2. Vacuum pumps
The vacuum pump operates during the
milk harvest and equipment washing and
can consume 20 percent to 25 percent of all
electrical energy use on a dairy farm. The
vacuum pump creates negative air pressure
that draws milk from the cow and assists
in the milk flow from the milk receiver to
either the bulk tank or the receiver bowl.
The airflow also sends water and cleaning
agents through the milking system during
the washing process.
There are four main types of vacuum
pumps: sliding vane rotary pumps, water-
ring pumps, rotary lobe (blower) pumps and
turbine pumps. Each of these operates
and uses energy differently. Vacuum
pumps become less efficient as the vacuum
level increases (Ludington et al., 2004).
Milking process Therefore, operating the vacuum pump at
The milking process consists of harvesting lower vacuum levels conserves energy.
Related ATTRA
milk from the dairy cow and transporting the
Publications Sizing the vacuum pump to meet the needs
milk to a bulk tank for storage. This process
Farm Energy can take place one or two or more times per of the milking and washing system can
Calculators day and most dairies schedule their lactations reduce capital costs for equipment, reduce
Conserving Fuel on for a continuous milk supply throughout the energy operating costs during the life cycle
the Farm year. On average, milking utilizes 18 percent of the pump and ensure that the pump is
of the electrical energy use on a dairy farm performing properly. The size of the vacuum
Renewable Energy
(Peterson, 2008). pump is dependent on all of the components
Opportunities on
the Farm
Ef f icient Agricultural
Buildings:
An Overview
Dairy Production
on Pasture:
An Introduction to
Grass-Based and
Seasonal Dairying
The vacuum pump operates during milking and equipment washing and is often the primary electrical energy
user. Photo by Andy Pressman.
Page 2 ATTRA Dairy Farm Energy Ef f iciency
3. in the system that admit air during opera- pump near the end of each milking is a
tion. Pumps are generally sized by account- good way to detect problems with the pump
ing for the amount of air admitted into the or electrical load. High motor temperatures
milking system during the milk harvest plus may indicate the need for a vacuum adjust-
a 50 percent reserve to account for acciden- ment, removal of exhaust restrictions, repair
tal air admittance and the wear and tear of of rotary vane oiling systems or cleaning
parts (MMMC, 1993). Outdated indus- lobe blower pumps. Changes in the speed
try standards used to recommend oversized of the vacuum pump can be caused by air
vacuum pumps in part because of an incor- leaks in the milking system, degraded drain
rect belief that additional vacuum capacity is seals, loose pump belts, malfunctioning pul-
necessary for washing. An oversized vacuum
sators or a malfunctioning VSD vacuum
pump may overheat as the pump ends its cycle.
sensor. A 5-cubic-foot-per-minute air leak in
The current industry performance stan-
the vacuum system can amount to over $100
dard, ASAE Standard S518.2 Feb03, Milk-
ing Machine Installations, provides current in wasted electrical costs (Peterson, 2008).
sizing guidelines for dairy vacuum pumps Problems associated with vacuum pumps
(Ludington et al., 2004). can be avoided by regularly checking vac-
uum levels and the operation of the VSD.
E
nergy
Variable-speed drives operating
A variable-speed drive (VSD), also referred Milk cooling systems costs of a
to as an adjustable-speed drive or variable- Cooling milk accounts for most of the elec- vacuum system
frequency drive, is an energy-efficient tech- trical energy consumption on a dairy farm. with a VSD can be
nology used for controlling the vacuum level Milk is harvested from a cow at around 95
reduced by up to
on sliding-vane rotary pumps and rotary- to 99 degrees Fahrenheit (F). To maintain
lobe pumps. Traditional vacuum systems 60 percent.
high milk quality, including low bacteria
run at maximum speed only, and rely on a counts, the raw milk temperature needs to
vacuum regulator to vent excess air that is be lowered quickly to around 38 degrees.
not being used during milking or washing Refrigeration systems consist of a bulk tank,
operations. A VSD adjusts the speed of the a motor-driven compressor unit, an evapora-
pump motor to meet the vacuum demand so tor and a condenser unit. The system oper-
that equal amounts of air are being removed ates by pumping a refrigeration coolant in a
by the vacuum pump and entering the milk- cycle that gives off heat as it condenses. Heat
ing system. By eliminating the amount of air exchangers cooled by well water, variable-
that would be admitted through a regulator, speed drives on the milk pump, refrigeration
the motor uses less horsepower during most
heat recovery units and scroll compressors
of the milking process. A VSD on a vacuum
are all energy conservation technologies that
pump eliminates the need for a conven-
tional regulator because less energy is deliv- can reduce the energy consumed in the cool-
ered to the motor and its operating speeds ing system.
