|
Cooperative Extension
Service
The University of Georgia College of Agricultural and
Environmental Sciences
Fences for Horses
Dr. John W. Worley, Biological and Agricultural
Engineering
Dr. Gary Heusner, Animal and Dairy Science
Purposes of a Fence
Height of
the Fence
Selecting the Fence
Fencing Materials
Gates
Construction
Maintenance
References
Pastoral
scenes of life in the country often include beautiful
horses running with tails raised high or peacefully
grazing in lush green pastures surrounded by a freshly
painted fence. While these fences are truly beautiful,
they also serve practical purposes. Fences are necessary
to safely confine horses yet provide them with the
opportunity to exercise and graze. Because of the
natural flight response of horses, they tend to injure
themselves in fences more than most other livestock. In
addition, many horses are extremely valuable and that
justifies the extra cost of building a fence that is
safe, strong and attractive. Painted rail fences are not
only beautiful to humans, they are highly visible to
horses. They appear to a horse as a solid barrier that
they are less likely to challenge or run into. When a
horse does contact a rail fence, it is less likely to
get a hoof hung in it or cut itself on sharp wire ends
as might be the case with many standard farm wire
fences. When selecting a fence, consider all three of
these important functions -- utility (keeping the horses
in), safety and aesthetics. How much importance is
placed on each function depends on the owner's budget,
the value of the animals, and your priorities. A number
of alternatives are available for consideration.
The
heights of fences used for other livestock do not
necessarily apply to horse fences. Horses are more
athletic and more likely to jump a fence than to go
through or under it when spooked or herded. The minimum
recommended height for perimeter pasture fences for
horses is 5 feet (60 inches). This height will deter
most horses from attempting to jump and will also reduce
the temptation for people to reach over the fence to pet
or feed horses. A 5-foot minimum height fence is both
horse-safe and people-safe.
For
paddocks (small pastures or turn-out areas fewer than 2
acres in size), corrals and stallion pens, a general
rule is that the top of the fence should be at eye level
with the horse's head in a natural upright position.
This is usually 4 to 6 inches above the horse's withers.
This height will discourage fighting over the fence and
help prevent horses from leaning over the fence,
although the sure way to eliminate leaning and rubbing
on any fence is with an offset electric fence wire.
Fences
that divide pastures can be 41/2
feet (54 inches) high. The bottom of the fence should be
6 to 8 inches off the ground. This is especially
important with wire mesh fences, since horses are less
likely to paw at the fence and more likely to keep the
fence line grazed. In addition, weed growth is easier to
control along the fence line by either application of
herbicides or use of a weed-eater if this clearance is
left below the bottom of the fence. It also adds 6
inches of height to the fence at no extra cost.
The kinds
of fences commonly used for horses include rail (plank
or PVC), various forms of galvanized and vinyl coated
wire, electric and combinations of these. Whatever the
fence is made of, it needs to be highly visible,
resistant to damage by horses, durable, attractive and
safe for contact by horses.
Rail or Plank Fences
Rail
(also called "plank" or "board") fences are popular on
horse farms because they are attractive, highly visible
and relatively safe. This category includes fences made
from treated and/or painted wooden planks nailed or
screwed to posts, split rails with rounded ends that
slide into holes in posts, PVC plastic boards, and
wooden boards coated with vinyl. If a horse runs into a
rail or plank fence, the fence is not likely to cause
physical harm unless the collision is hard enough to
break the rail. A horse is also less likely to get a
hoof hung in a rail fence. Probably the only
disadvantage to a rail fence is the cost of construction
and maintenance. Rail or plank fences are probably the
most expensive fences to build, and maintenance expense
can be significant.
Wooden
planks are usually either oak or treated pine. Pine
boards should be treated with CCA (chromated copper
arsenate) at a minimum of 0.25 lb/ft3 (0.4 or
higher if wood contacts the soil). Water-based paint or
a black asphalt or coal tar based paint can be used to
protect the wood and add to the beauty of the fence.
Treatment of the wood also discourages chewing of the
fence but may not be sufficient to prevent chewing when
horses are stressed or confined in a small space.
PVC
plastic fences (Figure 1) are generally more expensive
than wood. They are, however, becoming very popular
because of their attractiveness and the fact that they
do not require painting, since they are the same color
throughout the material. If a PVC board breaks, it does
not present a jagged end as sometimes happens with
natural wood planks. White PVC rail fences do, however,
require periodic washing with mildew removing agents,
especially in the humid south. Vinyl coated wood is
simply wood dipped in a vinyl coating. This product,
like PVC, does not require painting but it does require
washing to maintain appearance. In addition, the wood
inside the vinyl coating can warp with age just like any
other board. Treated wood is strong and durable and
resists rotting. It has a natural, attractive look but
may lack the eye appeal of a painted fence. Usually
either 1 x 6 or 2 x 6 boards are used for the rails.
