Comparison Termia AO EVO 24.0/1.3 TP vs Ballu BHP-15.000

The highest heating power produced by an industrial heater.

The maximum area that the unit can effectively heat directly depends on this parameter (see below). Even if it is not indicated in the specs, it can be approximately determined from the calculation that for heating 1 m² of a room with a standard ceiling height of 2.5 m and good thermal insulation will require 100 W of thermal power. If the ceiling height is significantly different, then the power required for heating can already be withdrawn from the volume of the room — every 2.5 cubic metres of volume will require the same 100 W (and the volume is found by multiplying the area by the height of the ceiling). There are also more complex formulas for the most accurate calculation, taking into account the degree of thermal insulation, the temperature difference between inside and outside the room, etc.; they can be found in special sources.

Note that in electric models (see "Power supply"), the maximum thermal power, in addition to all of the above, also determines the total power consumption of the unit: the power consumption (see below) cannot be less than the thermal output (usually, it is somewhat higher due to for the removal of part of the energy for the operation of the fan). In devices with a water circuit, the actual thermal output depends on the temperature of the coolant at the inlet and outlet. Therefore, in the characteristics, a certain standard value is usually indicated, and in t...he notes, it is specified for which temperatures it is relevant (for example, 90 ° / 70 °).

The largest area of the room that the industrial heater can effectively heat.

When determining the maximum area, usually, a universal formula is used that is valid for all heaters: 1 m² of floor space in a room with a standard ceiling height of 2.5 m requires 100 W of thermal power. Therefore, if the ceiling height differs markedly from this value, the actual heating area should be recalculated; for more details on scaling, see “Maximum thermal output".

This parameter describes the difference between the air temperature at the inlet to the heater and the outlet temperature — in other words, by how many degrees the air temperature rises when passing through the unit. The higher ΔT, the hotter the outgoing air will be and the more attentively it is necessary to observe safety measures (do not place the device near flammable and heat-sensitive materials, prevent people from being in the immediate vicinity of the gun exit, etc.).

The current consumed by the heat gun during normal operation. This parameter is useful primarily for assessing the load on the mains that occurs during the operation of the unit and organizing the appropriate connection. In particular, the rated current of the fuse installed in the connection circuit cannot be lower than the total rated current of the connected load — otherwise, the power will be turned off. Heat guns (primarily electric, see "Power supply") are quite high consumption consumers in terms of current.

The power consumed by the electrical components of the industrial heater during operation.

This parameter allows, first of all, to assess the load on the power grid and the suitability of the available power for the normal operation of the unit. It is relevant for all types of modern industrial heaters (see "Power supply"). However, it is worth noting that in some electric models, the power consumption is indicated for the ventilation mode. In this mode, the heating element is not activated, and the power consumption is extremely low — a few tens of watts. In such cases, the total power can be estimated from the maximum thermal output (see above) — in electrical models, these parameters practically do not differ from each other.

The maximum amount of air that an industrial heater can pass through itself in a certain time.

This parameter is associated with an increase in air temperature (see above): at constant power, higher performance usually corresponds to a smaller temperature difference. Accordingly, a more efficient industrial heater will heat the entire volume of the room faster, but the heating temperature will be lower. So, it is worth choosing according to this parameter, taking into account what is more important for you — a large temperature difference or a high heating rate.

The longest time during which the industrial heater can work without interruption.

The value of this parameter depends on the power supply (see above). So, in diesel models, the operating time is usually indicated on one full tank, without refuelling. Note that this implies operation at the lowest power, with minimal fuel consumption, and in optimal environmental conditions. Therefore, when choosing a diesel heat gun for this parameter, it is worth taking a certain margin, or better, separately calculating the operating time at the highest fuel consumption: for this, the volume of the tank (see above) must be divided by the maximum consumption. If we are talking about a gas or electric model, then the maximum operating time usually means the time during which the unit can work without overheating.

Regardless of the type, the long maximum run time provides additional convenience when working with an industrial heater. At the same time, it does not always make sense to pursue the maximum value of this parameter: in fact, the need for continuous heating for a long time occurs quite rarely. In addition, many diesel models allow refuelling right during operation (and in others, the refueling break usually does not exceed a few minutes). Therefore, it is worth specifically looking for a heat gun with a long time of continuous operation only if such a feature is fundamentally important to you.

An indicator that determines the degree of protection of dangerous (moving and current-carrying) parts of an industrial heater from adverse effects, namely solid objects and water. 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 — from objects with a diameter of more than 12.5 mm (fingers, etc.)
3 — from objects larger than 2.5 mm (most instruments)
4 — from objects more than 1 mm (almost all tools, most wires)
5 — dustproof (full protection against contact; dust can penetrate inside, but does not affect the operation of the device)
6 — dust tight (case with full protection against dust and contact).

For the second digit:
0 — completely unsuitable for contact with water, the device requires protection from moisture and is not suitable for rooms with high humidity.
1 — protection against vertically falling drops of water
2 — from water drops with a deviation of up to 15 ° from the vertical axis of the device
3 — from water drops with a deviation of up to 60 ° from the vertical axis of the device (rain)
4 — against splashes from any...direction 5 — against jets from any direction
6 — from sea waves or strong water jets
7 — the possibility of short-term immersion to a depth of 1 m (without the possibility of continuous operation in immersed mode)
8 — the possibility of long-term immersion to a depth of more than 1 m (with the possibility of continuous operation in immersed mode).

The protection class of industrial heaters, usually, is quite low, because the very principle of operation of these devices involves an abundance of holes and openings.