are reduced. Energy operating costs of a vac- There are two types of milk cooling
uum system with a VSD can be reduced by systems used on dairy farms. A direct-
up to 60 percent (Ludington et al., 2004). expansion cooling system cools the milk
In addition, lowering the vacuum pump’s directly in the bulk tank by using evapora-
RPMs can extend its life as there will be less tor plates that expand in the lower portion
wear and maintenance costs. of the tank. Indirect, or instant, cooling
systems rely on heat exchangers to precool
Vacuum pump maintenance the milk before it enters the bulk tank. A
Following the manufacturer’s maintenance precooling heat exchanger can lower milk
schedule, along with routine maintenance on temperatures as much as 40 degrees, resulting
all vacuum pump systems, can save energy. in refrigeration energy reductions of about
Checking the temperature of the vacuum 60 percent (Sanford, 2003b).
www.attra.ncat.org ATTRA Page 3
4. Heat exchangers the milk travels through multiple circuits
and the coolant flows through a single pass,
Heat exchangers used for precooling raw
or circuit. Farms that milk for long periods
milk transfer the heat from the milk to
of time can use heat exchangers that are
an intermediate cooling fluid, such as well
designed for two coolants. The use of two
water or a water-glycol solution, by having
different cooling fluids, such as first precooling
the milk and coolant flow in concurrent or
with well water and then with chilled water
counterflow configurations. In a concurrent
or a glycol-water solution, can cool the milk
flow configuration, the milk and coolant
as it is harvested.
flow in the same direction. The fluids flow
in opposite directions in a counterflow pat-
tern. Counterflow systems allow for lower Precooler energy savings
milk temperatures. The amount of cooling Installing a properly sized precooler can reduce
that takes place depends on the flow of the refrigeration energy consumption by about 60
milk in relation to the flow of the coolant, in percent (Sanford, 2003b). A properly sized
addition to the heat transfer area, the num- well water heat exchanger can reduce milk
ber of times the milk passes through the temperatures to within 5 to 10 degrees of the
coolant and the temperature of the coolant. groundwater temperature. Higher efficiency
I
nstalling a
properly sized
for precooling can be achieved with a 1-1 ratio
Well-water heat exchangers have been imple-
of coolant to milk flow and by using the larg-
precooler can mented in precooling systems for more than
est water lines possible in order to maximize
reduce refrigeration 20 years and can reduce cooling costs by
the coolant flow. Other factors that determine
energy consumption 0.2 to 0.3 kWh/cwt (hundred weight of
the energy and economic savings of a precooler
milk) (Ludington et al., 2004). There are
by about 60 percent. include herd size, number and size of compres-
two types of heat exchangers used for pre-
sors, type of coolant used and the age of the
cooling: shell-and-tube heat exchangers and
bulk tank. An added benefit of using water
plate heat exchangers. Shell-and-tube heat
for precooling is that it can afterwards be used
exchangers consist of a single small tube or
for livestock drinking water. Cows depend
multiple small tubes inside of a larger tube.
on drinking water to produce milk and
The milk flows through the smaller tube(s)
prefer warm water to cold. The warm water
while the well water flows through the larger
can also be used to perform other tasks, such
tube. Plate heat exchangers are made up of
as washing and heating.
a series of metal plates that are located side
by side. Milk and well water run in oppo-
site flow channels and the well water absorbs Variable-speed milk pumps
the heat from the milk on the opposite side As previously stated, a vacuum is required
of each plate. Plate heat exchangers are rel- to harvest milk. The milk, however, can-
atively small in size and, unlike shell-and- not transfer from a pipeline that is under
tube heat exchangers, additional plates can a vacuum to a bulk tank that is at normal
be added to increase capacity. atmospheric pressure. To compensate for the
difference in pressure, milk can flow into a
Heat exchangers are designed so that the
receiver bowl that triggers a milk transfer
milk and coolant make single or multiple
pump to push the milk from the receiver
passes between the plates or tubes. In a sin-
bowl either through a heat exchanger or
gle-pass heat exchanger, a circuit is arranged
directly into the bulk tank. Another option
so that the two fluids are in contact as they
that eliminates the receiver bowl and milk
go through separate sets of plates or tubes
transfer pump requires putting the bulk
before exiting the heat exchanger. Multi-
tank under a vacuum by placing rubber seals
ple-pass heat exchangers route the milk and
on the bulk tank covers.
coolant flow through two or more circuits,
putting the milk channels in contact with A variable-speed milk transfer pump
the coolant channels for longer periods of can further reduce energy use by slow-
time. A heat exchanger can be designed so ing the flow rate of milk through the heat
Page 4 ATTRA Dairy Farm Energy Ef f iciency
5. exchanger. A lower and more continuous
milk flow rate through the heat exchanger
increases the coolant-to-milk ratio and
results in greater milk cooling. Milk can be
cooled by an additional 15 to 20 degrees
by installing a variable-speed milk transfer
pump (Sanford, 2004c).
