FR2567706A1 - Method of heating by individual microwave radiator - Google Patents

Abstract

The invention relates to a device for heating living or other premises by individual microwave radiator whose energy source consists of UHF waves emitted by a magnetron supplied by an electric current. This device comprises: - two outer heating panels 2 provided with ducts 3 promoting thermal feedback of the air along its walls; - two pouches 8 consisting of thin leaves, resistant to high temperatures, which when welded together form a hermetic pouch containing a spongy fabric 9 hydrated with a small quantity of fluid. These heating pouches convey their heat very rapidly by conduction to the outer heating panels. Because of the small quantity of liquid employed, the microwaves are placed under optimal conditions of cost effectiveness, speed and economy. It is possible to incorporate a refractory block therein so as to store up heat at certain times.

Description

 The subject of the present invention, as a new industrial product, is a device relating to the heating of residential or other premises by an individual microwave radiator whose source of energy consists of high frequency electromagnetic waves (2450 megaetz). ) emitted by a magnetron powered by an electric current.

 In the devices known to date and marketed, the energy used for heating individual or central radiator is of different origin.

Electrically powered radiators typically use a spring or lamp type heater.

Some electric heaters are complemented by refractory blocks located around the resistors. Still others heat a liquid diffused inside the radiator by means of an armored, immersible resistance (the liquid being intended to retain and diffuse heat. It can consist of oil, water , possibly with additives such as gloter salt intended to create a greater heating inertia).

Still other processes of radiators use wood, sawdust, coal, gas, fuel oil, heavy oil, steam, air, etc.

The main drawbacks of these devices are either unpleasant and painful handling (wood, sawdust, charcoal) or bulky, posing storage problems (wood, coal, fuel oil or heavy oils), dangerous in certain cases ( gas) or very expensive requiring significant and costly thermal insulation of the spaces to be heated (convectors and radiators with electric resistances) not to mention central heating of the conventional type requiring a fairly heavy installation of piping to connect the entire radiator network to the central boiler.

 In addition to the complicated implementation of this type of heating, it is also necessary to underline the unsightly drawback of the piping, the heat losses and possible leaks at the connections.

Microwaves, on the other hand, are high frequency electromagnetic waves (2450 megahertz) close to those emitted by the shortest waves of radio or radars. These microwaves propagate like other electromagnetic waves, they pass through the air and are only stopped by the metal which reflects them.

They are emitted by a magnetron powered by electricity which converts electrical energy into electromagnetic energy. the microwaves emitted by the magnetron cause a change in orientation of the water molecules, which rotate on themselves by 1800 then return to their initial position and this 2450 million times per second.

These extremely rapid changes in orientation cause the molecules of water to rub together, causing the molecules to heat up and heat up.

Microwaves having the particularity of causing extremely rapid heating of liquids and of water in particular, this heating process will be, depending on the volume of water and the power of the magnetron, from 40 to 75% more economical than in any other. heating process, this therefore leads to a substantial saving in the cost price of heating.

 At present microwaves are known and used in the culinary industry with cooking ovens for foodstuffs and are also marketed as domestic ovens serving particularly for defrosting, cooking, reheating ready meals.

 It should be noted that the best heating coefficient for water or all hydrated materials via microwaves is between +10 centigrade and +800 centigrade, temperature precisely corresponding to the normal use of heaters. heating for housing or other purposes.

Example: at 0, that is to say the state of ice, the water practically does not absorb the energy supplied by the microwaves. The heating coefficient is therefore very small.

 However, when the ice melts, energy is suddenly absorbed in large quantities, the heating coefficient jumps forward, Figure 2.

This therefore means that concentrated heat develops at the first melting points, these heat up very quickly while other places remain frozen.

As the water temperature increases, the heating coefficient becomes smaller again, the speed of heating decreases as a result.

