Choosing the right pump: magnetic drive pumps vs electric diaphragm pumps
The benefits of the QUANTM electric operated double diaphragm pump compared to magnetic drive pumps.
Magnetic drive pumps are a good transfer solution with regards to leak prevention, maintenance requirements and they can handle corrosive, toxic, or flammable liquids. But much like standard centrifugal pumps, magnetic drive pumps are incompatible with many fluids. Furthermore, their magnetic mechanism can cause overheating and even alter the fluid’s composition. Graco’s QUANTM electric operated double diaphragm (EODD) pumps address all of these issues while also providing more unique features to enhance the transfer process.
Magnetic drive pumps
While magnetic drive pumps eliminate the problems associated with mechanical seals, they have a number of limitations that make them less than ideal for a range of industrial applications.
- Unsatisfactory solution for abrasives and solids
Magnetic drive pumps are primarily designed for pumping clean liquids that do not contain solids. Solids in the transfer material can cause quick failure of the close tolerance sleeve bearings and thrust surfaces inside the pump. These issues interfere with the pump’s performance and will accumulate, eventually causing complete failures of the pump and motor drive. Although some magnetic drive pumps are capable of moving heavier or more viscous fluids, they are best for applications that need to transport clean, low viscosity fluids. Ideally, they are not used for heavier applications that process solids containing fluids such as sludges, slurries and blends.
- Narrow preferred operating range and best efficiency point
Magnetic drive pumps are just like their cousin, the centrifugal pumps, in that they have a specific impeller diameter, which means they only operate at optimal efficiency at a specific flow. And just like centrifugal pumps, the operating range is narrow. Not only will moving outside the preferred range significantly reduce the pump’s efficiency, but eventually, it causes cavitation, vibration, impeller damage, suction and discharge recirculation, or reduced bearing and seal life.
- Deposit because of magnet overheating
The coupling action of the magnets can generate a lot of heat. Heat given off by surfaces warms the liquid in the pump and is passed into the process. If the material is not evacuated efficiently, the heat may rise enough to bake constituents of the process liquid into the impeller magnet hub, resulting in build-up of a deposit and eventually catastrophic failure of the pump itself. Furthermore, the magnets in a magnetic drive pump can demagnetize when exposed to temperatures above their upper limit. Dry-running mag-drive pumps exacerbates and speeds up these types of premature failures in the pump system.
- Sensitivity in low flow or near shut-off head conditions
Magnetic drive pumps are extremely sensitive when in low flow operation or near shut-off head conditions because the impeller is working against a higher head pressure. The magnetic coupling breakaway torque should not be exceeded. If this does occur, the magnetic coupling between the drive and the impeller axis is lost, causing the impeller to stop spinning, and damaging the pump or system.
- Sensitivity to variations in viscosity during operation
Liquids can vary in viscosity based on temperature or chemical reactions. The viscosity of the pumped fluid affects the required input power and magnetic torque required for transfer. All magnetic couplings are rated for a maximum torque; beyond this point, the magnets operate at reduced speeds (decoupling). Operation in this state can permanently de-magnetize the magnets, making these pumps especially vulnerable to variable operating conditions and resulting in high power demands. The integration of power monitors into the process should be included in the total investment cost for this type of pump.
- Not self-priming
Most centrifugal pumps are not self-priming. For the pump to work properly, its casing must be filled with liquid before start-up. When the casing fills with vapors or gases, the pump impeller becomes gas-bound and incapable of pumping. To make sure the pump remains primed and does not become gas-bound, centrifugal pumps need to be installed below the fluid level from which the pump takes its suction. Alternatively, the pump can be primed by supplying liquid under pressure through another pump placed in the suction line.
- Unable to run dry
Because the pumped liquid acts as a lubricant and coolant, in the event of running dry, the bearing and some other pump head parts will overheat and eventually become damaged. They will then require service or replacement. Magnetic drive pumps should not be used in services and applications with a risk of running dry.
Graco QUANTM EODD pumps
QUANTM is an electrically operated double diaphragm pump from Graco. Compared to a magnetic drive pump, the QUANTM EODD pump provides much more flexibility and sustainability. Take a look at the benefits:
- Wide operating range
QUANTM pumps are well suited to applications with varying flow and pressure. It poses no risk for shear-sensitive liquids and can easily handle abrasives and solids.
- Self-priming
QUANTM is self-priming and has excellent suction capabilities. With the added control of integrating an electric motor, every QUANTM pump includes a built-in AutoPrime feature for difficult to prime applications.
- Seal-less design
The QUANTM EODD’s seal-less diaphragm pump design eliminates leaking rotational seals and failures due to run-dry pump conditions.
- Stalls under pressure
The QUANTM pump stalls under pressure without any external sensors to prevent pump failures from clogged lines or closed valves.
- Runs dry
QUANTM pumps can run dry indefinitely without causing any damage to the system, thus avoiding costly repairs.
SUMMARY
These are the QUANTM electric double diaphragm (EODD) pump benefits in a nutshell
Magnetic drive pumps | Graco QUANTM EODD pumps |
Unsatisfactory for abrasives or solids | Easily compatible with abrasives and solids |
Narrow best efficiency point and preferred operating range | Consistent reliability over operating range |
Magnet overheating | Does not add heat to fluid being pumped |
Sensitive in low flow or near shut-off head conditions | Will not damage the pump at the outer limits of its performance range |
Deadhead/stall causes severe damage | Easily deadhead/stall with no additional equipment |
Process changes can lead to cavitation | No degradation due to changing conditions |
Difficult to choose correct pump | Simple pump selection (pressure/flow/chemical composition) |
Not self-priming | Excellent dry running/self-priming |
Special requirements for use in harsh environments | Can withstand harsh environments |
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