HVAC Maintenance Repair or Replace & Planned Replace Initiative Greg DuChane, Retail Vertical Market, Director, TRANE Jack Rehder, Western Territory Manager, TRANE Why Maintain Rooftop Units? Reduce Operating Costs Improve Comfort / Process Conditions Extend Equipment Life Tough Life for a Rooftop Unit Regarded as Semi Disposal Pieces of Equipment Operates in a Harsh Environment High Ambient Temperatures Brutal Radiant Heat Leaves, dust, pollen insects, rain, hail and snow. 1
Reduce Operating Costs Field Tests Have Shown that Rooftop Units Operate Well Below Stated EER Levels if Not Maintained A Tune Up Can Improve the Efficiency Savings Averaged 11% on 25 Rooftop Units in New England Study Savings Ranged from 22 42% on 23 Rooftop Units in Louisiana study Air-Side Vs. Refrigerant-Side Two Fluid Loops to Deal With Always Do Air Side Maintenance & Repairs First The Air Side Can Effect the Refrigerant Side, Such as Proper Air Flows Air-Side Focus Filters Evaporator Coil Fan Belts Motor Outside Air Dampers Cabinet Integrity 2
Filters Maintain Indoor Air Quality Protect Downstream Components Filters Changing Frequency Maintain Air Flow Reduce By Pass Air Indoor Air Quality Filter Structural Failure Clean Vs. Dirty Filters Effect on Energy Consumption Norminal cooling capacity (tons) a 10 10 10 Compressor input power (kw) a 9.8 9.75 9.67 Condenser fan input power (kw) a 0.56 0.56 0.56 Gross cooling capacity (Btu/h) a 112.79 110.10 105.14 Latent/sensible cooling ratio a 0.095 0.129 0.159 Total unit economics Total unit power (kw) d 12.42 12.27 11.70 EER (Btuh/W) e 9.08 8.97 8.98 Annual run time (hours/year) f 2,000 2,048 2,146 Annual energy use (kwh/year) g 24,840 25,129 25,102 Total annual cost (US$) $1,987 $2,010 $2,008 Annual dirty filter penalty Base Line $23 $21 Notes: a: Operating data from Carrier Corporation for unit # 48HJDO12 with standard fan. b: Assumed static pressure increase from dirty filter. c: Based on motor efficiency of 80 percent and belt drive efficiency of 95 percent. d: Sum of supply fan, compressor, and condenser fan power. e: Gross cooling capacity divided by total unit power. f: Assumed run time of 2,000 hours for a clean system; dirty systems run proportionately longer due to reduced cooling capacity. g: Total unit power times annnual run time. h: Electricity price; 8 cent per kwh. 3
Filters Filter Types Filter Depth (1,2 or 4 Inch) Filter Media Fiberglass Matt Polyester Matt Pleated Filter Material Options Filter material options Pressure drop Lifetime Filter type Average efficiency a (in. wg-new) b (months) c Unit cost d Annual cost e One-inch filters Fiberglass matt <20% 0.07 2 $0.94 $82.56 Polyester matt <20% 0.08 2 $0.94 $82.56 Environmental "EP40" 25% to 30% 0.22 3 $3.26 $92.16 Farr 20/20 pleated 20% to 25% 0.19 4 $4.25 $82.20 Farr 30/30 pleated 30% 0.23 3 $4.60 $113.60 Two-inch filters Fiberglass matt <20% 0.09 2 $150 $96.00 Polyester matt <20% 0.15 2 $1.50 $96.00 Environmental "EP40 pleated 25% to 30% 0.16 4 $3.51 $72.12 Farr 30/30 pleated 30% 0.14 6 $5.15 $61.20 Notes: a: Efficiency based on ASHRAE Standard 52.1. b: Pressure drop: Fiberglass and polyester information based on satalog data at 300 feet per second face velocity. All others based on independent test data at 375 feet per face velocity. c: Lifetime based on recommendations from filter vendor. Lifetime of fiberglass and polyester filters is short to prevent migration of dirt through the filter into the coil. Lifetime of pleated filters is based on changeout at a specified pressure drop. d: Single filter unit cost based on HVAC contractor order, case-lot purchase (at least a dozen filters), FOB Denver, size 20 x 20 inches. e: Annual cost based on replacement for a typical 10-ton unit at end of relative lifetime, four panels (20 x 20 inches), $10 labor cost for each filter change. How To Determine Filter Change Frequency? Time & Experience Measure Pressure Drop Install Transducers & Tie to EMS Install Pressure Differential Switch 4