Refrigeration heat recovery units
Refrigeration heat recovery units (RHR)
capture the waste refrigeration heat from
the condenser to preheat water before it is
transferred to a water heater. An RHR unit
can recover 20 to 60 percent of the energy
that is required to cool milk for storage
(Sanford, 2004b). Depending on the num-
ber of cows being milked, the RHR storage A well water precooler (far right) cuts compressor use by using groundwater to
tank should be sized to provide enough hot pre-cool the milk. Photo by Andy Pressman.
water for one milking. Th is includes hot
water for washing the milking system and needed to remove heat from the milk and
for washing the bulk tank. The payback for may, in fact, increase overall energy costs.
purchasing an RHR unit depends on the
savings from heating water and will vary Compressors
greatly from farm to farm. The function of a compressor is to compress
the cold, low-pressure refrigerant gas from
Types of refrigeration heat the evaporator to a high-pressure, high-tem-
recovery units perature state for condensing. The three
There are two types of RHR units: desu- types of refrigeration compressors used for
perheating and fully condensing units. A milk cooling on dairy farms are the recip-
desuperheating unit operates only when rocating, scroll and discus. The reciprocat-
the refrigeration system operates and pro- ing compressor is the most common and can
duces water temperatures around 95 to 115 be either open type, hermetic or accessible
degrees (Ludington et al., 2004). These units hermetic. The scroll and discus compressors
can be inexpensive to add, but only part of are newer and more efficient than recipro-
the available heat can be transferred to the cating compressors. Research has shown that
water. Nearly all of the available refrigeration replacing a failed reciprocating compressor
heat is recovered as hot water from a fully with a new scroll compressor can reduce
condensing unit, with temperatures reaching milk cooling costs by 20 percent because
120 to 140 degrees (Ludington et al., 2004). of a reduction in the electrical demand
This type of RHR unit meets the require- (Ludington et al., 2004).
ments of the cooling system by using a valve
to control the flow of cold water through Heating water
the heat exchanger. Once the storage tank Hot water is essential for producing high-qual-
is full, excess warm water can continue to ity milk on dairy farms and is primarily used
be used and not wasted. A fully condens- for cleaning milking systems. The amount of
ing RHR unit replaces the need for a regular hot water required varies from farm to farm
condenser in the refrigeration system and is and depends on the size of the milking herd
best integrated as part of a new or replace- and the type and size of the milking system.
ment refrigeration system. If nearly all of the On average, a minimum of 4 gallons of water
energy captured by the RHR unit is used at 170 degrees are required for each milking
for preheating water, then a precooler is not unit (Ludington et al., 2004). Hot water is
www.attra.ncat.org ATTRA Page 5
6. generally produced by water heaters that use in certified organic production and process-
either fuel oil, natural or propane gas, solar ing (National Organic Program) but some
energy or electricity. For some dairy farms, may be permitted for use on organic dair-
heating water can account for about 25 ies (USDA, 2000). Check with your organic
percent of the total energy used on the farm certifier to see if they have any restrictions
(Sanford, 2003a). for use of dairy acid sanitizers.
Types of water heaters Electric control devices and
There are several ways to reduce the amount peak demands
of energy used for heating water. Whether Using a control device for electric water heat-
using a direct or indirect water heater, overall ers can reduce electricity use during periods
efficiency is determined by the combustion of expected increases in demand above the
efficiency of the fuel source and the amount average supply level, also known as peak
of heat loss from the storage tank, known demand. Time clocks provide a simple and
as standby loss. A direct water heater com- cost-effective way to control water heaters.
bines the water storage tank and the heat- Shifting electrical loads to off-peak or low
ing element. The storage tank in an indirect
O
n average, demand hours and off-peak utility rates not
water heater contains a heat exchanger that only ensures farmers of having hot water at
lighting
is connected to a separate boiler unit. Insu- a reasonable cost, but also benefits the util-
represents lating the storage tank and connecting pipes ity provider by allowing direct control of the
17 percent of total can reduce standby losses for both types of energy demand on their system. Many util-
dairy farm electrical water heaters. The sides and top of an elec- ity companies offer incentive rates or rebates
energy use. tric water heater and the sides of gas and oil to encourage farmers to participate in elec-
water heaters can be insulated. tric water heater control programs. Not all
utility companies offer off-peak utility rates,
Water temperatures so it is best to check with local service pro-
Proper water temperatures are essential for viders to see if off-peak rates are available.
cleaning milking equipment. Using warm
or cold water when possible can help reduce Lighting
energy costs. A warm-water pre-rinse, about Appropriate lighting can improve productiv-
95 to 110 degrees, does not cause the milk ity and safety on a dairy farm. On average,
to stick to the equipment, which is a prob- lighting represents 17 percent of total dairy
lem with cold water. Additionally, a warm farm electrical energy use (Peterson, 2008).
