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Spray Equipment and Calibration
Many
pesticides used are applied with
hydraulic sprayers. Tractor-mounted, pull-type, pickup-mounted and
self-propelled sprayers are available. All sprayers have several basic
components: pump, tank, agitation system, flow-control assembly, pressure
gauge, and distribution system .
Properly applied pesticides should
be expected to return a profit. Improper or inaccurate application is usually
very expensive and will result in wasted chemical, marginal pest control,
excessive carryover, or crop damage.
Agriculture is under intense
economic and environmental pressure today. The high cost of pesticides and
the need to protect the environment are incentives for applicators to do
their very best in handling and applying pesticides.
Applicators of pesticides need to
know proper application methods, chemical effects on equipment, equipment
calibration, and correct cleaning methods. Equipment should be recalibrated
periodically to compensate for wear in pumps, nozzles, and metering systems.
Dry flowables may wear nozzle tips and may cause an increase in application
rates after spraying as little as 20ha.
Improperly used agricultural
pesticides are dangerous. It is extremely important to observe safety
precautions, wear protective clothing when working with pesticides, and
follow directions for each specific chemical. Consult the operator’s manual
for detailed information on a particular sprayer.
A sprayer is often used to apply
different materials, such as pre-emergent and postemergence herbicides,
insecticides, and fungicides. A change of nozzles may be required, which can
affect spray volume and system pressure. The type and size of pump required
is determined by the pesticide used, recommended pressure and nozzle delivery
rate. A pump must have sufficient capacity to operate a hydraulic agitation
system, as well as supply the necessary volume to the nozzles. A pump should
have a capacity of at least 25 percent greater than the largest volume
required by the nozzles. This will allow for agitation and loss of capacity
due to pump wear.
Pumps should be resistant to
corrosion from pesticides. The materials used in pump housings and seals
should be resistant to chemicals used, including organic solvents. Other
things to consider are initial pump cost, pressure and volume requirements, ease
of priming and power source available.
Pumps used on agricultural
sprayers are normally of four general types:
- Centrifugal pumps
- Roller or rotary pumps with
rolling vanes
- Piston pumps
- Diaphragm pumps
Centrifugal Pumps and Controls
Centrifugal pumps are the most
popular type for low-pressure high-volume sprayers. They are durable, simply
constructed, and can readily handle wettable powders and abrasive materials.
Because of the high capacity of centrifugal pumps (520ltrs/min or more),
hydraulic agitators can and should be used to agitate spray solutions even in
large tanks.
Pressures up to 6 bar are
developed by centrifugal pumps, but discharge volumes drop off rapidly above
2.8 bar. This “steep performance curve” is an advantage as it permits
controlling pump output without a relief valve. Centrifugal pump performance
is very sensitive to speed , and inlet pressure variations may produce uneven
pump output under some operating conditions.
Centrifugal pumps should operate
at speeds of about 3,000 to 4,500 revolutions per minute (RPM). When driven
with the tractor PTO, a speed-up mechanism is necessary. A simple and
inexpensive method of increasing speed is with a belt and pulley assembly.
Another method is to use a planetary gear system. The gears are completely
enclosed and mounted directly on the PTO shaft. Centrifugal pumps can be
driven by a direct-connected hydraulic motor and flow control operating off
the tractor hydraulic system.
This allows the PTO to be used for
other purposes, and a hydraulic motor may maintain a more uniform pump speed
and output with small variations in engine speed. Pumps may also be driven by
a direct-coupled gasoline engine, which will maintain a constant pressure and
pump output independent of vehicle engine speed. Centrifugal pumps should be
located below the supply tank to aid in priming and maintaining a prime.
Also, no pressure relief valve is
needed with centrifugal pumps. A
strainer located in the discharge line protects nozzles from plugging and
avoids restricting the pump input. Two control valves are used in the pump
discharge line, one in the agitation line and the other to the spray boom.
This permits controlling agitation flow independent of nozzle flow. The flow
from centrifugal pumps can be completely shut off without damage to the pump.
Spray pressure can be controlled by a throttling valve, eliminating the
pressure relief valve with a separate bypass line. A separate throttling
valve is usually used to control agitation flow and spray pressure.
Electrically controlled throttling valves are popular for remote pressure
control and are installed in an optional bypass line .
A boom shut-off valve allows the
sprayer boom to be shut off while the pump and agitation system continue to
operate. Electric solenoid valves eliminate the need for chemical-carrying
hoses to be run through the cab of the vehicle. A switch box which controls
the electric valve is mounted in the vehicle cab. This provides a safe
operator area if a hose should break.
