Although the actions described in this section require more extensive implementation, they can dramatically increase the efficiency of your store. Ask your local utility for more information about initiating such projects.
The optimization of refrigeration systems can reduce energy use by 24% relative to standard practice. The following measures yield the largest savings.
Floating head pressure. Taking advantage of lower ambient temperatures to reduce refrigerant temperatures is a form of free cooling. One approach is to allow the pressure of the vapor coming out of the compressor (the “head pressure”) to float—that is, to drop with reduced ambient temperatures. This requires an expansion valve capable of operating at lower pressures and flow rates, and such valves are now commercially available. In addition, refrigerant pressures must be kept high enough to avoid “flashing”—the unwanted vaporization of refrigerant. According to the Washington State University Energy Extension Office, floating head pressure savings generally range from 3% to 10%.
Ambient and mechanical subcooling. Reducing the temperature of liquid refrigerant below its condensation temperature is called subcooling. This can be done either by using ambient air or water to remove heat from the liquid refrigerant (ambient subcooling) or by using an additional refrigeration system (mechanical subcooling). Colder refrigerant means either more cooling per pound of refrigerant delivered to the display case or shorter compressor run times because less refrigerant is needed, both of which can decrease energy use. Ambient subcooling is often more cost-effective than mechanical subcooling because it requires less equipment.
Evaporative condensers. Most condensers in grocery stores are air-cooled, but it’s also possible to use evaporative condensers, which are cooled by water spraying over the condensing coils. Evaporative condensers are more energy efficient than their air-cooled counterparts, but they do have a notable disadvantage: They require a water supply, which often means increased maintenance due to freezing, clogging, and mineral buildup. Evaporative condensers may be cost-effective in drier climates, but the added maintenance may make them unattractive in other climates.
Heat-recovery systems. Heat-recovery systems are available that capture waste heat from refrigeration equipment to make hot water for use in the store. Heat recovered from a 7.5-horsepower compressor can heat all of the hot water a midsize supermarket would use in its kitchens and bathrooms. Often, enough waste heat is also available to supply hot water coils for space heating in cold weather.
Display case shields. Aluminum display-case shields can reduce refrigeration load from the display case by 8% when applied overnight and by 40% when applied over a 24-hour holiday, relative to the load present without the shield. Products are kept colder when the shields are attached and remain colder for several hours after the shields are removed.
Evaporator-fan motors. Replacing existing shaded pole motors on evaporator fans with electronically commutated motors will reduce the energy consumption of refrigerator and freezer cases by up to one-third. Drop-in replacement designs have made this retrofit relatively simple for a technician to perform. Additionally, most evaporator-fan motors in walk-in units run continuously even though full airflow is usually required only about half the time. Consider introducing advanced controllers that slow the fans when full-speed operation is unnecessary. Annual energy savings from adding walk-in cooler controllers can range from 10% to 60%.
Anti-sweat heater controls. The latest anti-sweat heater controls sense humidity in the store’s ambient air and reduce the operation of their heaters in low-humidity conditions. They promise significant savings and quick payback, and they are relatively easy to install. Savings can be in the 6% to 20% range, according to the Washington State Energy Solutions Database.
Smart defrost controllers. When installed in walk-in freezers, a smart defrost controller monitors several variables and optimizes the number of daily defrost cycles. Adding these kits can save hundreds of dollars a year per freezer, compared to conventional defrosting practices, depending on the size of the freezer.
Automatic doors for walk-in coolers. In addition to adding strip curtains to walk-in coolers, automatic doors can provide even greater energy savings, though at a higher cost.
Consider combined heat and power
Combined heat and power (CHP) plants generate electricity at the point of use and allow the heat that would normally be lost in the power generation process to be recovered to provide necessary heating and cooling. CHP plants can power store equipment and provide backup power generation when grid power is unavailable, which serves to prevent product loss; they can also provide hot water and auxiliary cooling for the facility. In one example, a Whole Foods store in Brooklyn, New York, installed a 157-kW CHP plant to power chillers, provide hot water, and provide power in the event of a power outage. Read more about the steps this store took in the SustainableBusiness.com article Whole Foods Brooklyn Store Is Most Innovative Yet.