water rinse does not cause mineral and pro- Optimal lighting conditions may increase
tein deposits in the pipeline, as is often the milk productivity and conserve energy con-
case when using hot water. The wash cycle sumption. Factors that contribute to increased
requires water temperatures between 120 milk production include the type of light,
and 170 degrees. Dairy farms require the the amount of light provided per watt, the
use of commercial water heaters since resi-
temperature of the work area, the height of the
dential electric water heaters are thermostati-
ceilings and the length of the lighting period.
cally controlled not to go above 140 degrees
because of federal safety regulations. The Lighting requirements on a dairy farm can
thermostat range for commercial water heat- be divided into three categories. The first
ers is 100 to 180 degrees. A cold acid rinse category is visually intensive task lighting,
will control mineral and bacterial buildup which requires the highest lighting levels
in the milk lines and will help conserve hot (Ludington et al., 2004). Areas that bene-
water. There are many types of dairy acid fit from this type of lighting include milk-
sanitizers and each one may have differ- ing parlors; equipment washing, equipment
ent rinse instructions. Most of these sani- maintenance and repair areas; offices; mater-
tizers are not listed on the National List of nity and veterinary treatment areas; and
Allowed and Prohibited Substances for use utility rooms. The second category includes
Page 6 ATTRA Dairy Farm Energy Ef f iciency
7. lighting for holding areas, feeding areas, Fluorescent lights
animal sorting and observation and gen- Fluorescent lights are made of a frame, ballast,
eral cleanup. These areas and tasks require light socket and the lamp(s). Ballasts provide
high to moderate lighting levels. Finally, low the needed voltage, current and waveform for
to moderate lighting levels are adequate for starting and operating fluorescent and high-
general lighting for livestock resting areas, intensity discharge lamps. The lamps are avail-
passageway lighting, general room lighting able in many different lengths and diameters,
and indoor and outdoor security lighting. shapes, color temperature ratings and mini-
mum operating temperature ranges. Fluorescent
Lamp types lamps range in length from 6 to 96 inches long.
The diameter of the lamp is expressed in eighths
There are three types of lighting systems of an inch and lamps come in the following
used on dairy farms: incandescent lamps, diameters: T-5, T-6, T-8, T-9, T-10, T-12, and
fluorescent lamps and high-intensity dis- T-17. A T-12 lamp is 12/8 inch, or 1.5 inches,
charge lamps. in diameter, while a T-8 is 8/8 inch, or 1
inch in diameter (Sanford, 2004a).
Incandescent lamps
Fluorescent lamps are linear (straight),
Incandescent lamps are common on many circular or U-shaped. The color temperature
dairy farms, although today they are consid- index, or CCT, refers to the color appearance
ered to be an inefficient light source. Their of the light emitted by a lamp (Sanford,
light output is only 10 percent, with the 2004a). It is indicated in degrees Kelvin (K).
remaining 90 percent of energy given off as Lower temperature values produce a red or
heat (Hiatt, 2008). orange color and refer to a warm emitted
Lamp Type Comparison Chart
Adapted from Sanford, 2004a and U.S. Department of Energy
Efficiency (Lumens/ Correlated Color
Lamp Type Color Lighting Tasks
Watt)* Temperature (CCT)(K)
Incandescent 5-20 White 2800 General
Milking parlor, milk
room, holding area,
Fluorescent (T-8 and
30-110 Bluish to White 2700-6500 office, equipment
T-12)
washing maternity/
veterinary area
Compact Fluorescent 45-72 White 2700-6500 General
Mercury Vapor 25-60 Bluish 3200-7000 Outdoor
Milking parlor, holding
area, milk room, equip-
Metal Halide 41-115 Bluish 3700 ment washing, mater-
nity/veterinary area,
outdoor
Milking parlor, hold-
High Pressure Sodium 50-140 Yellow-Orange 2100 ing area, feeding area,
outdoor
Low Pressure Sodium 60-150 Yellow Outdoor
* Efficiency defined as the ratio of light produced (lumens) to energy consumed (watts).
www.attra.ncat.org ATTRA Page 7
8. light. Higher temperature values produce High-intensity discharge lights
a blue, or cool, light source. The CCT val-
High intensity discharge (HID) lamps are a
ues for fluorescent lamps range from 3,000
very bright and efficient light source. HID
to 5,000 degrees K, while the average CCT
lamps often require a warm-up period and
value of an incandescent lamp is around
generate light by heating a gas mixture in the
2,800 degrees K. Minimum operating tem-
lamp. HID lamps must be mounted high in
peratures for fluorescent lamps are between
order to spread the light and to avoid a glare.
