Diluted acetic acid feeding pump submersible centrifugal pump
Centrifugal Pumps Overview
Centrifugal Pumps are the most popular and commonly used type of pump for the transfer of fluids. In simple words, it is a pump that uses a rotating impeller to move water or other fluids by using centrifugal force. These are the undisputed pump choice especially for delivering liquid from one location to another in numerous industries including agriculture, municipal (water and wastewater plants), industrial, power generation plants, petroleum, mining, chemical, pharmaceutical, and many others.
Centrifugal Pumps are useful since they can generally handle large quantities of fluids, provide very high flow rates (which may vary with the changes in the Total Dynamic Head (TDH) of the particular piping system) and have the ability to adjust their flow rates over a wide range.
Centrifugal pumps are generally designed and suitable for liquids with a relatively low viscosity that pours like water or light oil. More viscous liquids such as 10 or 20 wt. oils at 68-70 deg F will require additional horsepower for centrifugal pumps to work. For viscous liquids of more than 30 wt. oils, positive displacement pumps are preferred over centrifugal pumps to help lower energy costs.
Let us understand in detail, how a Centrifugal pump works. Centrifugal pumps are used to induce flow or raise a liquid from a low level to a high level. These pumps work on a very simple mechanism. A centrifugal pump converts rotational energy, often from a motor, to energy in a moving fluid.
The two main parts that are responsible for the conversion of energy are the impeller and the casing. The impeller is the rotating part of the pump and the casing is the airtight passage which surrounds the impeller. In a centrifugal pump, fluid enters into the casing, falls on the impeller blades at the eye of the impeller, and is whirled tangentially and radially outward until it leaves the impeller into the diffuser part of the casing. While passing through the impeller, the fluid is gaining both velocity and pressure.
Creating a resistance to the flow controls the kinetic energy of a liquid coming out of an impeller. The first resistance is created by the pump volute (casing), which catches the liquid and slows it down. When the liquid slows down in the pump casing, some of the kinetic energy is converted to pressure energy. It is the resistance to the pump’s flow that is read on a pressure gauge attached to the discharge line. A pump does not create pressure, it only creates flow. Pressure is a measurement of the resistance to flow.
Centrifugal pumps details:
Working Principle: | A centrifugal pump converts rotational energy, often from a motor, to energy in a moving fluid. |
Main applications: | Oil & Energy/Industrial & Fire Protection /Waste Management/Pharmaceutical, Chemical & Food Industries |
Driver: | Electric motor, diesel engine |
Power Specs: | 220/240/380/415 V 3phase; 50hz/60hz |
Max.permissible fluid temperature: | 350°C |
Type of connection: | Flange |
Installation position: | Horizontal |
Casing/Inner parts material: | Cast iron, Stainless steel/Cast iron, Stainless steel |
Shaft seal type: | Mechanical seal |
Maximum drive rating: | 45KW |
Maximum caliber: | 300mm(12nch) |
Maximum discharge-side pressure: | 0.8MPa(8bar) |
Maximum head: | 80m(262.4ft) |
Flow rate range: | 10-600m3/h |