EP0127619A1

EP0127619A1 - Heating device

Info

Publication number: EP0127619A1
Application number: EP19830900275
Authority: EP
Inventors: Alexandre Radulescu
Original assignee: Individual
Current assignee: Individual
Priority date: 1982-12-01
Filing date: 1983-01-07
Publication date: 1984-12-12
Also published as: FR2537374A1; FR2537374B1; WO1984002245A1

Abstract

Dispositif chauffant comprenant comme source thermique une résistance traversée par le courant électrique d'un appareil de transformation, et qui en fonctionnement est invisible en obscurité. L'appareil de transformation donne au secondaire plusieurs tensions de sécurité. Comme source d'énergie on utilise aussi des piles ou accumulateurs électriques.Heating device comprising as a thermal source a resistance traversed by the electric current of a transformer, and which in operation is invisible in the dark. The transformer gives the secondary several safety voltages. As an energy source, electric batteries or accumulators are also used.

Description

HEATING DEVICE

The present invention relates to a heating device which can save a large amount of heat and which may have important medical applications. The invention is associated with the most important elements which follow: - an electrical resistance, - a transformer, - a switch-switch. The electrical resistance is mounted in a glass bulb. Clear, colorless, transparent glass, a glass which is widely used in electronics and in the manufacture of the incandescent filament lamp for lighting. The resistance is protected or not against oxidation by an inert atosphere. Resistance is characterized by the fact that in operation it is invisible (or barely visible in the dark).

The transformer (transformer, autotransformer, adapter, etc.) has several safety voltages on the secondary that cannot electrocute.

The intermediate switch-switch between the resistor and the transformer can supply the resistor on one of these safety voltages, depending on the need.

The present invention is an improvement and extension of the FRENCH PATENT No. 2 475 801, and it is the same invention as the PATENT APPLICATION No. 82 20130, which have the same author as the present HEATING DEVICE.

The most important part of the improvement and extension is: a.- The heating device employs as resistance not only a filament which has been and which is used by an electronic tube or by an incandescent filament lamp for lighting , but also a resistor manufactured according to a principle new manufacturing. And this principle, with regard to manufacturing is determined theoretically and practically, with precision. b.- The resistance can be protected by an inert atmosphere and there is also the possibility of manufacturing a resistance that does not need. of an inert atmosphere to be protected against oxidation, In the latter case, the atmosphere (which can also be air,), is used only for the transfer of heat and this only in the event of overheating. c. - With regard to the glass of the bulb containing the resistor, the heating device specifies what Patent 2,475,801 does not give: a transparent, clear glass, without color. These elements are necessary, otherwise the rays of heat cannot pass without heating the glass, which must be avoided. d.- The heating device uses a transformer which supplies several voltages in the safety voltage domain. The resistor is supplied on one of these safety voltages. The voltage is changed as necessary using a switch-switch easily by moving or pressing a button, that is, there is the possibility of using the entire range of voltages, without the slightest difficulty. This facility is not possible using the elements given by Patent 2475801, which does not use the transformer or the switch. e.- The heating device gives details envisaging the applications of the heating and speci ally the applications in the medical field, details which are generally expressed in the applications of Patent 2 k-75801, which (pag. 3, line 24), indicate : "Applications are also in the medical field, zootechnics, greenhouses, laboratories, ..".

Fuel is the most important source of thermal energy. Thermal energy is a starting point for mechanical, electrical, acoustic energy, etc. It is the irapul sion and the heart of industrial life, which generates progress, comfort, wealth, ..

The population of the terrestrial globe doubles every thirty years. The population and industrial progress need an increasing amount of fuel from day to day. Before our eyes the fuel reserves are running out as we go along.

The current level of science and technology can give the hope that in a century the thermal energy of the fuel will be replaced by other energies. But fuel is also the capital raw material for the chemical industry, in an increasingly large field in our life. If tomorrow the thermal energy of the fuel can be replaced by other energies, the fuel raw material is irreplaceable. (And how is it possible to conceive a normal life without the chemical industry: plastic materials, the multitude of textile fibers, dyes, lacquers, paints res, linoleum, shatterproof windows, electrical insulators, material. Telephone, detergents, drug industry, etc., etc.,? ..).