 By the use of a small quantity of water distributed along its walls, the microwave radiator exploits to the maximum the properties of rapidity of heating of the ultra-high-frequency waves emitted by the magnetron, it gives for minimum consumption, maximum yield, it is therefore very efficient in terms of speed and energy savings; compact and of a classic central heating radiator size, it is simple, silent and clean to operate and does not need a complicated implementation, it can be installed simply by plugging into a socket ordinary current (110 or 220 volts conventional at 50 hertz) currently distributed in all dwellings, industrial or commercial premises.

The microwave radiator is therefore for the reasons stated above
A means of heating more efficient than any other type known to date in regions with a temperate climate, because it can adapt directly to all kinds of dwellings without any transformation of existing installations and without any particular insulation of premises.

 An embodiment of the invention is described below by way of indication and in no way limiting, with reference to the accompanying drawings.

Figure 1: is an external overview of the microwave radiator, as it appears to the user.

Figure 2: is a curve of the coefficient of water heating by microwaves.

Figure 3: is a view of the various sheet metal elements constituting the skeleton of the microwave radiator.

Figure 4: is a view showing the location of the various electrical and electronic elements of the microwave radiator.

Figure 5: is a vertical sectional view of the radiator at the magnetron.

Figure 6: is a view of the heating bag containing the hydrated sponge tissue.

Figure 7: is the electrical diagram with its different components.

The device which is the subject of the invention comprises a metal supporting skeleton, comprising
A frame or central core 1 serving for the rigidity of the assembly and which supports the various electronic and electrical elements on its lower part FIGS. 3 and 4 and the various sheet metal elements. Two external heating panels 2 comprising hollow sleeves 3 which will be used for the physical reaction of the hot air, and which will create thermal circulation by effect of chimneys. These panels are fixed on the element 1 (central frame) by metal profiles in the form of clamps 4 clipping to fix the assembly, and give it its rigidity. A cover 5 in the form of a bowl which constitutes the very base of the radiator and serves as a box for hiding all of the various electrical and electronic elements.

 A casing 6 fits onto the assembly in order to complete the aesthetics, to improve the soundproofing and to prevent any microwave leaks outside the radiator.

All of this bodywork can be made of metal, cast iron, various alloys, stainless steel, brass, copper, aluminum or cast aluminum, but absolutely all materials permeable to micro- waves, such as: plastic, glass, wood, earthenware and their derivatives.

Inside the radiator an expanded foam 7 of polyester, polyurethane, possibly glass wool or other type has three effects
It allows on the one hand to keep pressed against the heating walls 2 the heating bags 8 containing a spongy hydrated tissue 9 so that these heating bags are pressed along the heating walls 2 in order to impart heat to them uniformly by conduction.

 It also makes it possible to reverberate the heat towards the outside and avoid the creation inside the radiator of a micro-climate at high temperature, which would cause a loss of efficiency.

 Finally, it contributes by its anti-vibration effect to the sound insulation of the entire device.

The heating bags 8 consist of two thin but resistant sheets of polypropylene 10 connected to each other at a distance of about 1.5 cm from their outer edge by a sealed thermal weld thus constituting an airtight pocket containing a spongy hydrated tissue 9 d '' about 1 cm thick (possibly more). This heating pocket is perfectly airtight, the hydration of the spongy tissue will remain permanently constant.

The spongy tissue 9 which can be replaced by any material permeable to microwaves consists of micro-capillary vessels having the effect of a homogeneous distribution of a small amount of water in a maximum of volume and surface along the external heating wall 2 which will be heated by direct conduction between the heating pocket 8 and the heating panel 2.

Regarding the electrical and electronic part, it is fixed to the bottom of the central metal frame 1 which serves as a plate and comprises
A magnetron 11 whose power can vary according to the use and the format of the radiator used, but which on average will be from 500 to 700 watts (it is advisable beyond 700 watts to add the powers by adding another magnetron ).

 A transformer 12 makes it possible to transform the electric current 220 volts or other 50 HZ into high voltage current which can go from 2330 volts to 3000 volts, voltage necessary for the operation of the magnetron.

