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Comparison PowerWalker AVR 3000 SIV FR 3 kVA / 2400 W vs Volt Polska AVR-3000VA 3 kVA

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PowerWalker AVR 3000 SIV FR 3 kVA / 2400 W
Volt Polska AVR-3000VA 3 kVA
PowerWalker AVR 3000 SIV FR 3 kVA / 2400 WVolt Polska AVR-3000VA 3 kVA
from £132.19 
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AVR typerelayrelay
Input voltage230V (1 phase)230V (1 phase)
Power2400 W
Power3 kVA3 kVA
Specs
Input voltage range110 – 280 V150 – 270 V
Output voltage accuracy (±)10 %8 %
Efficiency95 %
Voltmeterdigitaldigital
Sockets
Grounded sockets12
Computer sockets1
Terminal connection
Protection levels
Protection
overheating
high frequency interference
short circuit
overload
over / under voltage
overheating
 
short circuit
overload
over / under voltage
General
Installation
floor
floor
Coolingpassiveactive
IP protection rating20
Carrying handle
Dimensions297x150x199 mm203x182x297 mm
Weight8.6 kg6.2 kg
Added to E-Catalogoctober 2022may 2022

Power

The maximum active load power allowed for this model.

Active power is the power that in AC appliances is spent on useful work or on heat generation. In addition to it, such devices also consume reactive power — it goes to the operation of specific components, primarily capacitors and inductors. Apparent power, denoted in volt-amperes (kilovolt-amperes), is the sum of active and reactive, see below about it. Here we note that in simple everyday situations, there is enough data on active power indicated in watts for calculations. In particular, it is this parameter that is considered the key when choosing stabilizers for washing machines and dishwashers : in the first case, power from 2 to 5 kW is considered optimal, in the second — from 1.8 to 2.5 kW.

Anyway, the total active power of the connected load should not exceed the figures indicated in the characteristics of the stabilizer. For a full guarantee, it's ok to take a certain margin, but this margin should not be too large — an increase in the allowable power significantly affects the dimensions, weight and price of the device. Also note that there are formulas that allow you to convert the active power consumption into total power, taking into account the type of connected electrical appliance; these formulas can be found in special sources.

Input voltage range

The voltage range at the input of the stabilizer, at which it is able to operate in normal mode and supply a constant voltage of 230 or 400 V to the load (depending on the number of phases, see above). The wider this range — the more versatile the device, the more serious power surges it can extinguish without going beyond the standard operating parameters. However, note that this parameter is not the only, and not even far from the main indicator of the quality of work: a lot also depends on the accuracy of the output voltage and the response speed (see both points below).

Also note that some models may have several modes of operation (for example, with 230 V, 230 V or 240 V output). In this case, the characteristics indicate the "general" input voltage range, from the smallest minimum to the largest maximum; the actual ranges for each particular mode will vary.

In addition, there are stabilizers that can operate outside the nominal input voltage range: with a slight deviation beyond its limits, the device provides relatively safe output indicators (also with some deviations from the nominal 230 or 400 V), but if the drop or rise becomes critical, it works appropriate protection (see below).

Output voltage accuracy (±)

The largest deviation from the nominal output voltage (230 V or 400 V, depending on the number of phases), which the regulator allows when operating in the normal input voltage range (see above). The smaller this deviation, the more efficiently the device works, the more accurately it adapts to “changes in the situation” and the less voltage fluctuations the connected load is exposed to.

When choosing for this parameter, it is worth considering first of all how demanding the connected devices are for voltage stability. On the one hand, high stability is good for any device, on the other hand, it usually means a high price. Accordingly, it usually does not make sense to buy an advanced stabilizer for an unpretentious load like light bulbs and heaters, but for sensitive devices like audio systems or computers, it can be very useful.

Efficiency

The efficiency of the stabilizer is the ratio, expressed as a percentage, between the amount of electricity at the output of the device to the amount of energy at the input. In other words, efficiency describes how much of the energy received from the network the device transfers to the connected load without loss. And losses during operation will be inevitable — firstly, not a single transformer is perfect, and secondly, the control circuits of the stabilizer also require a certain amount of energy to work. At the same time, all these costs are quite small, and even in relatively simple modern models, the efficiency can reach 97-98%.

Grounded sockets

The number of sockets for 230 V with grounding provided in the design of the stabilizer.

Some electrical appliances, such as refrigerators and washing/dishwashers, must be grounded when connected. This point should not be ignored — there is a risk of a serious electric shock. Accordingly, the number of sockets with grounding corresponds to the maximum number of such devices that can be simultaneously connected to the stabilizer without the use of splitters. At the same time, ungrounded devices can also be connected to such sockets.

