Pumps Terminology

Glossary

By Jayesh Patel
Published 05/1/2008
Pumps Terminology
Rating: Unrated

Who needs to know anything about pumps? You do!

Mechanical pumps are the second most common machine in the world, after electric motors.

GLOSSARY OF HEAT PUMPS TERMS

By Jayesh Patel
Published 03/13/2008
Pumps Terminology
Rating: Unrated

GLOSSARY OF TECHNICAL TERMS

There are many technical terms used in the description of Heat Pump systems; most of them are self-explanatory, but a glossary of terms will help to explain what they mean.

Most technical terms concern the refrigeration system found in all heat pumps:

Heat Pump: A heat pump is a device for transferring energy in the form of useful heat from one place to another. It cannot store, make or destroy heat energy – it simply moves it. There are a number of techniques that exploit heat transfer; the commonest in use is the Refrigeration Cycle. A heat pump is capable of transforming a large quantity of low grade, low temperature heat. Some air source systems will operate in winter ambient conditions down to -15ºC. Heat pumps are available that can operate in a variety of media Air, Water, glycol, etc.

A European standard for testing and rating heat pump performance, EN 14511 –
Part 1, defines a heat pump:
“[a] heat pump [is an] encased assembly or assemblies designed as a unit to provide delivery of heat. It includes an electrically operated refrigeration system for heating. It can have means for cooling, circulating, cleaning, and dehumidifying the air. The cooling is by means of reversing the refrigeration cycle”.

Heating Only Heat Pump: Ground Source heat pump systems are often optimised specially to deliver heating only. These units are often capable of delivering greater overall energy efficiencies than reversible units because the system is designed for a constant unvarying load above the freezing point of water at the evaporator section and can dispense with the Defrost Cycle.

Compressor: The compressor is often referred to as the heart of the refrigeration or heat pump system. It serves two main purposes. The first is to circulate the refrigerant fluid through the circuit like a pump, the other is to compress and raise the pressure and temperature of the refrigerant vapour so that it can easily be condensed back into a liquid to resume the heat transfer process.

Reverse Cycle Heat Pump: A reverse cycle system is a refrigeration system that can, by means of a valve that reverses the flow of the refrigerant fluid, change the operation of the system from heating to cooling. Or to facilitate defrost.

Heat Exchanger: A heat exchanger is a device for the transfer of heat energy from one medium to another. It can take a variety of different forms; the commonest in everyday use is a central heating radiator where hot water is circulated through pipes or plates and gives its heat up to the surrounding air.

Evaporator: In refrigeration systems the evaporator is the heat exchanger where refrigerant fluid is evaporated it absorbs heat from the surrounding air or water, thereby reducing its temperature.

Defrost Cycle: Where reversible air source systems operate at low ambient temperatures, the evaporator in the outdoor unit may attract moisture from the air at low ambient temperatures that will freeze forming a coat of ice. This is a function of the natural humidity outdoors and is not abnormal. This coating of ice is removed periodically with an automatic defrost cycle. The frequency of the defrost cycle is controlled automatically by a combination of time and temperature of the external coil.

Condenser: In refrigeration systems the condenser is the heat exchanger where Hot, compressed refrigerant gas is condensed to a liquid and further cooled to recommence its journey around the circuit.

Metering Devices: In a refrigeration based heat pump system, the flow and evaporation rate of the refrigerant within the evaporator is controlled by metering devices at the entrance to the evaporator.These devices are available in a variety of forms; the 3 most common types in commercial systems are:

Capillary tubes:
Any fluid flowing through an orifice will experience a drop in pressure. A capillary tube is a precisely measured length of a narrow tube with a pre-determined internal diameter that produces the desired drop in pressure along its length.

Thermostatic Expansion Valve (TEV):
An automatic mechanical valve that is self compensated for the pressure losses in the evaporator and controls the leaving superheat temperature of the refrigerant.

Electronic Expansion Valve (EEV):
A valve that is driven by a small dc stepping motor. Operates in the same way as a TEV, although the valve positioning is determined by a microprocessor. EEVs are capable of more precise metering and are found mainly in fully automatic systems.

Refrigerant: The heat transfer fluid contained in a heat pump refrigeration circuit. Normally this is a chemical contained in a hermetically sealed circuit that has a low temperature boiling point; refrigerants can be one of a number of man-made Fluorocarbons or a Hydrocarbon compound (refined Propane or Isobutane).

Ground Source Heat Pump: A heat pump installation that uses the earth as a heat sink to store heat or as a source of heat. In the UK the temperature below ground at a few tens of metres depth is stable within a small tolerance year round. Heat can be stored or obtained from shallow ground, about 2 m depth, or by deeper bore-holes where space is a consideration.