Rails made of 1 x 6 boards are less expensive but tend
to warp more and are not as strong as 2 x 6 rails. Wood
fencing is often painted with a mixture of asphalt or
coal-tar mixed with oils. This material is relatively
inexpensive and long-lasting. Exterior water-based
paints also provide good protection against weather and
are available in a wide variety of colors.]
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Figure 1. A PVC rail fence makes an attractive
picture. |
High-Tensile Polymer Fences
One type
of fence has the appearance of a rail fence but is
actually a wire fence called a "high-tensile poly-mer
fence." The "rails" consist of vinyl plastic 4 to 6
inches wide with two to three high-tensile steel wires
encased (Figure 2). These fences are less expensive than
rail fences, are very strong and have a nice appearance
and good visibility much like a rail fence. They are,
however, wire fences that must be tightened periodically
to maintain the proper tension. (This is true of any
high-tensile fence.) Some high-tensile polymer wires can
be electrified for added security, but a special coating
must be used to allow electricity to flow; you'll need
to specify electrifying the fence when it's purchased.
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Figure 2. A high-tensile fence with top
"rail." Tensioning devices are covered to
protect horses from cuts and to allow the
fence to be "dropped" quickly if a horse
becomes entangled.
|
Rubber Fences
Rubber
belting or rubber strips from old tires and conveyor
belts have been used for horse fencing. These have the
obvious appeal of being soft and yielding, preventing
injury to horses, but they require a good deal of
maintenance to keep them tight, since they continually
sag with time, especially in the heat of summer. Horses
do tend to nibble on the rubber and, with some products
made with nylon threads, this has caused colic and/or
impaction.
Mesh Wire Fences
Mesh wire
fences are strong, durable and considered one of the
safest fences for horses. They are less expensive than
most rail fences but more expensive than conventional
farm woven fences with 4- to 6-inch openings used for
cattle and other livestock. The openings in these fences
are small enough to prevent hooves being caught in them.
They also have no exposed sharp wire ends to cut the
animal's skin.
Two types
of mesh wire are the diamond mesh (Figure 3a), which
uses two wires twisted together in a diamond formation
with 2-inch x 4-inch openings, and the square knot mesh
(Figure 3b), which has single horizontal lines with the
wire spaced 2 to 4 inches apart. This fencing should
have a minimum of 121/2
gauge wire unless it is high-tensile steel. A 14-gauge
high-tensile steel wire will provide more strength than
a 121/2
gauge standard steel wire. A galvanized welded wire
fabric with 2 x 4-inch openings is sometimes used
because of its low price, but the joints will not hold
up under field conditions and it is not recommended for
horse fencing.
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Figure 3. a. A detail of diamond mesh fence. b.
Stiff-stay, square-knot fence. |
Electric Fences
Several
materials are used to construct electric fences. They
include aluminum wire, high-tensile smooth steel wire,
high-tensile steel wire coated with vinyl, and steel
wires woven into vinyl tape. Some tapes are considered
permanent fencing. They are highly visible to horses
since they are about 1½ inches wide. One product
contains 10 stainless steel wires 0.016 inch in diameter
with polyethylene yarn woven between the wires. These
products are stiff and difficult to bend, but these
qualities are needed to provide strength and durability
to the fence. Aluminum wire and some vinyl tapes and
ropes with smaller, more flexible wires are also
available, but they are designed primarily for temporary
fencing. They provide high visibility and their
flexibility makes them easier to move from one location
to another, but they do not provide the strength needed
for long-term use. Electric fences are very effective in
controlling horses once the horse has encountered the
fence, but good visibility is extremely important and is
not a characteristic of electric fences built with
smooth steel wire. To increase visibility, one or more
strands of vinyl coated wire or high-tensile vinyl tape
should be included in the fence (Figure 4).