Therefore as it is not possible to create the fuel, the need to save it is imperative. The heating of a small volume which is in a large space (without enclosing this volume), is a means of making a great saving of energy, which is the wish of the man, and it is often applied in the practical life: to disinfect a needle, it is heated in the flame of a match. The flame, although it has a duration of ten seconds, heats the needle to red, that is to say to a temperature which exceeds 800 ° C. But this heat although it has a temperature of 800 ° C, does not heat the room where it is located and cannot be recorded by a thermometer even though it dissipates in the room, because of the small amount of heat and the duration of 10 seconds.

At first glance the possibility of heating one. an object which has the volume of a person (6.1 m), being in a living room which is about 65 m, represents 1/650 of the amount of heat necessary for the heating of the whole room.

If, instead of objects, people are heated, the amount of heat needed is even smaller, because each person gives off a quantity of heat, and to heat it, it is enough to heat it to 24 ° C, a small film air around it., (ie the surface).

Theoretically the amount of heat that heats 6 people (or even objects and equivalent volumes), heat that dissipates in the room, does not influence the temperature of the room. representing only 1/100 of the amount needed to heat the entire room. This small amount of heat is a demonstration which shows how far energy can be saved by heating only small volumes.

To heat an ohjet to the desired temperature, without requiring the heating of the room where it is located, it is first necessary to seek the modality to direct the heat of a thermal source towards the object, although it is possible to do it cross through the heat from one end to the other.

The second premise is to look for the thermal source that can heat the object without damaging it.

The third premise is to control the heat source, in order to heat the object exactly as much as it takes.

The fourth premise is: the source thermal must be able to save investment and energy, that is to say a more advantageous means than other means employed. The fifth premise: the source must not inconvenience by its presence.

The sixth premise: the heat source must never endanger the person using this heating means.

Among other thermal sources, the lamp for lighting could have been of some interest. The electric lamp for lighting, has a filament which, crossed by the electric current, is. heated. The high temperature heats the filament to yellow-white, a temperature that exceeds 3000 ° C, and the bright color of the filament is a source of light. However, the filament is also a heat source which first heats the protective atmosphere and the glass of the lamp, which transfer heat to the surrounding environment.

The heat given off by the glass of the lamp is important: a 100 watt lamp diffuses the amount of heat, which is almost equivalent to the heat given off by a person's body.

This heat given off by the lamp could not remain unobserved. Easily obtained using the lighting lamp, heat has been used many times. However, the glass of the lighting lamp gets very hot: frequently it exceeds 180 ° C, a temperature which at the same time has created difficulties in use, because the glass chars when it touches. plastic material, paper, skin, wool, cotton, etc., i.e. the components of carbon with 1 hydrogen. The lighting lamp could heat a person in ^a bed, because it is a sufficient source of heat, but this heat has the downside of being concentrated in one point. This drawback limited the use of the lighting lamp as a heat source.

The invention presented by a very simple device gives the possibility of manufacturing a device which is characterized by the fact that it meets the requirements previously set out in six premises. This device only diffuses heat without light. This lightless heat can raise the temperature of an object from zero ºC to 150 ° C. But to heat an object to a temperature that exceeds 100 ° C, there are many ways. The interesting part of heating is the possibility of raising the temperature of an object heated between 1 ° C to 50 ° C, that is to say in the field of low heating temperatures, which is not possible with a lamp for lighting that has an incandescent filament and very hot glass.

Another disadvantage of using a lighting lamp, powered by a voltage chosen from the safety voltage domain, is that the lamp gives a very small amount of heat. Even the filament lamp of 1000 watts / 220 volts, which is usually the largest, supplied with two volts, diffuses only 0.722 kcal / h. In addition this lamp has a dimension of 30 cm. A very small amount of heat for such a bulky lamp! it is therefore necessary to build a special smaller bulb - with a more powerful resistance. The resistance supplied by a range of voltages in the field of safety voltages can give exactly with such a voltage the desired amount of heat, because the heat radiated by the resistance is a function of the supply voltage.