–20 and 50 degrees Fahrenheit, depending
Some HID fixtures can be equipped with a
on whether the ballast is electromagnetic or
diff user that distributes the light horizon-
the more energy-efficient electric type.
tally. The four common types of HID lights
The most common type of fluorescent lamp are mercury vapor, metal halide, high-pres-
is the T-12. However, smaller diameter lamps sure sodium and low-pressure sodium.
provide more light for a watt of power. Com-
pared to a T-12 lamp and ballast, the T-8 Mercury vapor lamps
fluorescent lamp provides about 15 percent Mercury vapor lamps emit a favorable blue-
more light, or lumens, and the ballasts are 40 white color that mimics daylight. However,
percent more efficient (Sanford, 2004a). The mercury vapor lamps are the least efficient of
A
100-watt
most energy-efficient fluorescent lamp is the the HID lamps, emitting only 32 lumens for
high- a watt. In addition, their disposal poses an
T-5, but that lamp tends to produce too much
pressure heat in an enclosed fixture. Enclosing fixtures environmental risk due to the mercury gas.
sodium lamp can in agriculture lighting systems protects the
provide 2.5 times housing from corrosion and protects the lamp Metal halide lamps
from dust, humidity and manure gases, all of Metal halide HID lamps provide the best
more light than a
which can shorten the life of a lamp. color of all the HID lamps and emit about 60
100-watt mercury lumens a watt, making them twice as efficient
vapor lamp while Compact fluorescent lamps as a mercury vapor lamp. A newer pulse-start
using significantly A compact fluorescent lamp (CFL) uses lamp technology is available for metal halide
less energy. about 75 percent less energy, measured in lamps. The pulse-start system can extend
watts, for the same amount of light as an lamp life by half over the standard metal
incandescent bulb. CFLs are directly inter- halide lamp, provide about 8 percent more
changeable with incandescent lamps, so lumens per watt and allow for faster warm-
changing a 60-watt incandescent lamp to a ups and restarts (Sanford, 2004a). Pulse-start
20-watt CFL cuts energy use by one third. metal halide lamps use a different type of bal-
CFLs also last six to 10 times longer than last and are not interchangeable with standard
incandescent light sources (Sanford, 2004a). metal halide lamps.
CFLs can be used outdoors, but should be
covered to protect the lamps from all weather High- and low-pressure sodium lamps
conditions. Low temperatures, both indoors Slightly more efficient than metal halide
and outdoors, may reduce light levels. In lamps are high- and low-pressure sodium
order to reach full output at cooler tempera- lamps. High-pressure sodium lamps
tures, CFLs require a warm-up period. emit about 95 lumens a watt and give off
an orange light. A 100-watt high-pres-
sure sodium lamp can provide 2.5 times
Factors affecting lamp life more light than a 100-watt mercury vapor
Several factors can shorten the life of a lamp. These include: lamp while using significantly less energy.
• Level of manure gases High-pressure sodium lamps are often
• Humidity used for mixed outdoor and indoor light-
• Dust ing applications. Low-pressure sodium
• Frequent switching on and off lamps are the most efficient HID light
source, but produce a poor color of light.
Page 8 ATTRA Dairy Farm Energy Ef f iciency
9. Low-pressure sodium lamps are often used for fresh air that is cooler
outdoor security lighting. and drier into the
barn, mixes and circu-
Lighting ef f iciency measures lates it, and exhausts
and dilutes moisture,
Replacing inefficient light sources with an
dust, manure gases
appropriate and higher-efficiency light can and odors, and air-
result in better task lighting with energy sav- borne contaminates.
ings that continue over the life of the lamp.
Energy conservation opportunities involve Cows that are exposed
changing incandescent lamps to compact to fresh air are less
fluorescents, upgrading to smaller diame- likely to develop heat
ter and more efficient fluorescent lamps and stress, respiratory ail-
upgrading to HID lighting. Since lighting ments, mastitis, repro-
fixtures distribute light in different patterns, ductive problems and
the barn layout and use should be considered other diseases that
in any lighting decision. could decrease milk
production. Many
Energy savings can be achieved by using dairy producers are
simple and inexpensive technologies that realizing the inher-
go beyond lamp replacement. Some tech- ent benefits of a grass-
nologies incorporate programmable logic ba sed produc t ion Circulation fansAndy improve air movment inside a
barn. Photo by
help
Pressman.
controllers and other computer-based system. Grass-based
control systems and include timers, dusk- dairies utilize an ecological approach to
to-dawn photo controllers, half-night health care by relying on natural immunity
controllers and motion detectors. New and that comes with pasture access. For more
more efficient technologies are continually information on grass-based dairying, see
being developed. the ATTRA publication Dairy Production
on Pasture: An Introduction to Grass-Based
Long-day lighting and Seasonal Dairying. According to experts,
Long-day lighting is a new development for heat stress in dairy cows begins when sur-
dairy farms that involves increasing milk pro- rounding temperatures exceed 65 degrees
duction by extending the day length with arti- and the relative humidity is 40 percent or
ficial light. According to researchers, dairy cows higher (Ludington et al., 2004). Maintain-
are day-length sensitive and can be stimulated ing a healthy atmosphere by controlling
to increase milk production by providing 16 mold, spores, dust and other irritants also helps
reduce the chances of milk contamination and
to 18 hours of uninterrupted lighting followed
lowers health risks to the farmers. Good venti-
by 6 to 8 hours of darkness (Sanford, 2004a).
lation also reduces building deterioration due
By implementing an efficient long-day lighting
to excess moisture, which can cause rot, mil-
system, milk production can be increased by
dew and electrical problems.