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Figure 4. A vinyl-coated wire adds significantly
to the visibility of a smooth-wire electric
fence. Safety is enhanced when visibility is
improved. |
High-tensile steel fences allow long stretches of fence
to be constructed between two strong corner or brace
post assemblies. The key to making these fences work is
to put more effort and investment into the brace post
assemblies and less in intermediate supports. Between
brace posts, the fence can be sup-ported by intermediate
posts made of fiberglass or of wood or steel with
insulators. Space these posts about 25 feet apart. Short
fiberglass or wooden stays can also be placed between
the posts to increase visibility. The main purpose of
the intermediate supports is to maintain proper spacing
of the wires. Tension in the wire is maintained by
permanent in-line stretchers and tension springs. Best
results are achieved when tensioners are used in
conjunction with springs. Wires must be attached to any
intermediate posts in such a way that they can move
laterally and be retensioned. Retension wires at least
once a year, especially in the spring when winter
conditions have contracted and stressed the wire and
before summer heat will cause it to expand. Wire should
be constructed of high-tensile steel and should be at
least 121/2
gauge in size. Commonly, one to five strands of
high-tensile wire are used in a fence. For a perimeter
fence, use four to five strands; fewer strands may be
used for temporary cross-fences. For horses, at least
one strand of these fences should be more highly visible
material, as discussed earlier (Figure 4).
For best
results, electrify alternate strands of wire (for
example, top, middle and bottom of a five-strand fence)
and ground the other wires. This provides a path for
electricity to return to the source without depending on
the earth. It also improves the performance of the
fence, especially in very dry conditions. One added
advantage to electric fencing is that it does provide
some protection from predators such as dogs, which
sometimes like to chase horses. Once a dog has
experienced an electric fence, he will not likely get
close to it again.
If a
properly designed fence charger (known as a "controller"
or "energizer") is used, an electric fence is quite safe
for use around animals as well as humans. While high
voltages are used to shock the animals and cause them to
avoid touching the wires again, the extremely short
duration of the electric charge prevents damage to
animals or humans. An electric fence does require some
maintenance. Vegetation growing up around the wires
reduces effectiveness. Some contact with vegetation will
be overcome by a good low-impedance fence controller,
but a large amount of contact will eliminate its
effectiveness as the charge is shorted to the earth
through the vegetation. Managers must also be diligent
to make sure that lightning or other power failures have
not affected fence power.
Proper
grounding is another important consideration.
Instructions are usually included with the fence
charger, but the grounding system usually consists of a
number of grounding rods driven into the ground spaced
at least 10 feet apart and tied together with copper
wire. It should be separate from any other electrical
grounding systems on the farm. If alternative fence
wires are charged and grounded, the fence will be
effective even in times when the ground is too dry to
conduct electricity. The top wire should be hot to
prevent reaching over the fence, and it is usually best
to ground the bottom wire to reduce the likelihood of
the hot wires being grounded out by vegetation.
Combinations of Fence Types
A strand
of electric fence wire can be added to a rail or wire
mesh fence to increase the effectiveness and durability
of the fence. If horses are damaging the fence by
reaching over it to graze, a strand of electric fence
across the top should prevent this. Place the wire on
insulators on the opposite side of the post from the
mesh wire or rails to prevent short circuiting the
fence. A strategically placed strand can also help by
discouraging predators. A mesh wire fence can be
improved by adding one rail at the top (Figure 5). The
rail increases the visibility of the fence and helps
deter horses from stretching the wires by resting or
pushing on the top, but horses will still push and
sometimes chew on the wood unless the top rail is
accompanied by an electric fence wire mounted on the
other side of the posts. One "rail" of high-tensile
polymer fencing (Figure 2), or even a polymer coated
wire (Figure 4), at the top of a wire fence will also
improve the visibility of the fence and is often more
compatible with the post spacing used for the wire fence
as compared to using a wooden top rail.
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Figure 5. A top rail added to a square mesh
fence prevents horses from stretching the fence
wires. An electric fence wire installed on the
opposite side of the post will prevent horses
from rubbing on or chewing the board. |
Comparison of Fence Types
As
previously stated, the type of fence chosen depends on
the priorities of the owner. Table 1 shows some general
factors to consider when selecting a fence.
|
Table 1. Comparison
of Common Fences |
|
Types |
Comparative
Cost Index1
(Material Only) |
Approximate
Life2
(Humid Climate) - yrs |
Upkeep |
|
4-Rail
(Posts spaced 8 feet) |
|
1" x 6" Treated
Boards |
200 |
10-20 |
Medium |
|
2" x 6" Treated
Boards |
350 |
10-20 |
Medium |
|
PVC Rails |
500-600 |
20 |
Low |
|
High-Tensile Polymer Coated |
|
5-inch rail width |
330 |
33 |
Medium |
|
Mesh Wire
(Diamond or 2" x 4" rectangle) |
|
121/2
gauge |
150 |
38 |
Low |
|
High-Tensile Electric3 - 121/2
gauge |
|
4 strands |
20 |
25 |
Medium |
|
1 strand |
7 |
25 |
High |
|
Reflective
Tape or Rope (Electric) |
|
1/2-inch
1-strand (temporary) |
11 |
25 |
Medium |
|
11/2-inch
Heavy Duty 2-strand
(permanent) |
33 |
25 |
Medium |
|
1Cost
index figures are to show relative cost, not
actual costs. For example, fence with an index
figure 25 costs about twice as much per foot as
a fence with an index figure of 12.