Geothermal Energy: Geothermal energy (so-called hot rocks) is obtained by deep drilling in suitable geological areas where volcanic activity can provide heat from the earths crust. This is a separate and distinct technology and should not be confused with ground source heat pumps.

Inverter Drive or Variable Speed Drive (VSD): Refrigeration systems in air to air heat pumps are often subject to wide variations in capacity and demand. A VSD system uses electronic speed control to vary the speed of the compressor motor. The motor speed can be increased to compensate for low ambient temperature conditions when less heat is available to use or decreased during mild weather. VSD systems are capable of high energy efficiencies because they match the unit’s capabilities to demand. Also known as VRV (Variable Refrigerant Volume) and VRF (Variable Refrigerant Flow).

Air to Air: A heat pump where the collecting medium is air and the destination medium is also air. Generally, most commercial small split and packaged systems are direct air to air.

Water to Water: A heat pump where the collecting medium (source) is either ground water or a glycol solution and the destination medium is also water or glycol. These systems are invariably indirect.

Air to Water: Air to water systems are mostly single packaged units. An outdoor unit collects heat from ambient air and delivers it to the conditioned space by means of water or glycol circulated through fan coils. This type of system uses a mixture of direct acting outdoor unit coupled with an indirect indoor section.

Water to Air: Water source systems are used where a supply of ground water, ponds or lakes are available. These systems are invariably indirect and need careful filtration to remove particles from the water source before it enters the heat exchanger. In the UK permission is usually needed for extraction of ground water.

Direct/Indirect: A direct system operates with the refrigerant in either or both heat exchangers in direct contact with the source or destination medium.

An indirect system has a secondary medium, water or glycol, circulated through the heat exchangers. By this means the refrigerant is contained in one remote place and refrigerant quantities can be minimised. This type of system is mandatory for all flammable or toxic refrigerants.

CoP: (Coefficient of Performance): Used as a ratio, CoP is an expression of the output of a machine in heating mode. The rated capacity divided by the rated total power input. In practice this is expressed as a single figure or sometimes as a percentage. For example, a system that is rated in heating at 6.5kW, with a rated power consumption of 1.8kW will have a CoP of 3.61 or 361%.
(See EER).

Energy Efficiency Ratio (EER). The out put of a machine in cooling mode. The rated capacity is divided by the rated total power input. In practice this is expressed as a single figure or sometimes as a percentage.

For example, a system that is rated in cooling at 6.5kW, with a rated power consumption of 1.8kW will have an EER of 3.61 or 361%.
(See CoP).

Kilowatt: The SI unit of power. It is used to specify the thermal performance of a Heat Pump as well as the power energy it consumes.

Kilowatt Hour (kWh): The standard unit of sale of electricity; it is the equivalent power consumed by a purely resistive load of 1000 Watts (1kW) for 1 hour. Your electricity supplier will specify the price in your supply contract.

CO2 Emission Comparisons with other Technologies

Pond Pump Glossary

By Jayesh Patel
Published 03/13/2008
Pumps Terminology
Rating: Unrated

Pond Pump Glossary

Inlet/Intake - Refers to the opening through which water enters the pump head.
Outlet/Discharge - The opening through which water exits the pump.
Flooded Suction/Gravity Fed - Liquid source is higher than the pump, and liquid flows to pump by gravity. Recommended for centrifugal pump installations.
Shutoff - Point in which pump will not push water passed the listed feet in a vertical column . No flow past the listed vertical feet. This does not effect the horizontal run but if the run is very long say 50 or 100 ft. then friction comes into play.
Flow - The measure of the liquid volume capacity of a pump. Given in Gallons Per Hour (GPH) or Gallons Per Minute (GPM) , as well as Liters Per Minute (LPM) and Milliliters Per Minute (ML/M).
Head - Another measure of pressure, expressed in feet. Indicates the height of a column of water being lifted by the pump, neglecting friction losses in piping. If pump is submerged, the head can be measured from the surface of the water. Head ( Ft. of Water) = 2.31 PSI. Example: 10 feet equals 4.32 PSI.
Seal-less - No seal is used, power is transmitted from the motor to pump impeller by magnetic force. Example is Magnetic Drive Aquarium Pumps and Wet rotor pumps. Example : Little Giant aquarium pumps, PES Wet Rotor Models (most mini pumps) and Cal "P" Models.
Submersible - A pump which operates only when totally submersed in the fluid which is being pumped, with water-proof electrical connections or cord , using a motor which is cooled by liquid.
In-Line - A pump which operates in open air , by connecting tubing to the inlet and discharge outlet.
Dual Purpose - This versatile pump category is designed to operate submersed or in-line.
NPT - Refers to the National Pipe Thread standard measurement.
MNPT - This refers to female pipe thread, in which the threads are on the inner side of the connection fitting.
Thermally Protected - Mechanically safety device in the motor to prevent overheating.
Impedance Protected - A non-mechanical method of preventing motor overheating. The motor coil is designed to "impede" excess current, resulting in a stabilized motor temperature.
Barbed Fitting - As apposed to a threaded fitting , rings projecting outward around fitting designed to grip hose. Usually measured in O.D. (outside diameter) , as apposed to hose measured in I.D. (inside diameter).
Quick Disconnect - Fittings that are locked on the the pump ports with a latch or locking device to convert pump ports to threaded or barbed connections , usually used on high pressure pumps.
Relay - Electrical solenoid with heavy contacts designed to absorb high current or high amp draw , usually for motors with 3 HP or larger or used with sprinkler timers to activate a sprinkler pump.