Evaporator Coil Dirt on Evaporator Coil Reduces Air Flow Reduces Coil s Capacity to Transfer Heat Louisiana Field Test 87% of Units Needed Evaporator Coil Cleaning Clean Evaporator Coil Yearly? Measure Fan Amp Draw & Pressure Difference Dirty vs. Clean Evaporator Coils TONNAGE KWH WITH KWH WITH Savings/Yr Savings/Yr Savings/Yr Savings/Yr CLEAN DIRTY @ $ @ $ @ $ @ $ COILS 1 COILS 2 0.04/kwh 0.05/kwh 0.06/kwh 0.07/kwh $ 224.00 3 8200 11400 $ 128.00 $ 160.00 $ 192.00 5 11000 16200 $ 208.00 $ 260.00 $ 312.00 $ 364.00 7.5 14800 22400 $ 304.00 $ 380.00 $ 456.00 $ 532.00 10 24600 33600 $ 360.00 $ 450.00 $ 540.00 $ 630.00 15 32000 48800 $ 672.00 $ 840.00 $ 1,008.00 $ 1,176.00 20 41600 64800 $ 928.00 $ 1,160.00 $ 1,392.00 $ 1,624.00 25 54000 81600 $ 1,104.00 $ 1,380.00 $ 1,656.00 $ 1,932.00 30 61600 97800 $ 1,448.00 $ 1,810.00 $ 2,172.00 $ 2,534.00 40 83000 132800 $ 1,992.00 $ 2,490.00 $ 2,988.00 $ 3,486.00 50 104200 164600 $ 2,416.00 $ 3,020.00 $ 3,624.00 $ 4,228.00 60 126000 197200 $ 2,848.00 $ 3,560.00 $ 4,272.00 $ 4,984.00 1.Unit operating at 80*F ambient temperature, 45*Fsaturated suction temperature (standard design), F22 refrigerant, 2000 hours of operation. 2. Unit operating at 140*F-144*F saturated condensing temperatures at 45*F saturated suction temperature (337-354 psi head pressure) to stimulate dirty condenser operation multiplied by required hours to give the equivalent cooling in the above table. Fan Bearing Lubrication Blade Cleaning Blade Rotation Measure Air Flow 5
Belts 5 10% Loss in Energy Transfer Proper Belt Tension, Change Belts Regularly Belt Alignment Spare Belt in Unit Standard V Belt Vs. Cogged V Belts Increase Drive Efficiency 2 10% with Cog Belts Motors Sealed Bearings Specify Energy Efficient Motors New Replacement Comparison of Standard vs. Premium Efficient Supply Fan Motors Motor specifications Standard-efficiency motor Premium-efficiency motor Norminal size (hp) 2 2 Motor efficiency a 82.50% 90.20% Motor power (watts) b 1,938 1,795 Motor cost c $325 $410 Marginal upgrade cost n/a $85 Economic comparison Annual energy use (kwh) 9,691 8,975 Annual energy cost d $775 $718 Annual energy cost savings n/a $57 Payback (years) n/a 1.5 6
Outside Air Dampers Economizer Cooling Dry Bulb Sensor Increase Set Point to Save Energy Enthalpy Control (Reference & Comparative) Ultimate in Energy Savings Old Versions are Hard to Maintain Cabinet Integrity Many Access Panels Too Many Screws Old Gaskets & Seals Leaks in Cabinet Costs More than $100/Year Refrigerant-Side Focus Refrigerant Charge Compressor Condenser Coil Condenser Fan & Motor 7
Refrigerant Charge Undercharged Systems Caused by Leaks Reduces Energy Efficiency Low Pressures on both High & Low Sides Frosting on Evaporator Entrance Warm Suction Line, Cool Liquid Line Warm Supply Air Continuous Compressor Operation Refrigerant Charge Overcharged Systems Caused by Charging Method Air Side Problems Does Not Effect Efficiency as Severely Effect of Refrigerant Charge on Efficiency Efficiency 100 95 90 85 80 75 70 65 80 85 90 95 100 105 110 115 120 % of Charge 8
Field Test of Refrigerant Charges Number of Units 14 12 10 8 6 4 2 0 52% 12% 16% 12% 8% >-30% -16 to -30% -6 to -15 % +/- 5% >+6% Refrigerant Charge Charging System Correctly Measure Superheat & Sub Cooling Weighing Refrigerant Charge Compressor Meg Test Motor Test oil for acid, especially after compressor failures Measure Compressor Heat with EMS System Low Voltage 9
Condenser Coil Exposed to the Outdoor Elements A Dirty Coil Raises the Condenser Temperature by 10 degrees Can Cost Over $250/Year in Energy Best Money You Can Spend on Maintenance Clean Coils Annually Condenser Fans No Maintenance Required Watch Out for Rapid On Off Cycling of Fan Repair or Replace Points to consider when evaluating Repair or Replace The life expectancy of HVAC Equipment is 12 to 15 years What is the condition of your HVAC What is the condition of your HVAC Due to recessionary issues routine maintenance has been lax This reduces life expectancy Is your equipment R22, refrigerant price escalating New HVAC is far more energy efficient and will save you money 10
Repair or Replace Establish a History Data Base on Your HVAC If history does not exist perform an accurate survey of your HVAC Build a data base of asset information Installation date, brand, model, serial # capacity, voltage, type and capacity of heat, blower motor hp. Additional information to meet municipality codes Maintenance records and warranty information Repair or Replace Current Condition of HVAC Perform an Inspection Cabinetry must be intact, fastened properly to minimize air leakage Quality of equipment, reputable brand, or builders model Number of breakdowns, keep records Poorly maintained, inferior quality, and frequent breakdowns Replace If Rooftop Unit costs more than 50% to fix replace the rooftop unit Planned Replacement Program Something You Should Consider 11