2Fence life based on combination of
post and wire life expectancy.
3Costs of electric controller not
included. |
Wire
Fencing
wire is usually covered with zinc, commonly called
"galvanizing," to protect it from rusting. The length of
time before wire begins to rust depends on the weather
but also on the thickness of the zinc coating. More zinc
means more years of service before rusting starts. Fence
manufacturers and the American Society for Testing
Materials have established "classes" of zinc coatings
for fence wire. Class 1 has the lightest coating of zinc
and Class 3 has the heaviest (two to three times as
much, depending on the wire size). The expected life of
a fence depends on many factors, but Class 3 galvanizing
can easily add 5 to 10 years of life to fence wire in a
humid climate like Georgia's. Make sure when you compare
the cost of fence materials that you compare the same
class of galvanizing (preferably Class 3). Some
suppliers carry only Class 1 galvanizing in order to
have a lower price, but if consumers demand a higher
quality product, dealers will certainly supply that
need.
Some wire
is coated with vinyl in addition to zinc. The primary
purpose of the vinyl is to increase visibility and
improve the attractiveness of the fence, but it also
helps protect the wire from deterioration. Some mesh
wire products are available on the market with welded
joints instead of twisted wire joints. These products
are significantly less expensive than standard fencing
products, but the joints will not hold up when tested by
time and the inevitable stress that will be placed on
them in a fence. The best investment is to buy a product
designed to do the job over the long term.
Fasteners
Selecting
the appropriate fastener to attach fencing to posts is
an important step in building a strong, durable fence.
All fasteners should be galvanized (preferably Class 3).
Nails should have grooves on the shank to help hold the
nail in place. Galvanized screws are another option for
fastening boards to fences. Good quality insulators are
essential on electric fences for longevity and to
prevent bleeding off of electrical charge through the
posts.
For wire
mesh fences, staple pull-out is a common problem when
you use softwood posts. To avoid this problem, use 13/4-inch
or 2-inch long, 8- or 9-gauge, hot-dipped, galvanized
staples with cut points and barbs. When properly
installed, a 13/4-inch
long staple has approximately twice the holding power of
a 11/2-inch staple in a softwood
post. If you use hardwood posts, you can use shorter
staples because they don't pull out of hardwood as
easily.
Fence Posts
Wooden posts are plentiful in Georgia. Some
major advantages of wood posts are strength as well as
resistance to bending, misalignment and withdrawal.
Build permanent fences with decay-resistant fence posts.
The most common wooden posts are pine pressure treated
with CCA (chromated copper arsenate). These posts have a
greenish color, last longer and are harder than posts
treated with older treatments such as creosote and Penta
(penta-chloro-phenol). This quality of hardness tends to
reduce staple or nail pull-out.
Wood
posts from 51/2 to 81/2
feet long and from 21/2 to 8
inches or larger diameter are readily avail-able. The
larger the top diameter, the stronger the post. Line
posts can be as small as 2½ inches, but larger ones will
make the fence stronger and more durable. Corner and
gate posts should have a top diameter of at least 8
inches. Brace posts should be 5 inches or more in
diameter. It is important to distinguish between the
need for posts in a rail or plank fence versus in a wire
fence. In a wire fence, most of the load is carried by
the corner or brace assemblies. The intermediate or line
posts mainly keep the wire spaced properly and can
therefore be much smaller. In a rail fence, each section
of the fence must be equally strong, requiring the same
size posts throughout the fence.
When
buying fence posts, make sure they have been properly
treated for contact with the soil. Most treated lumber
bought in builders' supply stores (including 4-by-4s
often used as posts) is treated at 0.25 lb of CCA per
cubic foot of lumber. This level of treatment is
designed for lumber exposed to the weather but not in
contact with the soil. It will not protect against
termites or the severe conditions of soil contact. Sawn
lumber should be treated at 0.5 to 0.6 lb/ft3
of CCA if it is to touch the earth. Fence posts can be
treated at 0.4 lb/ft3. Many people are
tempted to use "landscape timbers" for fence posts
because they are extremely cheap at times due to
over-supply. These timbers are a by-product of the
plywood industry. They are what is left over after the
veneer has been peeled off a large log. The danger in
using these for fence posts is that they are not treated
for ground contact, since they are not designed to
support a load. Usually, they are not labeled so it is
unclear what, if any, treatment has been applied.