To adjust for spraying with a
centrifugal pump , open the boom shut-off valve, start the sprayer and open
the throttling control valve until pressure comes up to 0.7 bar over the
desired spraying pressure. Then adjust the agitation control valve until good
agitation is observed in the tank. If the boom pressure has dropped slightly
as a result of the agitation, readjust the main control valve to bring the
pressure up to 0.7 bar above spraying pressure. Then open the bypass valve to
bring the boom pressure down to the desired spray pressure. This valve can be
opened or closed as needed to compensate for system pressure changes so a
constant boom pressure can be maintained. Be sure to check for uniform flow
from all nozzles.
Roller
Pumps and Controls
Roller pumps consist of a rotor
with resilient rollers that rotate within an eccentric housing. Roller pumps
are popular because of their low initial cost, compact size and efficient
operation at tractor PTO speeds. They are positive displacement pumps and
self-priming. Larger pumps are capable of moving 200l/ and can develop
pressures up to 21 bar. Roller pumps tend to show excessive wear when pumping
abrasive materials, which is a limitation with this pump.
Material options for roller pumps
include cast-iron or corrosion resistant NI-resist housings; nylon,
polypropylene, teflon or Buna-N-rubber rollers and Viton, Buna-N or leather
seals. Nylon rollers are used for all-around spraying; they are suitable for
fertilizers and weed and insect control chemicals, including suspensions.
Buna-N rollers are used for pumping abrasive suspensions and water.
Polypropylene rollers have proved
to be excellent for water handling applications and have approved wear
characteristics. Teflon rollers have also demonstrated multi-use chemical
handling ability. Roller pumps should have factory-lubricated sealed ball
bearings, stainless steel shafts, and replaceable shaft seals.
A control valve is placed in the
agitation line so the bypass flow is controlled to regulate spraying
pressure. Systems using roller pumps contain a pressure relief valve . These
valves have a spring-loaded ball, disc or diaphragm that opens with
increasing pressure so excess flow is bypassed back to the tank, preventing
damage to sprayer components when the boom is shut off.
Pressure relief valve.
The agitation control valve must
be closed and the boom shut-off valve must be opened to adjust the system .
Start the sprayer, making sure flow is uniform from all spray nozzles, and
adjust the pressure relief valve until the pressure gauge reads about 1bar
above the desired spraying pressure. Slowly open the throttling control valve
until the spraying pressure is reduced to the desired point. Replace the
agitator nozzle with one having a larger orifice if the pressure will not
come down to the desired point.
Use a smaller agitation nozzle if
insufficient agitation results when spraying pressure is correct and the
pressure relief valve is closed. This will increase agitation and permit a
wider open control valve for the same pressure.
Piston Pumps and Controls
Piston pumps are positive
displacement pumps, where output is proportional to speed and independent of
pressure. Piston pumps work well for wettable powders and other abrasive
liquids. They are available with either rubber or leather piston cups, which
permit the pump to be used for water or petroleum based liquids and a wide
range of chemicals. Lubrication of the pump is usually not a problem due to
the use of sealed bearings.
The use of piston pumps for farm
crop spraying is limited partly by their relatively high cost. Piston pumps
have a long life, which makes them economical for continuous use. Larger
piston pumps have a capacity of 96 to 150 l/m and are used at pressures up to
42 bar. This high pressure is useful for high pressure cleaning, livestock
spraying or crop insect and fungicide spraying. A piston pump requires a
surge tank at the pump outlet to reduce the characteristic line pulsation.
It is similar to a roller pump
except that a surge tank has been installed at the pump outlet. A damper is
used in the pressure gauge stem to reduce the effect of pulsa-tion. The
pressure relief valve should be replaced by an unloader valve . when
pressures above 14 bars are used. This
reduces the pressure from the pump when the boom is shut off so less power is
required. If an agitator is used in the system, agitation flow may be
influenced when the valve is unloading.
Open the throttling control valve
and close the boom valve to adjust for spraying .Then adjust the relief valve
to open at a pressure 1bar above spraying pressure. Open the boom control
valve and make sure flow is uniform from all nozzles. Then adjust the
throttling control valve until the gauge indicates the desired spraying
pressure.
Diaphragm Pumps and Controls
Diaphragm pumps are popular in the
agricultural market because they can handle abrasive and corrosive chemicals
at high pressures. They operate efficiently at tractor PTO speeds of 540 rpm
and permit a wide selection of flow rates. They are capable of producing high
pressures (to 60 bar) as well as high volume (240l/m), but the price of
diaphragm pumps is relatively high. High pressures and volumes are needed
when applying some pesticides such as fungicides. Diaphragm pumps are excellent
for this job. The spray system hookup for diaphragm pumps is the same as for
piston pumps . Be sure the controls and all hoses are large enough to handle
the high flow, and all hoses, nozzles and fittings must be capable of
handling high pressure.
