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Ammonia versus Freon

Ammonia is the most energy efficient refrigerant and is manufactured using natural elements (nitrogen and hydrogen) It has been used successfully and safely for well over 100 years and will not be phased out like R-22. However its toxic nature and pungent odor requires that more stringent code regulations be adopted in the design of the plant room. When using ammonia some jurisdictions require that a professional operator be on staff, which can increase the total facility operating cost. For larger multi-sheet facilities you should very strongly consider ammonia for its increased energy efficiency advantage.

R-22 refrigerant is more expensive and less efficient than ammonia, however there are some benefits. Plant room and operator requirements are not as rigid as ammonia. Many of the new refrigerants also totally ozone friendly and will not be phased out like R-22 will be. R-22 compressors generally require less maintenance than ammonia compressors.

Power Factor Correction

Power factor is the relationship (phase) of current and voltage in AC electrical distribution systems. Under ideal conditions current and voltage are "in phase" and the power factor is 100%. If inductive loads, e.g. motors, are present, power factors less than 100%, typically in the range of 80% to 90% can occur.

Low power factor, electrically speaking, cause's heavier current to flow in power distribution lines in order to deliver a given number of kilowatts to an electrical load.

Because the utility company must invest in oversized equipment to serve low power factor loads, a charge is commonly assessed on a facility's electric bill to recover the equipment costs and lost energy caused by low power factor.

Electric motors used to drive the refrigeration equipment commonly cause the voltage and current to get out of alignment. Power factor correction capacitors "re-align" the voltage and current with each other. This is true with both fixed capacitors and automatic capacitor banks. These capacitors should be installed on all motors 25 hp and larger.

Computer Control System

The following are some of the many advantages of computer control. The computer system can utilizes a technique known as floating suction. It will monitor the rate that the ice temperature is changing and select just enough compressor capacity to accomplish the required cooling task while maintaining consistent ice temperature. For every degree the suction pressure can be raised the power can be reduced by approximately 1.5%. The computer can respond to any type of sensor including slab sensors, brine sensors, in ice sensors, and infrared sensors.

The computer can be programmed to provide night set back to minimize running during unoccupied times or in areas with off peak loads the ice can be run down colder during periods with lower utility rates.

It is very cost effective to float the head pressure down during periods of colder ambient temperatures. Complicated formulas can be programmed into the computer to minimize the ratio of condenser fan to compressor horsepower. For every degree the discharge temperature can be reduced by approximately 1%.

High Efficient Motors and Soft Start Controllers

It is always important to use motors with a high efficiency rating. To increase the total system efficiency "Soft Start Controllers" can be installed on the compressor motors. A soft start controller will greatly reduce inrush current and the consequential peak demand loads. The soft start also reduces the strain on the compressor during the high torque generated at start up. Any reduction in your power bills as a result of a soft start controller will depend on the method used to calculate the demand load. You will have to check with your utility company.

Dual Drive Brine Pumps

Dual drive brine pumps allow a 60% reduction in pump horsepower by stopping the large main brine pump and starting a lower horsepower pony pump. The reduced horsepower pony pump will still provide 60% to 75% of the pumping capacity of the main pump. Calculations must be run to determine the reduced flow capacity of the chiller and the level of staging offered by the compressors. In most cases a very favorable horsepower per ton improvement can be obtained. In addition to the energy savings you will have the added security of a backup brine pump in the event of a failure.

Oversized Evaporative Condenser with Energy Miser Fan System

Evaporative condensers are the most efficient method of condensing. Consideration should be taken for local water conservation regulations, health regulations (legionnaire's disease), and the mineral content of the water to ensure is appropriate for your area.

It is always wise to select a condenser for the lowest condensing temperature that can be practically achieved. It is good design practice to size a condenser for a maximum of 90 degrees condensing at full load conditions. For every degree you reduce the discharge temperature the efficiency will increase by approximately 1%.

A dual drive fan system will reduce the fan horsepower by 60% to 80% during reduced load conditions and during colder weather. This format will also provide a backup in the event of a fan motor failure.