Steel posts have four major advantages over
wooden posts when used for wire fences. They cost less,
weigh less, can be driven into the ground rather easily,
and are fire-proof. They also help ground the fence,
minimizing damage by lightning. Steel posts vary from 5
to 8 feet long. A wide variety of steel posts are
available with widely varying prices and quality, so
carefully compare post specifications to be sure you are
comparing equal quality. For permanent fencing, steel
posts should be galvanized. If you use Class 3
galvanized wire, the wire will usually outlast the posts
unless the posts are galvanized.
Steel
posts do not have as much strength against bending as
wood posts. Wooden line posts can be placed every 50 to
75 feet to help keep steel posts from bending and
improve fence stability.
Various
kinds of posts are available for electric fence line
posts as the requirements for strength are much less
than for non-electric fences. Posts are available in
wood, plastic, steel and fiberglass. Wood and steel
posts require insulators to prevent short-circuiting the
fence through the posts. High-density fiberglass posts
(commonly known as "sucker rod," since they were
originally by-products of the oil industry) make
excellent electric fence posts. They are usually gray or
white in color, are very strong and durable, and are
nonconducting so insulators are not required.
All posts
must be long enough for the fence height and depth of
setting. Add together the height of the top wire above
the ground, the depth of the post in the ground, and 6
extra inches to get the desired length.
Electric Fence Controllers
Most
people will agree that touching an electric fence is a
very unpleasant experience. The experience for horses is
no different. When animals come in contact with an
electric fence, the shock they receive affects their
nervous system. The severity of the shock depends on the
voltage and amperage (current) as well as the duration
of the shock and the sensitivity of the animal. It takes
at least 700 volts to effectively control short-haired
breeds of animals such as horses. The controller that
delivers this shock is the heart of any electric fence
and should be selected carefully.
Controllers are safe yet effective because of the short
duration of the charge. The charge is powerful but does
not last long enough to damage the heart or to cause
electrical burns. Modern low-impedance controllers have
the capacity to power long distances of multi-wire
fences and are not affected as much as earlier
controllers by some contact with grass or other
vegetation. Some chargers will actually retard
vegetative growth by burning any vegetation that comes
in contact with them.
Controllers are available in battery powered models as
well as 120-volt AC models. When 120-volt power is
available, the 120-volt models have an obvious advantage
since you don't have to buy or recharge batteries. Cost
of operation is minimal (usually less than $1 per month)
for these units. If commercial power is not available
near the fence to be energized, battery-powered units
are available to fill this need. These units operate on
12, 24 or 36 volts (one, two or three 12-volt batteries
in series). The batteries must be recharged every two to
six weeks, depending on the system and amount of use.
Deep cycle, marine and RV type batteries are best suited
for battery-operated controllers. "Deep cycle" means
that the battery is designed to be discharged almost
completely before being recharged. Automobile batteries
are designed to be almost fully charged at all times and
so will not last as long as deep cycle batteries.
Solar
collectors are also available to recharge the batteries
daily. Solar chargers are usually not as powerful as
120-volt AC chargers, but they do offer an attractive
alternative for remote locations where livestock
pressure (the tendency for animals to test the fence) is
low.
It is
important to match the capacity of the con-troller to
the fence you want to charge. Most manufacturers
indicate the strength of the unit by the number of miles
it will power, but the standards for these ratings are
not well regulated. Look for a controller that gives the
output voltage delivered at varying loads (measured in
ohms,  ). A
good controller will deliver 1,000 volts at 100
of
resistance. (Lower resistance means a higher load on the
controller.) Avoid controllers that do not provide you
with this information. A good rule of thumb for sizing
controllers is to determine the number of miles of
electrified wire in the fence and add at least 25
percent to offset any power drain caused by vegetation
touching the fence. For example, if you have 4 miles of
five-strand high-tensile wire with three of the strands
electrified, you would need a controller rated for at
least 15 miles (3 wires x 4 miles = 12 miles + 0.25 x 12
= 15 miles).
Check the
charger on a regular schedule and after any lightning
storm to make sure it is still working properly. Fence
testers are available that are designed to check the
voltage on fence wires. A light is also available that
can be hung on a fence wire; it indicates from a
distance whether or not the wire is energized. The
brightness of the light indicates the strength of the
charge.