5 to 16 percent.
Types of ventilation
Ventilation
There are two types of ventilation: natural
Proper ventilation is needed in dairy barns and mechanical. Natural ventilation uses
throughout the year to help maintain animal the least amount of energy and requires
health and productivity, the barn’s structural the exchange of air, the ability to control
integrity, milk quality and a comfortable ventilation rates, flexibility to provide the
work environment for the laborers. The air cows a comfortable environment through-
inside a barn becomes warm and humid as out the year and good barn construction
cows continuously produce heat and mois- (Wood Gay, 2002). Barns that are in the
ture. An efficient ventilation system brings path of prevailing winds and designed with
www.attra.ncat.org ATTRA Page 9
10. adjustable side and end walls can take advan- Circulation fans
tage of breezes and thermal buoyancy and Circulation fans are mounted inside build-
minimize unexpected air exchanges.
ings to help improve air movement and to
Mechanically ventilated barns require air reduce dead air spots. There are different
inlets and exhaust fans opposite one another. types of circulation fans, all of which have
Exhaust fans are powered by an electric propeller blades attached directly to a motor
motor and contain hoods, protective screens or to a motor-and-belt drive system.
and louvers or shutters. Each fan targets a
Two common types of circulator fans used
certain area to provide uniform control of
in dairy housing systems are box fans and
moisture and gases (Peterson, 2008). Ven-
tilation fans used in livestock buildings are high-volume low-speed fans (HVLS). Box-
typically axial flow fans, which are designed type fans generally operate at moderate to
to let air pass straight through the fan par- high levels of efficiency, depending on the
allel to the fan blade drive shaft (Arnold fan diameter, with the larger diameters being
and Veenhuizen, 1994). Traditional ventila- more efficient (Sanford, 2004d).
tion systems are designed with air inlets and HVLS fans are large-diameter circulation
exhaust fans placed on opposite ends of a fans with diameters ranging from 8 to 24
A
properly building, whereas air inlets and exhaust fans feet. One 24-foot HVLS fan can move the
designed in a cross-ventilation system are located on same amount of air as six 48-inch high-speed
and sized opposite sides of a building. box fans and can save up to 3.3 kilowatts
ventilation fan in an hour of operation (Sanford, 2004d).
system should
Fan selection HVLS fans save energy by replacing exist-
A properly designed and sized ventilation ing circulation fans that are not efficient.
provide the required In addition, HVLS fans tend to be quiet,
fan system should provide the required
amounts of amounts of ventilation needed to maintain reduce moisture in buildings and reduce fly
ventilation needed a comfortable environment for the cows and bird populations in barns.
to maintain a and the laborers during each season. The
comfortable blade size and shape, fan speed in terms of Fan ratings
environment for the revolutions per minute (rpm), motor horse- The Air Movement and Control Associa-
power and housing design determine how tion International (AMCA) is an indepen-
cows and the laborers
much air a fan can move. This is known as dent testing laboratory that rates fans on
during each season. fan capacity and is measured cubic feet per their ability to move air. Fans that meet cer-
minute (cfm). The size of ventilation system tain AMCA or other reliable testing perfor-
needed depends on its capacity to remove mance criteria receive a certified rating seal
excess moisture during the milder and of approval. Th is rating can be helpful to
colder months of the year while forcing cool select the proper fan for an intended use. For
air through the building during the sum- more information on the AMCA, visit their
mer to reduce animal heat stress. Exhaust Web site at www.amca.org. The Bioenviron-
fans range in size from 5 inches in diameter mental and Structural System (BESS) Labo-
to 72 inches. Exhaust fan motors may be as ratory provides research, product testing and
small as 1/20 horsepower and may exceed education on agricultural fans. Performance
more than 50 horsepower (NFEC). test results are available on their Web site at
Static pressure is the difference in pressure www.bess.uiuc.edu.
between inside and outside of a building,
ventilation fan or air inlet (Ludington et Ventilation control systems
al., 2004). It is measured in inches of water The use of thermostats to control ventila-
or inches of mercury. The static pressure tion systems reduces energy consumption by
of an efficient exhaust fan should be having the fans operate only when needed.
between 0.05 and .125 inches of water and Properly located thermostats should accu-
is measured with a manometer. rately reflect the average temperature inside
Page 10 ATTRA Dairy Farm Energy Ef f iciency
11. the building. Mounting a thermostat at least
10 feet from a fan and at least 1 foot below
the ceiling reduces the thermostat’s exposure
to adverse factors, such as sunlight and air
intake drafts, that can alter the thermo-
stat’s temperature reading (Wells, 1990). All
control systems should be located so they
cannot be bumped by the livestock.
