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Comparison Grundfos ALPHA1 L 25-60N-180 6.5 m
1 1/2"
180 mm
vs Grundfos UPS 25-40N-180 3.8 m
1 1/2"

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Grundfos ALPHA1 L 25-60N-180 6.5 m 1 1/2" 180 mm
Grundfos UPS 25-40N-180 3.8 m 1 1/2"
Grundfos ALPHA1 L 25-60N-180 6.5 m
1 1/2"
180 mm
Grundfos UPS 25-40N-180 3.8 m
1 1/2"
Expecting restock
from $188.76
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Main functioncentral heatingcentral heating
Designsingle headsingle head
Pump typecentrifugalcentrifugal
Rotor typewetwet
Specs
Max. flow3560 L/h2900 L/h
Max. head6.5 m3.8 m
Max. operating pressure10 bar10 bar
Minimum fluid temperature2 °С2 °С
Max. fluid temperature95 °С110 °С
Features
stepless adjustment
automatic operating mode
control panel
3 speeds
 
 
Motor
Max. power consumption45 W
45 W /35/25 W/
Mains voltage230 V230 V
Shaft arrangementhorizontalhorizontal
Connection
Connection typethreadthread
Inlet/outlet arrangementcoaxiallycoaxially
Inlet1 1/2"1 1/2"
Outlet1 1/2"1 1/2"
More specs
Pump housing materialstainless steelstainless steel
Impeller materialplastic
Country of brand originDenmarkDenmark
Protection classIPX4DIP44
Insulation classF
Port-to-port length180 mm180 mm
Dimensions (HxWxD)134x123x180 mm
Weight2.1 kg
Added to E-Catalogmay 2022november 2014

Max. flow

The maximum flow of a pump is the amount of liquid it can pump in a certain amount of time.

Features of choosing the optimal performance option depend primarily on the purpose of the pump (see above). For example, for DHW recirculation models, the pump performance should not exceed the performance of the water heater. If the water heater is capable of delivering 10 litres per minute to the DHW circuit, then the maximum pump performance will be 10*60=600 L/h. The basic formula for calculating the performance of a heating system takes into account the power of the heater and the temperature difference at the inlet and outlet, and for the cold water system — the number of points of water intake. More detailed information about the calculations for each application can be found in special sources, and it is better to entrust the calculations themselves to professionals.

Max. head

The head can be described as the maximum height to which a pump can lift liquid through a vertical pipe without bending or branching. This parameter is directly related to the pressure that the pump produces: 10 m of head approximately corresponds to a pressure of 1 bar (do not confuse this parameter with operating pressure — see more about it below).

The head is one of the key specs for most circulation pumps. Traditionally, it is calculated based on the difference in height between the location of the pump and the highest point of the system; however, this principle is relevant only for units that boost the pressure of cold water(see "Suitable for"). Circulation pumps for heating and DHW work with closed circuits, and the optimal pressure depends on the total hydraulic resistance of the system. Detailed calculation formulas for the first and second cases can be found in special sources.

Max. fluid temperature

The highest liquid temperature that the pump is capable of operating normally.

The possibility of using the unit directly depends on this parameter (see "Suitable for"): for example, models for heating systems must tolerate a temperature of at least 95 °C, and for DHW supply — at least 65 °C. Well, anyway, this parameter should not be exceeded: an overheated pump will fail very quickly, and the consequences of this can be very unpleasant.

Features

— Number of speeds. The number of speeds provided in the design of the pump. Each speed corresponds to its performance value (see above). The options could be:
  • 1 speed. There are no adjustments in such models; when turned on, the pump can operate only at one speed. This is the simplest and most inexpensive option, due to the absence of additional elements (regulators) in the design. Of course, it is convenient only in cases where the unit must operate at full capacity every time it is turned on.
  • 2 speeds. 2 speeds give the user some degree of choice: the pump does not have to be turned on at full power — when it is not required, the unit can be run at reduced power to save electricity and not wear out the mechanisms beyond what is necessary.
  • 3 speeds. The largest number of adjustments found in modern pumps — it makes no sense to provide a larger number for many reasons. It gives even more options for setting operation parameters than 2 speeds.
  • Stepless adjustment. This option implies the ability to set the regulator to any position from minimum to maximum (in some models, fixed settings may also be provided, but only as an additional option). It provides maximum freedom and precision in the choice of operating mode. However, it significantly affects the price; and the real need for smooth adjustment occurs quite rarely.
Automatic operating mode.... The essence of this function differs depending on the purpose of the device (see above). So, in models for increasing the pressure of cold water, the automation turns on the pump when the tap is opened and turns it off when it is closed — a special sensor reacts to the movement of water. In models for heating and domestic hot water, automation is responsible for adjusting the operating parameters — for example, when screwing the valves and reducing the flow rate, the pump can reduce the pressure, as well as, for additional functions, such as an on-off timer. Anyway, this feature makes life easier for the user, eliminating the need to perform certain operations manually and adding new features to the pump; but the specific set of these features depends on the model.