Horses
tend to congregate around gates, so make sure whatever
gate used is sturdy and safe. Gates should be
aesthetically related to the fence. Steel tubing or pipe
gates are routinely used for horses.
Gates
should be level with the top height of the fence. Gates
into a pasture should be wide enough to allow equipment
-- such as tractors, mowers, fertilizer trucks and
wagons -- to get into the pasture (a minimum of 14 to 16
feet wide). The minimum width for any gate a horse will
be passing through is 4 feet; however, if you foresee
the need for equipment to pass through the gate, make it
at least 8 feet wide. If gates are to open into lanes,
the gate should be the same length as the width of the
lane, or another gate may be added to the lane so the
lane can be closed off when you move or herd horses.
Gates are often hung to swing both ways -- in and out.
Avoid gaps between gates and supporting posts to prevent
horses from getting a hoof caught or foals from getting
their heads caught in the gap. Plans are available from
your county extension office for a gate opener that can
be operated from horseback.
Like most
construction and maintenance jobs around the farm, fence
construction requires proper techniques and common-sense
judgement. Every fencing job presents slightly different
problems. A few basic principles are good starting
points for every fencing job. Here are some to consider.
Establishing the Fence Line
Where a
permanent fence is installed on a property line, locate
property lines exactly. A mistake here can be very
costly. Once this is done and any trees and brush are
removed, you are ready to establish the fence line.
On level
ground, an end post can be installed at each end of the
run and a string or a single strand of wire stretched
between the two posts to establish the line. On rolling
ground, where hills are too high to sight from one
end-post to the next, you can use surveying equipment
(if available) to establish the location of intermediate
points on the line. Alternatively, intermediate sighting
stakes can be driven at the tops of hills. Drive two of
these temporary stakes about 8 to 10 feet apart at the
approximate position where the line will cross the crest
of the hill. If both posts appear to be lined up when
sighted from each end post, they represent a true
midpoint of the line. If not, you can move them back and
forth until they are properly aligned.
If
possible, when building a rail or plank fence, the
length of the fence should be such that all posts are
equally spaced. If the posts are to be spaced every 8
feet, then the length should be an even multiple of 8
feet. Otherwise one section may need to be 5 feet or 3
feet or even 2 feet long, which detracts from the
appearance of the fence.
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Figure 6. Fence post spacing around curves
depends on the sharpness of the curve. |
When a
wire fence must go around a curve, place small stakes
every 16 feet around the smooth curve. Then start
figuring the post hole positions where the curve is
greatest. The sharper the curve, the closer the posts
should be. Select three stakes at a point of maximum
curvature. String a line from the first to the third
stake (Figure 6). Measure the distance from the center
stake to the string and space the posts as given in
Table 2.
|
Table 2.
Fence Post Spacing around Curves |
|
Distance
from Center Stake to String |
Post
Spacing |
|
Inches |
Feet |
|
8 or less |
12 |
|
8 to 14 |
10 |
|
14 to 20 |
8 |
End- and Corner-Post Brace
Assemblies
For any
wire fence, corner-post and end-post assemblies are the
most important structures in the entire fence. They are
the foundation upon which the fence is built. When wire
is first stretched, the pulling force on the corner or
end may be 3,000 pounds. Winter cold can contract the
wire, which increases that force to 4,500 pounds. Design
fences to with-stand forces causes by mowers accidently
running into them, trees falling on them, and animals
running into them. Both corner and end assemblies must
be strong enough to withstand these forces.
Additionally, gates are usually hung on end-post
assemblies, so the assembly should be strong enough to
hold the gate up without sagging.
Figure 7
shows proper construction of a double span H-brace
assembly for wooden anchor posts. A double span assembly
is more than twice as strong as a single span; use it
whenever the fence span will be more than 200 feet long.
A corner post will need a brace assembly for each fence
line leading to it. Post depths shown in Figure 7 are
minimums. Use deeper settings for sand or wet soil. One
often overlooked detail is the length of the horizontal
post between the end post and the brace post. This
should be 2 to 21/2 times as long
as the height of the fence in order to achieve the
proper angle for the diagonal brace wire. It should be
attached to the corner and brace posts with a
3/8-inch
galvanized steel pin to keep it from moving when the
posts move over time.