 A capacitor 13, an iodine bridge 14, a ventilation 15 allowing the continuous cooling of the magnetron, in fact to operate in good conditions a magnetron must not exceed a temperature of 350 centigrade, a two-blade thermostat cut-out is also generally integrated into the magnetron. A circuit breaker fuse connected directly to the external heating panel 2 having the effect of cutting off the power supply when the temperature of the heating panels exceeds 600 centigrade, in accordance with the laws in force or any other temperature chosen arbitrarily.

 A circuit breaker room thermostat 18 can be adapted to the radiator in order to be able to precisely adjust the average heating temperature.

On the other hand, one of the peculiarities of the heating effect formed by the friction of the water molecules with each other is that this molecular disorganization does not stop completely until one or two minutes after the emission of the micro is cut off. -waves.

 To save energy, it is therefore advisable to provide a timer having the effect of operating the radiator for one minute, then switching it off for one minute, then operating it again for one minute, and so on until the appliance has reaches the desired temperature. The cycle thus established will allow a substantial saving of energy, it will be able to be regulated on a different time according to the needs and the use. It is the only form of heating that continues to increase in temperature when it is turned off, resulting in real heating inertia that consumes no energy and requires none to cause it.

 The various elements making up the electrical and electronic part of the individual microwave radiator being already known and industrialized, it is not necessary to make a further designation here.

 One of the particular adaptations of the microwave radiator consists in replacing the foam 7 as well as the heating bags 8 and their contents 9 by a complete block of waterproof refractory material constituted inside a multitude of microscopic capillary vessels retaining a rate of very low humidity throughout the block.

This particular interpretation of the present invention makes it possible to store within this refractory block a large amount of heat during a distribution period (E.D.F) off-peak hours (reduced tariffs) in order to gradually restore it during the full tariff period.

 On the other hand the individual microwave radiator containing almost necessarily a ventilation 15 serving to cool the magnetron 11, it is possible to improve its efficiency by channeling to the outside under the sleeves 3 the excess air, to the using a ramp pierced with small holes, in order to speed up the drawing of the external chimneys 3 and to facilitate the rapid creation of a thermal bridge.

To obtain better sound insulation, it is advisable to stick on the inner part of the cover 5 as well as on the inner part of the casing 6 and on the outer part of the central frame 1 a material based on lead and tar having an anti effect -vibratory this can also be supplemented by a thickness of polyurethane foam with open cells and filled with one or more particles or sheets of lead this in order to perfect the important sound insulation for this kind of device.

 It is also possible to replace the heating bags 8 and their hydrated spongy tissue 9 with a layer of fluid or gas (in compact or vaporized mass) maintained along the walls by a plate or by pipes made of material permeable to micro- waves.

In order to improve the efficiency and the distribution of the electromagnetic waves in the enclosure of the radiator it is possible to use a metallic shell of parabolic or conical shape located around the antenna of emission of the magnetron and which would concentrate the microwaves and would give them a much higher power and profitability. The angle of the shell will be more or less open depending on the use and the desired effect.

 One use of the present method may consist in employing the high temperature micro-climate which is created inside the enclosure.

In this case, it suffices to remove the foam block 7, to replace it with two rigid polypropylene or other plates, placed so as to keep the heating pockets 8 and their spongy tissue 9 pressed against the walls 2. The volume d the air replacing the foam 7 will then rise in temperature; this superheated air can then, via shutters located in the metal frame of the radiator, be diffused into the room to be heated and thus improve the efficiency of the device. It is important that wire cloths are placed in front of the enclosure shutters to avoid microwave leakage.

 It is understood that the present invention is not limited to the embodiments described and represented, which constitute examples to which numerous modifications can be made without departing from the present invention.

 The device which is the subject of the invention can be used as permanent and permanent heating of residential, commercial, industrial or other premises.

Thanks to its individuality and ease of transport, it can also be used as an auxiliary heater without any inconvenience.

In all cases to replace conventional and traditional heaters for new buildings, this mode of heating is particularly interesting with regard to the heating equipment of old buildings. It requires no special equipment and no transformation. Its ease of implementation avoids any piercing of walls and the passage of unsightly pipes. It can be adapted to pavilions and individual houses as well as collective buildings.