Computer sockets

The number of sockets in the stabilizer design that use the IEC 320 C13 plug. This connector has a pentagonal shape (resembles a rectangle with two cut corners), and it has three contacts. It is used in various types of modern electronics, but it is most widely used in computer technology — which led to the name. Physically, IEC 320 C13 is not compatible with conventional 230V plugs, however adapter cables are available.

Terminal connection

The presence in the design of the stabilizer of at least two pairs of terminals — at the input and at the output. Unlike sockets, which are designed for frequent connections and disconnections, the terminal connection is designed to permanently secure the wires — roughly speaking, "attached — clamped — forgot." It does not involve direct connection of electrical appliances, usually the power from the terminals goes further into the mains and is already distributed through it to individual sockets in the room. Accordingly, this option is typical for powerful models (on average from 3 kVA and above, see "Power"), which are designed for installation in one place as a permanent element of the power grid. Often such stabilizers do not have their own outlets at all — only terminals.

Protection

- From overheating. Protection that prevents the critical temperature rise of individual components of the stabilizer - for example, in case of overload, short circuit or failure in the cooling system. When a certain temperature value is exceeded, it turns off the device in order to avoid breakdowns and fires. Such systems are especially important for semiconductor types of stabilizers - thyristor and triac(see above). And in some models, this function can be supplemented by a temperature increase signal - it works at a temperature close to critical.

- From high-frequency interference. This protection dampens incoming high-frequency interference, preventing them from affecting the operation of devices connected to the stabilizer. Such interference can occur, for example, from electric motors, welding machines, etc. So, in audio systems, high-frequency distortion causes an unpleasant background from the speakers. RFI protection filters out these distortions, providing a smooth sine wave output.

- Against short circuit. A system that protects the stabilizer in the event of short circuits in the connected load. A short circuit is a situation when the resistance in the circuit becomes close to zero; this leads to a sharp increase in current strength, overloads the power grid and the stabilizer itself, and also creates a ri...sk of breakdown or even fire. In order to avoid unpleasant consequences, appropriate protection is provided: it disconnects the load in case of a significant excess of the current in it. This feature is almost mandatory in modern stabilizers.

- From overload. Safety system in case of stabilizer overload - that is, a situation when the total power of the connected load becomes greater than the corresponding indicators of the device itself (see "Power"). The reason for this situation may be, for example, the inclusion of an additional consumer or a change in the operating mode of one of the existing ones. Unlike the short circuit described above, when overloaded, all electrical appliances work normally, the stabilizer itself is abnormal, which can lead to its failure or even fire. To avoid this, overload protection is applied. Its specific implementation may be different. In some models, the load is turned off immediately, in others - after a certain time after the warning signal, which gives the user the opportunity to reduce power consumption and avoid system tripping.

- From over / under voltage. A system that protects the device from too low or too high input voltage. A significant overshoot of the input voltage range (see above) is dangerous not only by the risk of damage to the stabilizer itself: under such conditions, the device’s capabilities are not enough to fully protect the connected load, which can result in trouble for it. And this function prevents such consequences: if the input voltage goes beyond the permissible values (they may be wider than the operating values, see “Input voltage range”), the stabilizer is disconnected from the network. At the same time, some of its functions may remain operational - for example, a voltmeter that allows you to assess the "state of affairs" in the network at the input. And in some models there is a function to automatically turn on when the voltage returns to operating limits.

Cooling

The method of heat removal from the heating elements of the stabilizer.

— Passive. Passive cooling is any type of cooling that does not provide forced heat removal and is carried out only due to natural heat transfer and convection. In low-power stabilizers of this type, the cooling system as such may be completely absent — the amount of heat generated is relatively small, and the natural thermal conductivity of the case and the parts themselves is quite enough to dissipate it into the environment. In more advanced models, radiators can be installed. The main advantage of any passive cooling is the complete absence of noise. In addition, such systems are inexpensive, do not consume energy, take up relatively little space and are very reliable — there is simply nothing to break there, in most cases. On the other hand, they are significantly inferior to active cooling in terms of efficiency, and therefore are poorly suited for powerful devices, especially thyristor and triac (see "Type").

— Active. Active cooling involves the forced removal of heat from the components of the device. This is usually done by combining heatsinks with fans that "blow" excess heat out of the case. Such systems have extremely high efficiency, they can be used in stabilizers of any power, and for semiconductor models (see "Type") active cooling is simply irreplaceable. However, the cost of this efficiency is a high noise level, as well as significant dimensions and weight, which ac...cordingly affect the entire device. Fans tend to draw dust into the case, so you need to monitor them and periodically clean the “hardware” of the stabilizer; and if the fan fails, all cooling, in fact, fails. In addition, the cost of such systems is significantly higher than that of passive ones.