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Figure 7. Double span H-brace assembly. Post
depths shown are minimum. |
Figure 8
shows the proper way to secure the brace wire. It should
be constructed of 12½ gauge high-tensile wire. The
diagonal wire can be tightened with a wooden twitch as
shown or with a wire tensioner. Tensioners can usually
be purchased with the high-tensile wire. The H-brace is
a bracing system in which each component plays an
important part, so pay attention to details when
constructing these braces.
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Figure 8. Correct procedure for threading
9-gauge smooth wire for diagonal brace.
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When a
fence is more than 650 feet (two rolls of wire) between
corner posts, use braced line post assemblies every 650
feet in the fence line. A braced line assembly is the
same as a single span braced corner except that a second
diagonal brace wire is used to take fence pull in the
opposite direction.
Some
other brace assemblies are not as strong as the H-brace
but they will work in many cases for short pulls and in
favorable soil conditions. One is commonly called a
"dead man" brace (Figure 9). The end post should be
large (10-12" diameter) at
least 4 feet in the ground. The "dead man" is a short
(4-foot) piece of post buried just under the surface
perpendicular to the end post on the loaded side. This
positioning supports the post so when the post tries to
lean, it must push the "dead man" through the soil
sideways.
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Figure 9. A "dead man" brace is an inexpensive
alternative for short fences. |
A second
type of brace is called an "angle brace." (Figure 10)
The keys to making this brace work are (1) making sure
the end post is deep in the ground (about 4 feet), (2)
placing a 1- to 2-square-foot rock or piece of concrete
under the angle brace post, and (3) properly tightening
the tension wire. The tension wire in combination with
the angle post gives this brace its strength. If the
fence starts to sag, tension can be reapplied by
tightening the tension wire.
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Figure 10. An "angle" brace is another low-cost
alternative to the H-brace. The tensioning of
the wire, the depth of the main post, and the
concrete pad are critical to the strength of
this brace. |
Fence Post Setting
Steel
posts are almost always hand or power driven. Wood posts
are frequently driven with power driving equipment
(Figure 11). Driving posts is faster than digging holes
and tamping (packing) soil around posts. Driving also
results in a stronger foundation for the post. Drive
posts with the small end down. The results may look
strange (large end up), but the resulting fence will be
much stronger and damage to the posts during driving is
minimized. Corner posts can be driven as well, but it is
some-times necessary and always advisable to drill a
pilot hole about 3 or 4 inches smaller than the post
before driving. The pilot hole reduces driving
resistance and gives more control over the direction of
lean of the post. (Drive end posts at a slight angle
away from the direction of pull so they will be straight
when tensioned.)
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Figure 11. A tractor-mounted post driver. |
When
posts are not driven, you must dig holes and tamp (pack)
soil around the post with a small (approximately 1-inch
diameter) rod. While this method is not usually as
strong as driving posts, it is important to properly
tamp dirt around the posts in order to give the posts as
much strength as possible. Place the post in the hole
and line it up with other posts using a guide wire or
string. Then place a few inches of dirt in the hole and
tamp it. In order to achieve proper compaction, the soil
should be moist but not overly wet. Filling and tamping
is repeated a few inches at the time until the hole is
filled with compacted soil. The most important part of
tamping is getting the bottom 6 inches of soil properly
packed, and this cannot be accomplished if the hole is
filled before tamping begins - as is often done. In
general, concrete is notrecommended around posts. It
reacts with wood and actually causes the life of the
post to be shorter than when properly tamped with dirt.
Some small rocks or gravel can be added to the soil, but
it is important to have a variety of soil particle sizes
mixed in. In the long term, a few large rocks will not
hold as well as a mixture of rocks and soil or even
well-tamped soil.
Set
wooden line posts at least 2 feet deep. In most soils,
studded "T" (steel) posts need to be driven only until
the anchor plate is beneath the surface. For uni-form
depth, mark the digging tool or steel post to the
desired depth. A gauge pole, cut to desired length, is
handy for spacing posts. Space line posts about 10 to 12
feet apart for most fences (25 feet for high-tensile
wire fences). Narrow spacings are better over irregular
ground and in contour fences. Rail fences norm-ally have
post spacings of 8 to 10 feet.
Installing Wire on Fences
In
general, you will want to install and stretch wire in
sections, running from one corner and/or brace post
assembly to the next. Always work from the bottom up
when installing wire. Install the bottom wire first,
then the next highest, etc. Attach wire to the side of
the post nearest livestock except where appearance is
important. Use galvanized staples or the wire clips that
come with steel posts to attach wire to posts. (Of
course, fencing insulators must be used on electric
fence wire attached to steel or wooden posts.)