Consider desiccant dehumidification
In humid climates, much of the energy used in air conditioning goes to removing moisture from the air. Desiccant dehumidification can be a cost-effective solution for removing this moisture because it uses natural gas instead of electricity. In some cases, air-conditioning equipment can be smaller because it only gets used to cool dry air.
Upgrade to more efficient lighting
Lighting is critical to creating ambiance and making merchandise attractive to shoppers. High-quality lighting design can reduce energy bills and drive sales. If your facility uses T12 fluorescent lamps, relamping with high-performance T8 lamps and electronic ballasts can reduce your lighting energy consumption by 35%. Adding specular reflectors and new lenses and reducing the number of lamps can double the savings. Occupancy sensors or timers can add further savings in areas that aren’t highly trafficked, and payback periods of one to three years are common. LEDs can provide even greater savings: Fluorescent fixtures can be replaced with LED fixtures, LED retrofit kits, or LED tubes. New fixtures are the most efficient alternative; LED tubes are the easiest, but they may not provide adequate light levels or light distribution.
Refrigerated display case lighting. The efficiency of LEDs improves in cold operating environments (unlike linear fluorescent systems, the light output of which drops in low temperatures). LEDs are also directional in nature, allowing for less wasted light. As a result, LED case lighting can cut lighting energy use by more than 40% compared to T8 fluorescent lamps.
LEDs can also be tied to occupancy sensors so that the cases are only illuminated when shoppers are present. This is a particularly easy savings opportunity for supermarkets that remain open 24 hours a day. When Walmart initiated a pilot LED program integrating occupancy sensors into its LED display lighting, the company estimated the total time lights were on would drop from 24 to 15 hours per day—a 38% reduction. Occupancy sensors aren’t typically used for cases that are illuminated by fluorescent lighting because frequent switching reduces the life of fluorescent lamps, but it has no impact on LEDs. This approach also lengthens the life of LEDs—the more time the LEDs spend turned off, the longer the lamps will last.
The use of LEDs also reduces case compressor loads. Because the cases can use lower-wattage lamps, there’s less heat to dissipate. Additionally, the heat sink for an LED can be positioned to allow at least some of the heat to dissipate outside the case. With fluorescent lighting, most of the waste heat must be offset with additional cooling inside the case. When LEDs are used with occupancy sensors, they’ll spend less time in the on mode and therefore contribute less to the cooling load. LEDs also provide more even light distribution, can be dimmed, have a very long lifetime, and have been shown to appeal to shoppers at significantly greater rates than linear fluorescent lighting.
Use smart lighting design in parking lots
Reduce light levels. Parking lots are often overlit—an average of 1 foot-candle of light (sometimes less) is usually sufficient. Dimming and occupancy-sensing controls can also add to energy savings in parking lots.
Install more efficient light sources. The most common lamps used for outdoor lighting are high-intensity discharge (HID) sources—metal halide and high-pressure sodium (HPS). Fluorescent and induction lamps are also used in parking lots, but LEDs have become the most efficient alternative as their performance has improved and prices have come down.
LEDs can be a good choice for parking lots because the fixtures perform well in the cooler conditions that are typically found outside at night, and because LEDs work better with controls than HID products do. LEDs also offer long life (which reduces maintenance costs), they provide more even light distribution, and they produce less light pollution and light trespass—properties that improve aesthetics and contribute to energy savings. For example, in recent field testing, the US Department of Energy (DOE) found that LEDs had only somewhat higher efficacy than HPS lamps, but that LEDs provided substantial energy savings thanks to lower overall light levels enabled by better uniformity and less light pollution. The one downside is that users should be wary of the potential for glare. A parking lot retrofit of LEDs cut lighting energy use by 70% in the DOE-monitored Application Assessment of Bi-Level LED Parking Lot Lighting (PDF) at a Raley’s Supermarket in California.
Consider reflective roof coating
Painting the roof of a grocery store with white or other highly reflective paint can reduce the energy required for summer cooling by 25% to 65% and help trim peak demand, as well as increase the life of the roof. The US Environmental Protection Agency has a list of suitable reflective roof coating products.