Display. Various additional information can be displayed on the display: operating mode, performance settings, water temperature, set timers, error messages and much more. It makes management more convenient and intuitive. Pumps usually use the simplest form of black and white LCD screens, but this is quite sufficient for the purposes mentioned.

Control panel. In this case, the control panel means a panel that has a switch with a choice of operating modes between automatic (see above) and manual. Accordingly, the presence of several modes almost necessarily means the presence of a control panel. But the speed switches themselves are not considered for this function.

Impeller material

It is the material from which the impeller is made. It is the main part of the pump, which provides pressure due to movement.

Plastic. This material is inexpensive in itself, and it is easy to process, due to which it is distinguished by low cost. In addition, plastic is not subject to corrosion. On the other hand, it is considered the least reliable of all materials used in modern pumps and, therefore, is used in relatively inexpensive models that are not designed for serious loads. The exception to this rule are special high-strength polymers but they are rare.

Stainless steel. As the name suggests, stainless steel is virtually corrosion-resistant. However, this is not its only advantage — this material is very durable and reliable, and due to this, it is used even in powerful high-performance models.

Cast iron. This material is in many ways similar to steel — in particular, it is considered very reliable — but it has a slightly higher weight. On the other hand, in most cases, this is not a noticeable drawback, but cast iron costs a little cheaper than stainless steel.

Brass. An alloy based on copper and zinc which has a golden colour. The varieties used in circulation pumps are highly resistant to corrosion, they surpass even stainless steel. Therefore, this option is well suited for...water with a high oxygen content. The disadvantage of brass can be called a rather high cost.

Protection class

It is an indicator that determines the degree of protection of dangerous (moving and current-carrying) parts of the hardware of the pump from adverse effects, namely solid objects and water. Since pumps, by definition, are used for pumping liquids, and many of them can normally pass quite large particles, in this case, we are talking about protection against moisture and objects from outside.

The level of protection is usually indicated by a marking of the letters IP ("ingress protection") and two numbers, the first of which indicates protection against the effects of solid objects, and the second — against the ingress of water.

For the first digit, each value corresponds to the following protection values: 1 — protection against objects with a diameter of more than 50 mm (large body surfaces) 2 — against objects with a diameter of more than 12.5 mm (fingers, etc.) 3 — against objects more than 2.5 mm (most tools) 4 — against objects larger than 1 mm (virtually all tools, most wires) 5 — dust-proof (total protection against contact; the dust can enter, but does not affect the operation of the device) 6 — dust-proof (case with full dust protection and contact).

For the second digit: 1 — protection against vertically falling drops of water 2 — against drops of water with a deviation of up to 15 ° from the vertical axis of the device 3 — against drops of water with a deviation of up to 60 ° from the vertical axis of the device (rain) 4 — again...st splashes from any direction 5 — from jets from any direction 6 — from sea waves or strong water jets 7 — short-term immersion to a depth of up to 1 m (without the possibility of continuous operation in immersed mode) 8 — long-term immersion to a depth of more than 1 m (with the possibility of permanent operation) in immersed mode).

In some cases, one of the numbers may be replaced by the letter X — this means that the official certification for the corresponding parameter has not been carried out. In pumps, X is usually put in place of the first digit, because a high degree of moisture resistance in itself means a high degree of protection against solid contaminants. At the same time, for such models, an additional letter index can be provided, which describes the degree of protection against specific solid objects — for example, IPX2D. The letter D corresponds to the highest degree of stability, which does not allow the wire to be hit; the previous options A, B and C respectively mean protection from the hand, from the finger and a small tool like a screwdriver.

Insulation class

The heat resistance class of the insulating materials used in the construction of the pump. The higher the heat resistance — the more reliable the device, the less likely it is to ignite or break the insulation in case of overload or overheating. In addition, powerful performant units can become very hot even in normal operations.

In modern pumps, mainly the following classes of insulation are found:

— B. Materials with a heating limit of 130 °C. They are the most modest option by the standards of pumps. Use binding and impregnating compositions of organic origin.

— F. For this class, the heating limit is 155 °C — the average for pumps. Such insulation uses mainly synthetic binders.

— H. Insulating materials based on organosilicon binders/impregnators. Due to this, their heat resistance reaches 180 °C.
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