Staples
should never be smaller than 11/2
inches long, preferably 13/4
or 2 inches. Do not staple the vertical or stay wires of
wire mesh fencing. Drive staples so the wire is held
close to the post but not tight (Figure 12a). The wire
should be able to move through the staple to allow
expansion and contraction of the wire. Good brace
assemblies and tensioning springs (in high-tensile
fences) should keep the wire tight. Avoid driving
staples parallel with the grain since that will weaken
the grip of the wood on the staple. Rotate slash cut
staples in a certain direction depending on whether the
staples are right or left cut (see Figure 12b). Place
the staples parallel to the grain and then rotate
slightly away from the flat faces of the staple joints.
This will result in the desired direction of staple
penetration (Figure 12c) and a staple that has 40
percent more resistance to withdrawal than staples
rotated the wrong way.
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Figure 12. Proper stapling techniques are
important to prevent pull-out. |
Electric Fences
One of
the best ways of assuring good performance of an
electric fence is to provide a good grounding system.
For an electrical charge to do its job, it must travel
out on the "hot" or energized wire, go through the
animal, and return through either the earth or a
grounded return wire. A good grounding system will
improve current flow and make the fence more effective,
especially when the earth is dry. The controller
grounding system should be separate (a minimum of 50
feet away) from any other driven grounds or metal
objects that might be attached to grounding systems.
Failure to do this could cause stray voltage problems on
the farm electrical system. The grounding system should
consist of a minimum of 24 feet of ground rod. More
footage is needed for more powerful controllers. Check
your controller instructions for recommendations. This
is usually accomplished by driving three or more 8-foot
ground rods (see Figure 13) spaced 10 feet apart and
connected by #8 copper wire. In addition, place a driven
ground rod every 1/2 mile of fence
and attach it to the grounded wires in the fence. Proper
grounding will make the charger's job easier and thus
improve its performance. Lightning arresters are
available and help protect the controller if the
lightning strike is not too close, but they will
probably not prevent damage by a direct hit. As a rule
of thumb, you need one lightning arrester for every
ground rod in the controller grounding system. Space
arresters more or less equally around the fence with one
near the controller.
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Figure 13. Driven ground rod for grounding an
electric fence. |
One of
the best arrangements for electric fences is to
alternate charged wires and grounding wires. This
arrangement makes the fence much more effective than
charging every wire, especially when the ground is dry.
If all wires are charged, electricity must return to the
controller via the earth, and dry soil makes a poor
conductor. Drought conditions usually cause poor forage
in the pasture and poorly grounded electric fences,
which can mean problems with livestock escaping the
fence. Using alternate wires as hot and grounded wires
means any time an animal contacts two adjacent wires, he
will get a shock. The only disadvantage of this
arrangement is its susceptibility to short-out if limbs
or other heavy objects fall across the fence and cause
two strands to contact each other.
A fence
that is properly cared for will give long and
trouble-free service. Include some of the following
suggestions in your regular maintenance program:
-
Repair or replace anchor post assemblies when-ever
they show signs of weakness.
-
Paint
wooden fences as needed for longer life as well as
appearance.
-
Wash
PVC or vinyl fences with chlorine bleach solution to
remove mildew as needed.
-
Re-fasten loose wires to posts and splice broken
wires when necessary.
-
Keep
the fence wires properly stretched. This will be
needed once or twice a year for high-tensile fences.
-
Keep
weeds and brush cleared from the fence line,
especially on electric fences.
-
Check
the voltage on electrical fences on a regular basis.
Inspect the fence for problems if voltage begins to
fall.
-
Plan
and follow a regular inspection routine for any
needed maintenance.
Planning Fences,
American Association of Vocational Instructional
Materials, 1980.
Planning and Building Fences on the Farm,
University of Tennessee Agricultural Extension Service
PB 1541, 1996.
Fences for the Farm,
Circular 774, University of Georgia Cooperative
Extension Service, 2000.
Bulletin 1192/October, 2000
The University of Georgia and Ft. Valley
State University, the U.S. Department of Agriculture and
counties of the state cooperating. The Cooperative
Extension Service, the University of Georgia College of
Agricultural and Environmental Sciences offers
educational programs, assistance and materials to all
people without regard to race, color, national origin,
age, sex or disability.
An Equal Opportunity Employer/Affirmative Action
Organization Committed to a Diverse Work Force
Issued
in furtherance of Cooperative Extension work, Acts of
May 8 and June 30, 1914, The University of Georgia
College of Agricultural and Environmental Sciences and
the U.S. Department of Agriculture cooperating.
Gale A. Buchanan, Dean and Director |