Planned Replacement Program Market Data Industry shipments & construction starts indicate that the HVAC replacement market has been on a growth curve since 2009. Traditionally this has not been the case, HVAC shipments would track with commercial building starts. This data points to a strong replacement market in both Unitary & Applied unit shipments. During the recession maintenance took a back seat. Planned Replacement Program Planned Replacement Program Benefits The Planned Replacement Program is designed to address HVAC equipment that was installed in the midto late 1990 s. Most equipment is nearing the end of their service life of 12 to 15 years in retail applications. Older units were also developed prior to significant advances in efficiency technology. New HVAC equipment can lower energy costs by up to 40%. 12
Replacement Program Cost of Older Equipment Older equipment is more prone to breaking down, repair costs are also generally higher and more frequent with an older system. Spending capital to patch an older system whether it s for a $1,500 condenser coil or a $500 blower motor, plus labor costs adds up over time and doesn t improve operational efficiency. Avoid spending more money repairing old equipment, which may require only more repairs with age. Invest current and future repair costs in new equipment, which has the added benefit of higher efficiency, increased durability & service friendly features. Planned Replacement Program Key Benefits Avoid Expensive Emergency Replacement Situations Lower Replacement Costs Control the Timing of Capital Expenditures High Efficiency Equipment Offsets the Rising Costs of Energy Replacing older units from the 1990 s with new equipment delivers instant energy savings. As energy costs escalate, the return on investment is quicker. Planned Replacement Program More than Efficiency Replacing older equipment can also help improve comfort & indoor air quality. Proper sizing & duct design eliminate hot & cold spots, while humidity control equipment & high efficiency filters can minimize i i mold growth that t can tigg trigger health concerns. Enhanced comfort & air quality deliver a better customer experience & satisfaction and increased sales. Between higher efficiency, reduced costs and better environment, a planned replacement unit is the smart and affordable decision. 13
Planned Replacement Program Utility Inflation Projected electric rates also play into the Planned Replacement process. Industry projections notes gradual increases in electrical rates through 2030. Within modeling programs there is typically an input that allows for projected increases in electrical rates to be factored into the ROI calculation. Planned Replacement Program Mechanics Program Mechanics Facilities teams need to identifying older equipment (>12 15 years) on active properties. Prioritization of HVAC assets can have many drivers (repair cost, operating hours, equipment age, & facility remodeling) however the metric is determined the financial calculation begins to take shape. Planned Replacement Program Modeling Tools Restaurant (3,000 S.F.) 25 Tons (3 5 Ton RTU s) 6.0 EER Existing Unit 11.0 EER Replacement Unit 14
Replacement Program Implementation HVAC fleet management is a constant issue for retail facilities teams & also represents approximately 30 to 40 percent of electrical consumption. The Planned Replacement Program should become an annual process. The timing of your program is set to coincide with the restaurateurs capital funding processes & sustainability planning. Rebates & Incentives Percentage of Existing Programs Which Include Incentives Packaged Units 79% Controls 77% Unitary 73% Typical Payouts 50% 90% of the Incremental Cost of Higher Efficiency i Equipment Vs. Standard d 10% 20%, or more, of the Equipment Cost Usually Capped Out at 50% of the Total Installed Cost Goal is to Buy Paybacks Down to 2 Years or Less Purpose is to Reward Improvement of Local or ASHRAE Code Who is Eligible? All Rate Payers Paying the Systems Benefits Charge Government Entities are Eligible 15