Connection
The method of connecting the auto-inverter to the on-board network or car battery.
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In the cigarette lighter. Connection to a standard car socket DC 12V; traditionally, the role of such an outlet is played by the cigarette lighter socket (hence the name), but many newer cars also have a separate socket. This option is the most convenient — after all, plugging the plug into the socket is much easier than pulling cables from the battery to the inverter installation site. On the other hand, it is only suitable for models with a rated output power (see below) up to 300 watts — high power creates extra loads on the on-board network and can lead to overheating and damage to the wiring.
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Crocodiles (to the battery). Connection directly to the battery using cables with alligator clips. By itself, a direct connection to the battery allows you to create quite powerful devices — the 300 W limit, typical for power from the cigarette lighter (see above), does not apply here. However, it is believed that alligator clips provide a less dense and reliable connection than cables (see below), and are less suitable for high currents. Therefore, the rated power of such inverters usually does not exceed 1500 W. On the other hand, such a connection is more convenient for quickly connecting and disconnecting the inverter.
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Cable (to the battery). Connection di
...rectly to the battery using cables with flat terminals, which are clamped into the battery terminals when connected. This design provides a tighter contact than the "crocodiles" described above, but is less convenient when connecting and disconnecting the inverter. It is typical for high power inverters.
— In the cigarette lighter / crocodiles. Universal models that allow connection both through the cigarette lighter socket and directly to the battery using crocodile clips. The technical features of both connection options are described above. Here we note that the rated output power of such inverters can exceed 300 W; in such cases, when operating from the cigarette lighter, care must be taken not to connect a load of more than 300 W to the device.Rated power output
The total power supplied by the autoinverter in normal operation. In other words, this parameter can be described as the
highest rated power of the connected load, at which the device is able to work without failures and overloads for a long time (comparable to the discharge time of the battery used for power).
Accordingly, when choosing according to the rated output power, it is worth proceeding from the energy consumption of the intended load. At the same time, it is worth choosing an inverter with a margin of 15-20% — for example, for a laptop with a consumption of 150 W, a device with at least 175 W is recommended. This is due not only to overload protection, but also to the fact that many inverters are able to deliver the claimed power only when the battery is fully charged, and as this charge is exhausted, it decreases.
It is also worth considering that some devices, such as car refrigerators or household vacuum cleaners, consume significantly more energy when starting up than during normal operation. Therefore, when choosing an inverter for such devices, it is worth focus not only on the rated, but also on the peak power — the power that the auto-inverter is capable of delivering without consequences within a few seconds.
Peak power output
The highest total power supply (peak) that the autoinverter can deliver to the load for a relatively short time is 2-3 s. Usually, this power is higher than the nominal one (see above) by 30-50%. At the same time, if you choose an inverter for maximum power, the same rules apply as for the nominal one — the device performance should be 15-20% higher than the total power of the connected load. And to work with devices that consume a large amount of energy at startup (vacuum cleaners, power tools, etc.), it is also worth specifying the peak power of the inverter — it should not be lower than the "starting" load power.
Efficiency
Efficiency of the autoinverter.
Efficiency is the ratio (in percent) between the amount of energy that the device delivers to the load and the amount that it consumes from the vehicle's on-board network. Accordingly, the higher this indicator, the more efficient the work and the less loss during conversion. In fact, this means that, other things being equal, a device with a higher efficiency will allow the load to run longer on battery power; this is especially important at high power consumption.
In modern auto inverters, efficiency values of 80 – 85% are considered average, 90% or more are good.
Number of sockets
The number of standard sockets for 230 V provided in the design of the auto-inverter.
The more outlets, the more electrical appliances can be connected to the inverter at the same time. At the same time, the specifics of using automotive converters is such that they rarely have to be used for several devices at once. In addition, simultaneous connection requires appropriate power (see "Rated output power"), and the sockets themselves also significantly affect the dimensions. Therefore, most often in modern models
one outlet is used — this, usually, is enough. However, high-end powerful inverters can have
two outlets.
Cable length
The length of the connecting cable included with the autoinverter. The longer the cable, the farther from the connection point you can install the device; this is especially important for models designed to work directly from the battery (see "Connection").
Operating temperature
The range of ambient air temperatures in which the car inverter is guaranteed to maintain normal performance. It is necessary to focus here on the expected minimums and maximums
of operating temperatures. For example, if in a harsh winter the thermometer readings do not fall below -15 ° C, then the devices from the “-20 ° C and below” item for such operating conditions will be enough with a margin.
Dimensions
General dimensions of the autoinverter.
In modern cars (especially passenger cars), usually, there is not much space for installing additional equipment. This parameter allows you to estimate the space required to place the inverter, make sure that the selected device fits into the “footprint”, and, if necessary, choose another location or another model. At the same time, it must be remembered that for many auto-inverters a certain margin is needed in place — for the normal operation of the cooling system; this margin is usually specified in the detailed documentation.