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Comparison Shimge QDX30-6-0.75L vs Delfin MVS 12-I

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Shimge QDX30-6-0.75L
Delfin MVS 12-I
Shimge QDX30-6-0.75LDelfin MVS 12-I
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Suitable forclean waterwaste water
Specs
Maximum performance
45000 L/h /maximum/
30000 L/h /maximum/
Maximum head
11 m /maximum/
10 m /maximum/
Pump typecentrifugal
Maximum immersion depth5 m
Maximum particle size0.2 mm35 mm
Maximum liquid temperature40 °С35 °С
pH value6.5 – 8.5
Float switch
Suction systemmultistagesingle-stage
Outlet size3"2"
Engine
Maximum power750 W750 W
Power sourceelectricelectric
Mains voltage230 V230 V
Power cord length8 m10 m
General specs
Protection class (IP)X868
Country of originChinaUkraine
Pump housing materialaluminiumstainless steel
Impeller / auger materialaluminiumstainless steel
Dimensions260х420 mm
Weight11.6 kg
Added to E-Catalogdecember 2017november 2014

Suitable for

— Pure water. Pure water pumps conventionally include all models for which the maximum particle size (see below) does not exceed 5 mm; in addition, the permissible content of mechanical impurities (also see below) for them is also small. Accordingly, many of these models are capable of pumping water with impurities normally, but they are not suitable for heavily contaminated liquids.

— Dirty water. This category includes pumps capable of working with large mechanical impurities — more than 5 mm. Note that some manufacturers position such models as mixed-use units, “for dirty and clean water”. However, they have a reinforced design, the presence of a grinder capable of grinding the particles mentioned, a reinforced body, an increased diameter of pipes, increased power, etc. .P. The main difference between such pumps and waste water pumps (see above) is the impossibility of working with high-viscosity liquids.

— Waste water. Waste water pumps are in many ways similar to the models for dirty water described above because they also have to deal with large particles. The main difference is the allowable size of these particles — it is 50 mm or more; in addition, the entire design of such pumps is created based on the high viscosity of the pumped liquid.

— Chemical liquids. Pumps designed to work with chemical liquids are distinguished primarily by the use of highly resistant materials in the design — usually polymers. Due to this, they can endur...e working with aggressive substances without consequences — acids, alkalis, oil products, solvents, liquefied gases, etc. In addition, other special solutions are often used in “chemical” pumps, which allow the safe pumping of flammable and explosive materials, very cold, hot, viscous liquids, etc. The main scope of such units is the industry — both chemical and oil, food, etc. Note that different models can be designed for different types of substances.

Maximum performance

The maximum volume of water that the device can pump in a certain amount of time. It is one of the key specs of any pump because characterizes the volume of water with which the device can work. At the same time, it does not always make sense to pursue maximum performance — after all, it significantly affects the dimensions and weight of the unit.

Some formulas allow you to derive optimal performance values for different situations. So, if the pump is designed to supply water to water intake points, its minimum required performance should not be lower than the highest total flow rate; if desired, a margin of 20-30% can be added to this value. And for sewer models (see "Suitable for"), everything will depend on the volume of wastewater. More detailed recommendations for choosing a pump depending on performance can be found in special sources.

Maximum head

The maximum head generated by the pump. This parameter is most often indicated in meters, by the height of the water column that the unit can create — in other words, by the height to which it can supply water. You can estimate the pressure created by the pump using a simple formula: every 10 m of head corresponds to a pressure of 1 bar.

It is worth choosing a pump according to this parameter, taking into account the height to which it should supply water, as well as adjusting for losses and the need for pressure in the water supply. To do this, it is necessary to determine the difference in height between the water level and the highest point of water intake, add another 10 to 30 m to this figure (depending on the pressure that needs to be obtained in the water supply), and multiply the result by 1.1 — this will be the minimum pressure required.

Pump type

The basic principle by which the suction action of the pump is carried out.

— Centrifugal. As the name suggests, this type of pump uses centrifugal force. Their main element is the impeller installed in a round casing; the inlet is located on the axis of rotation of this wheel. During operation, due to the centrifugal force that occurs during the rotation of the wheel, the liquid is thrown from the centre to its edges and then enters the outlet pipe directed tangentially to the circle of rotation of the wheel. Centrifugal pumps are quite simple in design and inexpensive, while they are reliable and economical (due to high efficiency), have a large suction height (see below), and the fluid flow is continuous. At the same time, the performance of such units can drop dramatically with high resistance in the water supply system. In addition, if the liquid level is below the inlet, the pump will have to be refilled with water before each start.