Timer controls and moisture sensors can also
be used to control ventilation rates. How-
ever, the use of these control devices may not
save energy. Timer controls cycle motors on
and off to meet set ventilation rates and may
use more energy to start the motors from the
off mode. Timer controls also create larger
temperature swings. Furthermore, moisture
sensors have been reported not to work
adequately in barns (Wells, 1990). NCAT Energy Engineer Dave Ryan performs a farm energy audit. Photo by
Andy Pressman.
Ventilation system maintenance
Dairy ventilation systems require routine Farm energy audits
maintenance to keep fans operating at high A farm energy audit is a tool to help agri-
performance levels. Poorly maintained fans cultural producers conserve energy and save
and obstruction to air inlets and fan outlets money by implementing energy efficient
can reduce fan efficiency by as much as 40 equipment. The audit collects and analyzes
to 50 percent. Cleaning fan parts, lubricating information on farm energy consumption
bearings and other moving parts, checking and its associated costs, and then makes
belt tension and alignment and removing recommendations on ways to reduce them.
any obstructions will keep fans performing Farm energy audits also explore ways to
at peak efficiency and reduce energy costs. capture renewable energy resources that
Long-term efficiency can be improved by are available on a farm. Dairy operations
repairing or replacing bent, damaged or are often good candidates for farm energy
misaligned fan blades, shutters, guards audits as there are significant opportunities
and other fan parts. An air velocity meter for dairies to save energy and money through
can be used to detect reductions in the conservation and efficiency measures.
performance of the ventilation system. Farm energy audits can be conducted by a
Control systems should be cleaned regularly professional or through do-it-yourself energy
and thermostats should be checked yearly efficiency calculators. For more information
for accuracy by comparing their readings on energy audits and farm energy calculators,
against a mercury thermometer. see the ATTRA publication Farm Energy
Calculators:Tools for Saving Money on the Farm.
Factors that affect the ef f iciency of a
livestock ventilation system Financial incentives
1. Ventilation system design There are several federal, state and nonprofit
2. Fan blade type and design grant and incentive programs for imple-
3. Ef f iciency of electric motors to power fans
menting energy efficiency and renewable
energy systems on dairy farms. For informa-
4. Use of fan control system
tion on state and federal incentives, see the
5. Routine maintenance and cleaning Database of State Incentives for Renewables
and Efficiency (DSIRE) at www.dsireusa.org.
www.attra.ncat.org ATTRA Page 11
12. Saving energy at The Lands at Hillside Farms
The Lands at Hillside Farms is a historic dairy
farm and nonprofit sustainable agriculture edu-
cation center located in Shavertown, Penn. The
farm’s grass-based milking herd of around 60
cows is made up of Jerseys, Holsteins and Jersey-
Holstein crosses. After the cows are milked in a
tie-stall barn, the raw milk is collected and pro-
cessed on the farm. In 2007, the National Center
for Appropriate Technology (NCAT) conducted a
farm energy audit at The Lands at Hillside Farms.
The study found that most of the energy on the
farm is used for pasteurizing and homogenizing
raw milk, making dairy products and refrigeration.
NCAT also identified several energy conservation
opportunities for harvesting milk in the dairy barn.
Recommended energy conservation measures with
a short payback period included replacing incan-
descent lamps with compact fluorescent lamps,
insulating the water heater with a blanket, insu-
lating hot water piping with foam insulation and
using water from the precooler as drinking water
for the cows. These energy conservation measures
would save about $300 a year in energy costs. Install-
ing a variable-speed drive to control the vacuum
pump and milk flow through the plate cooler was
not recommended because of the high implemen-
The Lands at Hillside Farms, Shavertown, Penn. Photo by Andy Pressman. tation costs in relation to the size of the herd.
For information on grant and loan guaran- harvesting, milk cooling and storing, ven-
tees to assist agriculture producers with pur- tilation and lighting. An energy audit can
chasing renewable energy technologies and be a valuable tool to a dairy farmer who
energy efficiency improvements, see the is trying to understand how energy is
U. S. Department of Agriculture’s Rural currently being used on the farm and
Development Business and Cooperative identify cost-saving opportunities.
Programs Web site at www.rurdev.usda.gov/
rbs/farmbill.
Acknowledgments
Summary Special thanks to Joseph Schultz, with Focus on
There are many opportunities for dairy Energy and GDS Associates, Inc., and John Frey,
farms to reduce their electrical energy executive director of the Center for Dairy Excel-
consumption. Dairy farms can become lence, for providing technical review of this publi-
more energy efficient by upgrading older cation. Thanks also to Margo Hale and Dave Ryan
equipment, installing new technologies and of NCAT for providing input for the equipment
changing management practices for milk and water heating sections of this publication.