This type of heating, thanks to its very low electrical consumption in proportion to its output, requires no particular insulation or special layout of the premises and remains, in any case, competitive and particularly economical.

Claims (18)

 1- Device relating to an individual radiator for heating residential premises or the like, characterized in that it comprises in its upper part a radiant and convective heating body constituted by a sealed enclosure with UHF electromagnetic waves (2450 Megahertz) and in its lower part a foot containing the various electrical and electronic elements useful for UHF emissions  2- Device according to claim 1 characterized in that it is the emission of U.H.F waves which serves as energy to cause the heating of the radiator.  3- Device according to claim 1 characterized in that it uses a magnetron (11) to produce the microwaves useful for heating the liquid it contains.  4- Device according to claim 1 and 3 characterized in that the microwave radiator comprises heating pockets 8 so hot water bottles plated along its walls made of very thin sheets (10), permeable to microwaves, but strong enough to withstand high temperatures. These sheets are welded in a particularly hermetic manner to each other in order to form a definitely waterproof pocket.  5- Device according to claim 4 characterized in that the heating pockets (8) contain a spongy fabric (9) supporting high temperatures; or any other material, permeable to microwaves, comprising an infinity of capillary micro-vessels allowing a uniform distribution of a liquid, during heating, along the walls.  6- Device according to claim 5 characterized in that the heating pockets (8) thanks to their spongy fabric (9) can distribute in a maximum volume on a maximum surface, a minimum volume of liquid.  7- Device according to claims 1 and 6 characterized in that the radiator should contain only between 0.5 liters and 2 liters of water taking into account that the electromagnetic waves, which cause the disorganization of molecules, are not effective if the volume of water is very small.  8- Device according to claim 1 characterized in that the head of the magnetron (11) comes out directly into the enclosure.  9- Device according to claims 1 and 4 characterized in that a block of expanded foam (7) (or glass wool or any other thermal insulating product permeable to ultra high frequency waves) allows to hold regularly pressed along heating panels (2) heating pockets (8).  10- Device according to claim 2 characterized in that one can adapt a timer to the microwave radiator thus creating an alternative cycle of operation in a continuous heating progression. This is to use the natural inertia of microwave heating.  11- Device according to claims 4 and 9 characterized in that the heating pockets (8) pressed along the heating panels (2) directly transmit their heat by conduction.  12- Device according to claim 9 characterized in that the block of expanded foam (7) prevents the formation inside the radiator of a micro-climate at high temperature and forces the heat to diffuse outwards.  13- Device according to claims 1 and 9 characterized in that the block (7) and the heating bags (8) and their contents (9) can be replaced by a sealed refractory block containing a very low humidity rate allowing to accumulate a large quantity of heat at a reduced rate (off-peak hours) and to restore it during a full rate period.  14- Device according to claim 1 characterized in that it is possible, by means of recuperating ducts, to channel the air of the cooling ventilation of the magnetron to accelerate the thermal effect.  15- Device according to claims 1 and 11 charac risé by the fact that the outer heating panel (2) creates a reaction inside the sleeves (3) and causes thermal circulation by effect of chimneys (3).  16- Device according to claims 1, 4, 5, 6 and 7 characterized in that it is possible to replace the heating pockets (8) with a layer of fluid or gas, compact or vaporized, maintained along the outer heating wall (2).  17- Device according to claims 1 and 3 characterized in that by filling a metal shell of parabolic or conical shape around the magnetron transmitting antenna, the diffusion and the efficiency of the electro waves are significantly improved. magnetic.  18- Device according to claims 1, 4, 5, 6, 7 characterized in that by replacing the foam (7) by a volume of air heated by the pockets (8) and their spongy tissue (9) is obtained a high temperature micro-climate. The air thus heated can be diffused by means of shutters (protected by a metallic safety fabric) drilled in the wall of the radiator. This process helps provide superior efficiency by convection.