| Pump
Terminology |
| Head |
Refers
to the height of a column of water that can be supported by
the pressure or vacuum exerted at the pump.
|
| Static
Suction Head |
The
vertical distance between the pump impeller and the surface
of the liquid on the suction side of the pump.
|
| Dynamic
Suction Head |
The
static suction head plus the additional suction head created
by friction from the liquid flowing through the hoses, fittings,
etc. Atmospheric pressure enables pumps to lift water. As a
result, an atmospheric pressure of 14.7 psi at sea level limits
practical dynamic suction head lift to less than approximately
26 feet for any pump.
|
| Static
Discharge Head |
The
vertical distance between the pump’s discharge port and
the point of discharge, which is the liquid surface if the hose
is submerged or pumping into the bottom of a tank.
|
| Dynamic
Discharge Head |
The
static discharge head plus the additional discharge head created
by friction or resistance (usually referred to as losses) from
the liquid flowing through the hoses, fittings, sprinklers,
nozzle, etc.
|
| Total
Head |
The
dynamic suction head plus the dynamic discharge head.
|
| Pressure |
Pressure
is force per unit area and is usually listed in psi (pounds
per square inch). Pressure is often included in pump performance
curves. Pressure and head are directly related when referring
to pump performance. The pressure exerted (in psi) at the base
of a column of water is 0.433 x Head (in feet). If you attach
pressure gauge at the base of a pipe 100 feet tall pipe filled
with clear water, you would measure 43.3 psi. Notice how the
diameter of the pipe doesn’t affect the pressure value.
The maximum pressure (at zero discharge) of any pump can be
determined by multiplying the maximum head by 0.433.
|
| Friction
Losses |
The
additional pressure or head created at the pump due to the friction
of the liquid flowing through the hoses, pipes, fittings, etc.
Friction losses always occur when a liquid is flowing through
pipes and becomes greater as the length of pipe increases and/or
the diameter decreases. Friction losses result in reduced pump
output and can be minimized by used the largest and shortest
hoses possible. Friction losses are included in dynamic suction
and dynamic discharge head.
|
| Impeller |
An
impeller is a rotating disk containing vanes coupled to the
engine’s crankshaft. All centrifugal pumps contain an impeller.
The impeller vanes sling liquid outward through centrifugal
force, causing a pressure change. This pressure change results
in liquid flowing through the pump.
|
| Volute |
The
volute is the stationary housing enclosing the impeller. The
volute collects and directs the flow of liquid from the impeller
and increases the pressure of the high velocity water flowing
from the vanes of the impeller.
|
| Self-Priming |
Most
centrifugal pumps require the pump casing to be filled with
water before starting. Self-priming is a term often used to
describe pumps that have the ability to purge air from the case
and create a partial vacuum, allowing water begin flowing through
the suction hose. All Honda pumps are defined as self-priming.
|
| Mechanical
seal |
This
is a spring-loaded seal consisting of several parts that seals
the rotating impeller in the pump case and prevents water from
leaking into and damaging the engine. Mechanical seals are subject
to wear when pumping water containing abrasives and will quickly
overheat if the pump is run without filling the pump chamber
with water before starting the engine. Honda trash pumps contain
silicone carbide mechanical seals, designed to withstand abrasive
conditions.
|
| Cavitation |
The
sudden formation and collapse of low-pressure vapor (bubbles)
across the vanes of the impeller. When the surface pressure
on a liquid becomes low enough, the liquid will begin to boil
(even at room temperature). With centrifugal pumps, cavitation
can occur when the suction vacuum becomes to great enough to
allow water vapor or bubbles to begin forming at the impeller.
When this water vapor travels through the rapid pressure increase
across the impeller, a large amount of energy is released which
can cause impeller damage. Minimizing suction head and using
the largest practical suction hose diameter will reduce the
likelihood of cavitation. You should never use a suction hose
with a diameter smaller than the pump’s suction port.
|
| Water
Hammer |
Water
Hammer is energy transmitted back to the pump due to the sudden
stoppage of water flowing from the pump. Water hammer is more
likely to occur when using a very long discharge hose. If the
flow of water at the end of the discharge hose is shut off in
less than the "critical time", energy is transmitted
back to the pump causing a large pressure spike in the pump
housing. Water hammer often results in damage to the pump casing.
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