— Vortex. Peripheral pumps are somewhat similar to centrifugal pumps: they also have a round casing and an impeller with blades. However, in such units, both the inlet and outlet pipes are directed tangentially to the impeller, and the blades differ in design. The method of operation is also fundamentally different — by the name, of it uses the vortices formed on the wheel blades. Vortex units are significantly superior to centrifugal ones in terms of pressure; in addition, they are usually self-priming (see "Suction...type"), and the design in most cases is such that the pump has to be filled with water only when it is first turned on after installation. On the other hand, such models are sensitive to contamination — even small particles entering the impeller can cause damage, significantly reducing efficiency. Yes, and the efficiency of vortex pumps is low — 2-3 times lower than that of centrifugal pumps; they are also inferior in suction height (see below).

— Centrifugal-vortex. Pumps that combine the two principles described above in operation. Such a unit is a pair of centrifugal and vortex pumps mounted on a common shaft and connected in series. During operation, water first enters the centrifugal wheel, which is responsible for suction, and then to the vortex wheel, which provides pressure. Due to this, it was possible to combine the advantages of both types in one unit — a large suction height, a high pressure and a self-priming device. However, these units cost accordingly.

— Vibratory. The term "membrane" is also used. The action of vibration pumps is based on the use of a flexible membrane, equipped with a device that makes it vibrate. This membrane is one of the walls of the working chamber, and the chamber itself has inlet and outlet valves. When the membrane moves "out" and the volume of the working chamber increases, the inlet valve opens (the outlet is closed), allowing fluid to enter; and when the membrane moves “inward” and pushes the liquid out, on the contrary, the outlet opens. The main advantages of this device are simplicity, compactness, versatility, low cost, ease of regulation and almost complete insensitivity to dry operation. At the same time, the service life of such units is relatively short due to the strong wear of the membrane.

— Auger. The main part of such pumps is precisely the auger — a rotor (or several rotors) in the form of a screw. This design makes the pump very reliable, allows it to achieve high outlet pressure and uniform liquid supply, provides self-priming (see "Suction type"), and also has a low noise level. At the same time, auger units are difficult to manufacture and, accordingly, expensive.

Maximum immersion depth

The maximum depth at which a submersible pump can be placed without the risk of failure or breakdown. It is usually indicated for fresh water, so in fact it is advisable not to lower the pump to the maximum depth level — after all, the density of the pumped liquid may be greater, which will create off-design loads on the structure.

Maximum particle size

The largest particle size that the pump can handle without problems. This size is the main indicator that determines the purpose of the device (see above); and in general, the larger it is, the more reliable the device, the lower the risk of damage if a foreign object enters the suction line. If the risk of the appearance of too large mechanical impurities is still high, additional protection can be provided with filters or grids at the inlet. However, such a measure should be considered only as a last resort, because from constant exposure to solid particles, the grids become clogged and deformed, which can lead to both clogging of the line and filter breakthrough.

Maximum liquid temperature

The highest temperature of water at which the pump is capable of operating normally. Usually, in most models this parameter is 35-40 °C — at high temperatures it is difficult to ensure effective cooling of the engine and moving parts, and in fact, such conditions are rare.

pH value

The pH value of the pumped liquid for which the pump is designed. This indicator describes the level of acidity of the medium, roughly speaking, how reactive it is to the “acidic” or “alkaline” side: low pH values correspond to an acidic environment, and high pH values are alkaline. Acid and alkaline have different effects on the materials used in the construction of various equipment, including pumps. Therefore, when designing parts in direct contact with the liquid, the pH level must be taken into account, and the use of the pump with unsuitable substances is not recommended — this can lead to corrosion, which affects the composition of the pumped liquid and reduces the life of the unit. However, this parameter is critical mainly for specialized models such as pumps for chemical liquids or sewage (see "Suitable for"). In ordinary water (even dirty) the pH range is not so extensive that it cannot be covered entirely.

Suction system

— Single-stage. Suction system with one impeller or similar element. Although such a design loses to a multistage one in terms of efficiency and power, at the same time, its characteristics are quite enough for most tasks; while single-stage pumps are simpler and cheaper. Due to all this, this option is used in most modern units.

— Multistage. This suction system consists of several impellers (or other similar parts that directly provide suction). Such pumps are significantly superior to single-stage ones, they provide powerful pressure and are less sensitive to impurities. At the same time, in fact, all these advantages are needed relatively rarely, and multistage systems are quite expensive. Because of this, they are used in a relatively small number of pumps — they are mainly powerful models designed for situations where one suction stage is not enough.