A variable frequency drive (VFD) fan control will also provide excellent condenser efficiency. For optimum efficiency a computer should control the VFD. The programming will factor in the condenser load profile, a refrigerant table, and relative humidity.

Oversized Flooded Chiller

A properly engineered oversized chiller will provide several benefits to the system. The suction pressures can be operated at a higher level, increasing refrigeration system efficiencies by 1 1/2% for every degree the suction temperature is increased. Pressure drops will be substantially reduced on the brine side, minimizing pump horsepower and destructive velocities. The additional size will minimize the negative effects of scaling, further increasing the life of the chiller. The added surface area will facilitate rapid temperature pull-downs when required.

Oversized Titanium Plate Chiller

Titanium plate chillers offer five major advantages.

1. The optimum in corrosion resistance
2. Herringbone counter-flow pattern enables excellent heat transfer at greatly reduced flow rates, thus minimizing the required brine pump horsepower
3. Reduced floor space requirements
4. An exceptionally reduced refrigerant charge of 35 pounds versus 1200 pounds for a conventional flooded chiller of the same capacity
5. Ease of field service. An oversized plate chiller, which will reduce energy requirements as well as facilitate rapid temperature pull-down when required

Liquid Refrigerant Sub-cooling / Snow Melt Pit

The entire electrical load in a refrigeration system is used to make ice and then up to 10 times a day the ice is scraped off and allowed to melt. Many facilities even use more power by melting the snow with hot water. Traditionally snow melt pits obtained the heat from high temperature discharge gas. On a freon system a sub-cooling system will preserve the high temperature discharge gas for heating hot water where it is more valuable. The liquid sub-cooling method melts the snow and recovers the cooling value of it, which in turn is directed right back into the refrigeration system for a capacity boost of up to 30%. With a snow melt pit the snow can be eliminated without opening the outside doors and letting the heat in. The refrigeration plant will run cooler and the refrigeration power costs will be reduced significantly during the ice melting process.

Hot Water Heat Reclaim

It is very economical to reclaim waste heat from the refrigeration plant for heating hot water. Hot water in arenas is typically used for the showers or for filling the ice resurfacer. This does not eliminate the need for a supplemental boiler but will drastically reduce the cost of operating it.

Desiccant Dehumidifier

One of the largest contributing factors of having a great ice surface is proper humidity control in the building envelope. Excess humidity also increases the refrigeration load on the ice plant. The most reliable and economical way of dealing with the humidity is through the use of a desiccant dehumidifier. This will provide you with an excellent ice surface during all weather conditions at a fraction of the operating cost of the old style mechanical dehumidifiers.

Low Emissivity Ceiling

Up to 30% of the heat load entering a typical community arena is radiant heat generated from the suns rays entering through the roof. A low emissivity ceiling can block out up to 97% of this radiant heat, drastically reducing the load on the refrigeration plant. A low-e ceiling should be strongly considered on all recreational ice facility.

Diesel or Gas Driven Compressors

In some locations, due to the availability or cost of electrical power, it may be favorable to operate one or all of the compressors with internal combustion engines. In areas with time of day billing, it can be advantages to operate the engine during peak electrical demand periods. Additional heat reclaim is also available from the engine cooling system. Some gas companies offer significant grants for the conversion to gas. In deciding if this is a good option, you must calculate the additional cost of maintenance the engines will require.

Building Heating Integration

The whole refrigeration process involves moving heat from one area to another. In many arenas this heat is wasted at the condenser or used for inefficient purposes such as melting snow. It is very efficient to use this heat for heating the public areas throughout the complex or adjacent buildings. We have saved Billions of kilowatts of energy by integrating ice rink refrigeration systems with building heating systems. We would be glad to design a system for your facility that will save you hundreds of thousands of dollars.

The chart above depicts the various sources of heat gain in a typical ice skating facility. The chart is generic and will vary from place to place and season to season. The information contained in the chart is a good visual indication of where energy consumption is prevalent and where energy saving measures should be emphasized.

For instance it becomes obvious that installing a low emissivity ceiling to reduce radiant heat load will provide far better value for your energy conservation dollars than insulating the headers if both energy conservation projects were of a similar value.