The type of pesticide and nozzle
being used usually determine the pressure needed for spraying. This pressure
is usually listed on the chemical package. Low pressures of 1 to 3 bars may
be sufficient for spraying most herbicides or fertilizer, but high pressures
up to 30 bar or more may be needed for spraying insecticides or fungicides.
Spray nozzles are designed to be
operated within a certain pressure range. Higher than recommended pressures
increase the delivery rate, reduce the droplet size, and may distort the
spray pattern. This can result in excess spray drift and uneven coverage. Low
pressures reduce the spray delivery rate, and the spray material may not form
a full width spray pattern unless the nozzles are designed to operate at
lower pressures.
Always follow the pressure
recommendations of nozzle manufacturers as explained in product catalogs.
Avoid using nozzles too small for
the job. To double the spray rate from nozzles, the pressure has to be
increased by a factor of four times. This may exert excessive strain on
sprayer components, increase wear on the nozzles and produce
drift-susceptible droplets.
A pressure gauge should have a
total range twice the maximum expected reading. The gauge should indicate
spray pressure accurately. Measuring the discharge rate at a specific
pressure on the gauge is recommended during calibration. Install a gauge
protector or damper to prevent damage.
Sprayer Tanks
The tank should be made of a
corrosion-resistant material. Suitable materials used in sprayer tanks
include stainless steel, polyethylene plastic and fiberglass. Pesticides may
be corrosive to certain materials. Care should be taken to avoid using
incompatible materials. Aluminum, galvanized or steel tanks should not be
used. Some chemicals react with these materials, which may result in reduced
effectiveness of the pesticide, or rust or corrosion inside the tank.
Keep tanks clean and free of rust,
scale, dirt, and other contaminants which can damage the pump and nozzles.
Also, contamination may collect in the nozzle and restrict the flow of
chemical, resulting in improper spray patterns and rates of application.
Debris can clog strainers and restrict flow of spray through the system.
Flush the tank with clean water
after spraying is completed. A tank with a drain hole at the bottom near one
end helps allow complete drainage. A tank with a small sump in the bottom is
another excellent alternative. An opening in the top large enough for
internal inspection, cleaning, and service is a necessity.
The capacity of the tank must be
known to add the correct amount of pesticide. Most new tanks have capacity
marks on the side. If your tank is not translucent, it should have a sight
gauge to indicate the fluid level. The sight gauge should have a shut-off
valve at the bottom to allow closing in case of damage. On plastic and
fiberglass tanks, marks can be placed on the side of the tank. Your sprayer
should be sitting on level ground when reading the litres remaining in the
tank. Incorrect volume readings cause improper amounts of pesticide to be
added, which can result in poor pest control, crop injury, or increased
pesticide cost.
An agitator in the tank is needed
to mix the spray material uniformly and keep chemicals in suspension .
The need for agitation depends on
the type of pesticide applied. Liquid concentrations, soluble powders, and
emulsifiable liquids require little agitation. Intense agitation is required
to keep wettable powders in suspension so a separate agitator, either a
hydraulic or mechanical type, is required. The hydraulic jet type is operated
by a pressure line hooked into the spray system directly behind the pump. The
hydraulic jet agitator should be positioned in the tank to provide agitation
throughout the tank. A flow of 20 to 24 litres for each 400 litre tank
capacity is usually adequate for an orifice jet agitator. Several types of
venturi-suction agitators are available that help stir the liquid with less
flow. With these, the agitation flow from the pump can be reduced to 8 or 12
litres per 400 litre tank capacity.
Do not install a jet agitator on
the pressure regulator bypass line, as low pressure and intermittent liquid
flow will usually produce poor results. They will agitate the spray solution
only when the spray boom is shut off.
A mechanical agitator with a shaft
and paddles will do an excellent job of maintaining a uniform mixture but is
usually more costly than a jet agitator. Mechanical agitators must be
operated by a separate drive, hydraulic motor or 12 volt electric motor. They
should be run between 100 and 200 RPM. Higher speeds may cause foaming of the
spray solution. Adjustable agitators are desirable to minimize the foaming
that can occur with vigorous agitation of certain pesticides as the volume in
the tank decreases. Agitation should be started with the tank partly filled
and before pesticides are added to the tank. With wettable powders and
flowables, continue to agitate while filling the tank and during travel to
the field. Don’t allow pesticides to settle as the spray mix must be kept
uniform to avoid concentration error. This is especially important with
wettable powders because they don’t dissolve, they are usually much heavier
than water, and they are extremely difficult to get them in suspension after
they have settled out in the tank and hoses.
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