Coil voltage of solenoid may vary depending on control device, usually coil voltages come in 24V , 110V or 230V AC , amp and horsepower ratings for contacts are usually listed.
Kilowatt(1000 watts) Hour - Electrical measurement designed to bill customers based on usage per hour. Watts are listed for every unit , power consumption and cost is dependent on the KILOWATT HOUR charged in your area. If a pump states that it uses 1000 watts and your power company charges you 10 cents a kilowatt hour then it cost's you 10 cents an hour to run that unit and if the pump list's 250 watts then it cost's you 2.5 cents per hour to run that unit.
Centrifugal pump - moves water by displacing liquid from the center of the impeller as it spins to the outer part of the impeller creating a vacuum in the center by means of centrifugal force. The diameter of the impeller predicts the pressure and the width predicts the water flow. Impellers can spin at 3600 RPM and 1800 RPM and other speeds , all fountain pumps are centrifugal. This type of pump is not self priming except in the case of sprinkler pumps , pumps with leaf baskets and pumps with foot valves installed (jet pumps).
Positive Displacement pump - remove water from a cavetti or cylinder by directly applying pressure to a diaphragm or piston or a flexible impeller and cam. Check valves are used to preserve the pressure down line except in the case of the flexible impeller and cam. Usually diaphragm or flexible impeller or piston pumps are used for more exact amounts of water and for higher pressures. This makes them ideal for solar applications , RV's, pressure washers, small cabins, R.O., misters or situations where water demand is low but pressure demand is high. A centrifugal pump is limited in the pressure it can produce unless the design of the pump allows for impeller stacks. This type of pump is usually self priming a few feet.

Types of Pond Pumps

Large Volume Plastic pumps - These pumps utilize a permanent split capacitor (PSC) motor sealed in a Stainless Steel Housing, which in turn, is surrounded by a plastic case. The PCS motor allows these pumps to use less energy than other pumps of similar flow capacity. The motor also produces less heat ; therefore, the pump does not require oil internally. These pumps are ideal for use in waterfall and stream applications, found in water gardens.
Epoxy Encapsulated (Potted) Pumps - These pumps feature an epoxy-encapsulated motor, plastic housing, and radial lip seal on the motor shaft. They provide enough power to effectively operate a water garden, statuary or tabletop fountain. Algae build-up does not effect these small, powerful workhorses. In fact, they may even be used in some harsh, industrial-type applications. These "potted" pumps are usually more compact in size than an oil-filled pump of equal flow capacity.
Wet-Rotor (Hysteresis) Pumps - The wet-rotor pumps, often mistaken as magnetic drive pumps, utilize an epoxy-encapsulated motor and plastic housing. A permanent magnet is attached to the impeller. The magnet acts as the rotor would in a conventional motor. The water being pumped surrounds the rotor, thus the term "wet-rotor". They are seal-less and oil-less. These pumps work well in water garden, statuary, and some industrial applications. They are the most compact and energy efficient type of pump manufactured. The other side of this efficiency is very little starting torque. therefore, these pumps do not produce as much pressure and will not pump water as high as as their epoxy-encapsulated counterparts.
Permanently Lubricated Pumps - Without exception , these pumps offer the ideal combination of assets. The oil-filled motor housing design also features a radial lip seal on the motor shaft. They have an exceptional life expectancy, because the oil serves as a continuous lubricant for all the moving parts and the shaft seal. This non-toxic oil, often paired with an aluminum, cast iron, or plastic housing, also helps dissipate heat build-up found in continuous-running pumps. Therefore, the motor stays cool and extends the life of the pump.