

0

200

400

600

800

1000

1200

1400

Sites Institute forSocial

Research

Ross Schoolof Business

College ofEngineering

Athletics ITS DesktopSupport

PlantOps SNRE Other

Num

ber o

f Com

pute

rs

Department

Number of Computers on 21-24 hours/day - Top Departments

36

User Experience is Critical

37

0.00

4.00

8.00

12.00

16.00

20.00

24.00

Sites Athletics College ofEngineering

Ross Schoolof Business

PlantOps SNRE

Tim

e (h

ours

)

Department

Average Time in Energy States for PCs by Department

Off

Standby

Active

Idle/Logged Off

Current Levels of Energy Management Differ

38

Engineering 1471

Athletics 406

PlantOps 633

Business 1024

SNRE 278

Sites 1280

0.0%

20.0%

40.0%

60.0%

80.0%

100.0%

0 6 12 18 24

Aver

age

time

Idle

as %

of t

ime

On

Average time in On state (hours)

Opportunity for Energy Savings by Department (number of department computers below department name)

Energy Saving Opportunity is Fragmented

How much can U of M save?

• Over one year: – 525,000 kWh saved – $42,000 reduction in energy costs (at $0.08/kWh)

39

• Assume: – 4000 computers

– 30% of day in Sleep state

Consider 50,000 Computers + Heating + Cooling + Ventilation + Lighting + …

Conclusions & Recommendations

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study

V. CONCLUSIONS & RECOMMENDATIONS

40

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Conclusions &

Recommendations

Conclusions Current limitations in energy data measurement are a barrier to effectively incentivizing energy efficiency

The University’s organizational complexity impedes implementation of energy management solutions

A complete energy management solution needs to consider user experience

Central PC energy management can potentially save the University several hundred thousand dollars

41

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Conclusions &

Recommendations

Root Question

What is the potential for network-based technologies to collect, aggregate and communicate building energy data to enable informed, coordinated management by key decision makers?

42

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Conclusions &

Recommendations

Recommended Future Work Align energy decisions and costs

– Investigate finance and accounting structure to incentivize future energy management

– Map energy decision making at U of M

Conduct study of factors affecting user experience

Implement a comprehensive Enterprise Energy Management System (EEMS) – Expand scope and granularity of data – Pilot converged building energy management

43

Energy Management

Network-Based Energy

Management

University Energy

Management

University of Michigan

Case Study Conclusions &

Recommendations

44

Questions?