FR3005720A1 - HIGH EFFICIENCY ELECTRIC HEATING AND HEAVY THERMAL INERTIA - Google Patents

Abstract

The invention relates to an energy-efficient heating system with a high heat output as soon as it is put into service and with thermal inertia, equipped with an anti-dust system. It consists of a motor-turbine unit that draws ambient air through a dust filter located in the lower part of the radiator, then compresses it and propels it on a resistance-dissipator group, thus improving heat exchange. The compressed hot air then flows through rough mineral particles in the upper part of the radiator. This step causes, by friction of the air, the increase of the rise in temperature as well as a thermal inertia due to the heat stored in the mineral particles. As soon as it is put into operation, this heating device provides a much higher heat output than any existing heating system on the market, with a very fast increase in power. To heat the same volume, the resistance works much less and allows to achieve very high energy savings while ensuring real comfort.

Description

The present invention relates to an electric heating system, individual or collective energy-efficient, high heat output from its commissioning, thermal inertia and further provided with an anti-dust system.

The existing radiators heat very quickly but are energy-consuming, without any heat restitution related to inertia (convectors, blowers, radiants), or benefit from thermal inertia but with a poor performance when they rise in temperature (cast iron radiators, aluminum, oil baths, boiler radiators). The device according to the invention allows the optimization of the heat transfer between the electrical resistance and the air. It comprises a principle of heating by friction of the air through rough mineral particles. These same particles have a role of thermal inertia. The device includes a filtration of dust and pollen. In the lower part of the radiator, the air is sucked through a pollen filter by a motor-turbine that propels compressed air on the resistor and its dissipator. The fact that the air is compressed in contact with the resistor-sink assembly improves the heat exchange. The compressed hot air then flows through rough mineral particles in its upper part. This step causes, by friction of the air, the increase of the rise in temperature as well as a thermal inertia due to the heat stored in the mineral particles.

20 We then obtain a heating system which, as soon as it is put into operation, provides a much higher heat output than that of all the existing heaters on the market, with a very fast optimal rise in power. To heat the same volume, the resistance works much less time and allows to achieve very high energy savings while ensuring real comfort by feeling soft heat, fast 25 and not suffocating. Filtration of dust and pollen prevents clogging of minerals and blackening of the wall on which the radiator is placed (as can be seen above the convectors). The accompanying drawings illustrate the invention: FIG. 1 represents in section the device of the invention for individual heating.

Figure 2 shows in section the principle on a collective heating. Figure 3 shows the principle of suction and distribution of compressed air and filtered for collective heating. With reference to drawing 1, the device comprises a management box provided with a thermostat (10). If the temperature of the room is lower than that desired on our thermostat, the control unit controls the energizing of the motor-turbine unit (2), as well as the resistor (5). The ambient air is sucked in and filtered through a filter (1). The turbine engine (2) compresses the air in a pipe (3) which itself diffuses the compressed air in contact with the resistance-dissipator assembly (5). The compressed hot air is directed towards the rough mineral particles (7) retained by a holding grid (6). The passage of compressed hot air into the mineral particles (7) causes a friction effect on the air and therefore a new rise in temperature. The rough mineral particles (7) accumulate the calories causing a thermal inertia effect. Compressed hot air is naturally directed to the outlet (9), passing through the upper grate (8) to diffuse the calories into the room to be heated. With reference to drawing 2 (collective heating version), a device located in a technical room supplies the (the) radiator (s) with compressed air and filtered. Compared with drawing 1, the filter, the turbine engine and the tubing are replaced by a simple air inlet on the bottom of the radiator controlled by a solenoid valve (11). The air heating remains identical to drawing 1. With reference to drawing 3, we have a sectional diagram of the suction and distribution points of the compressed air, as well as the principle of management of the flow rate. air on the whole of an office building for example. The air treatment, ie suction, compression and filtration, is carried out in a technical room (19). legend figure 1 1 Anti-dust and anti-pollen filter 2 Engine-turbine group 3 Compressed air circulation manifold 4 Air flow distribution grid Electrical heater-dissipator group 6 Particulate support grid 7 Rough mineral particles 8 Particle holding grid 9 Hot air outlet deflector Control box of the motor-turbine unit, the resistance, and the electrical connection thermostat in the A area Air compression zone legend figure 2 11 Solenoid valve Compressed air supply 12 Compressed air distribution grid 13 Motor-turbine group 14 Particle holding grid 15 Rough mineral particles 16 Particle holding grid 17 Hot air outlet 18 Solenoid valve control unit air supply, resistance, thermostat and electrical connection to A compressed air zone legend figure 3 19 Technical room: suction and flow unit compressed air supply with filters 20 Ambient air inlet 21 Compressed air heating supply 22 Compressed air supply line 23 Ambient air suction line

Claims (2)

CLAIMS1) Electric heating device, individual or collective, energy-efficient, high heat output as soon as it is put into service and with high thermal inertia, provided with an anti-dust system, characterized in that the ambient air is sucked and filtered through a filter (1) by a turbine engine (2) which compresses the air in a manifold (3) which itself diffuses the compressed air in contact with the resistance-dissipator assembly (5). ) through an air flow distribution grid (4). The compressed hot air then moves to the rough mineral particles (7). The passage of compressed hot air into the mineral particles causes a friction effect on the air and therefore a new rise in temperature. The mineral particles (7) accumulate the calories causing a thermal inertia effect. 2) Heating device according to claim 1 characterized in that rough inorganic particles are integrated between two holding grid (6) and (8) in order to obtain a friction of the compressed air generating a new rise in temperature and a thermal inertia accumulation for optimal output at the air outlet (9).