Page 12 ATTRA Dairy Farm Energy Ef f iciency
13. References
Arnold, Glen and Michael Veenhuizen. 1994. Livestock Publication (A3784-7). Madison, Wisconsin:
Housing Ventilation Fan Selection. Ohio State Cooper- University of Wisconsin.
ative Extension Factsheet. Columbus, Ohio: The Ohio Sanford, Scott. 2004d. Ventilation and Cooling
State University. Systems for Animal Housing. University of Wisconsin -
Hiatt, Richard. 2008. Agricultural Lighting. Cooperative Extension Publication (A3784-6).
Presentation at the Farm Energy Audit Training for Madison, WI: University of Wisconsin.
Field Advisors workshop. Augusta, ME. January. U.S. Department of Agriculture. 2000. 7CFR Part 205
Ludington, David, Eric Johnson, James Kowalski, of the National Organic Program. Washington, D.C.:
Anne Magem and Richard Peterson. 2004. Dairy Farm USDA Agriculture Marketing Service.
Energy Efficiency Guide. Ithaca, NY: DLTech, Inc. U.S. Department of Energy. 2009. “Energy Savers:
Milking Machine Manufactures Council (MMMC). Lighting.” Washington, D.C.: Energy Efficiency &
1993. Maximizing the Milk Harvest. Chicago, IL: Renewable Energy. www.energysavers.gov.
Equipment Manufactures Institute. Wells, Grant. 1990. Dairy Barn Ventilation: Exhaust
National Food and Energy Council (NFEC). Date Fan Systems. University of Vermont Extension
Publication (BR-869). Burlington, VT: University of
Unknown. Controlled Livestock Ventilation. Ag
Vermont Extension.
technical Brief. Columbia, MO: National Food and
Energy Council. Wood Gay, Susan. 2002. Natural Ventilation for
Freestall Dairy Barns. Virginia Cooperative Extension
National Organic Program. National List of Allowed Publication. Blacksburg, VA: Virginia Tech.
and Prohibited Substances. Sections 205.600-606.
www.ams.usda.gov/AMSv1.0/NOP.
Further resources
Peterson, Richard. 2008. Energy Management
for Dairy Farms. Presentation at the Farm Energy Web sites
Audit Training for Field Advisors workshop. Center for Ecological Technology
Augusta, ME. January. www.cetonline.org
Organization provides publications and links on energy
Sanford, Scott. 2003a. Heating Water on Dairy Farms.
efficient and renewable energy technologies.
University of Wisconsin – Cooperative Extension
Publication (A3784-2). Madison, Wisconsin: Pennsylvania Center for Dairy Excellence
University of Wisconsin. www.centerfordairyexcellence.org
Organization dedicated to improving the profitability of
Sanford, Scott. 2003b. Well Water Precoolers. the dairy industry. Web site provides resources and tools
University of Wisconsin - Cooperative Extension for improving profitability through energy efficiency.
Publication (A3784-3). Madison, Wisconsin:
University of Wisconsin. DLTech, Inc. Dairy Farm Energy
www.dairyfarmenergy.com
Sanford, Scott. 2004a. Energy Conservation in Information about dairy mechanical systems, their
Agriculture: Energy Efficiency Agricultural Lighting. functions and efficiencies.
University of Wisconsin - Cooperative Extension
Publication (A3784-14). Madison, Wisconsin: EnSave
University of Wisconsin. www.ensave.com
This commercial site offers technical papers on vari-
Sanford, Scott. 2004b. Refrigeration Systems. able speed drives for dairies, efficient fans and lighting
University of Wisconsin - Cooperative Extension and other farm energy topics.
Publication (A3784-4). Madison, Wisconsin:
Milking Machine Manufactures Council
University of Wisconsin.
www.partsdeptonline.com/maximizing_the_milk_
Sanford, Scott. 2004c. Variable Speed Milk Pumps. harvest.htm
University of Wisconsin - Cooperative Extension Part of the Equipment Manufactures Institute trade
www.attra.ncat.org ATTRA Page 13
14. association that provides resources, research funding Wisconsin’s Focus on Energy
information and educational materials that benefit dairy www.focusonenergy.com
farmers. Link is to Maximizing the Milk Harvest – Wisconsin-based program providing information,
A Guide for Milking Systems & Procedures. resources and financial incentives to help implement
Rural Electricity Resource Council energy efficient and renewable energy projects. Agricul-
www.rerc.org tural & Rural Business Programs provides information
National clearinghouse and technical support on energy efficiency for agricultural producers.
provider on energy efficiency with an emphasis Innovation Center for U.S. Dairy
on rural applications. www.USDairy.com
The Dairy Practices Council Industry-wide consortium working to address barriers
www.dairypc.org and opportunities in the dairy industry by promoting
Nonprofit organization that publishes approved sustainable business practices. Web site contains infor-
educational guidelines for the dairy industry. mation on energy savings opportunities for dairy farms.
Notes
Page 14 ATTRA Dairy Farm Energy Ef f iciency