The radiant heat beam, projected by the resistance, directly heats the object to be heated without heating the transparent glass of the bulb containing the resistance and the air between the heated object and the bulb (the object is also a surface).

The heated object absorbs the radiated heat, because of its opaque surface, which does not allow the rays to continue their path. The object heated by radiation thus obtains a higher temperature than the surrounding medium and this difference in temperature of the heated volume immediately becomes in turn a heat emitter, this time by convection, because the heat always flows to the lower temperature.

The heated volume absorbs heat up to a temperature "X", and soon it has a constant temperature: this is the stability regime, when the object absorbs a quantity of heat by radiation and diffuses the same quantity of convection heat. This temperature "X", when the heated object enters the steady state, is an equilibrium temperature with the surrounding medium. When the source and the receiver are in a room or in the open air and the conditions are the same, the temperature of the receiver is the same (the stability regime). If the temperature of the surrounding medium rises or falls, the temperature difference is maintained; the source heats up by the temperature difference.

When the heat source produced by a heating device and the receiver are in a box closed by thermally insulated walls, the temperature inside the box and also the temperature of the source lie continuously to the point where the insulation or the source breaks.

A third hypothesis: the heating object is in the body of a mammal. It heats the layers affected by a temperature difference, but although the space around the source is closed, the temperature does not rise continuously like in a box, because the blood circulation becomes more active, and it carries a amount of heat. Despite everything, a local temperature difference persists and this temperature in steady state, is a function of the amount of heat and blood circulation. The resistance which is the thermal source of the heating device is also the most difficult element from the manufacturing point of view.

The manufacture of the resistance necessarily responds to the premise that in operation it is invisible or barely visible in the dark.

The resistors manufactured to be used in the range of voltages between 0 - 24 volts, are the most efficient and the most accessible from the point of view of manufacturing. Resistors manufactured to be used in the voltage range between

0 - 12 volts, in comparison with those manufactured to be used between 0 - 24 volts, have a cost price per watt (respectively per kcal), which is four times more advantageous. The cost price goes up a lot with the interval of use. According to this principle, resistors can be manufactured for voltages between 0 - 220 volts, but the cost price per watt is much higher. A lighting lamp has a filament which is an incandescent metallic resistance in operation. The limits between which the filament is incandescent frequently exceed by 30% the nominal voltage of the lamp. The lower incandescence limit gives the smallest amount of light per watt; the upper limit gives the greatest amount of light per watt, but in this case, the life of the filament is incomparably shorter.

From the point of view of the efficiency of the light, one seeks for the lamp, the greatest quantity of light per watt, but the manufacturer also wishes like his customer, a long life for the lamp, which, like the light, is the claims product. It is the fundamental Consequence for which one seeks a tension of compromise between the luminosity and the life of the filament.

This compromise tension, between the quantity of light per watt and the life of the filament can be called "the Useful Voltage of Incandescence (TUI). That is to say the TUI, is the tension which diffuses a bright light given by l incandescence, and at the same time, it is the operating voltage when the filament has a long life.

You can find the filament that has the desired TUI by calculations and research; it is a very important study for the manufacture of the lamp for lighting, which seeks the practically applicable filament by giving the greatest amount of light per watt. This study is also necessary for the heating device. In this sense we are looking for the resistance that can give the smallest amount of light per watt. For each material used, the TUI can help find the operating limit voltage for the heating device, when in darkness the resistance is invisible. This limit voltage which crosses the resistance, it remains invisible in darkness, can be called the Efficient Heating Voltage (TEC).

One can find the TEC for a metallic resistance of a heating device, when the ratio between the TUI and the TEC is equal or greater than 26. That is to say, one obtains the TEC, when the TUI is divided by ≤ 26.

When the ratio between TUI and TEC is between 18 - 26, the resistance is barely visible in the dark. When the ratio is below 18, the resistance becomes visible in the dark.

The ratios given have been tested on a metallic material and they are linked to the nature of the resistance material. So the limits are not not general, they are only informative.

Consequently, there is a wide range of voltages between zero and a limit voltage, which crosses the resistance, the resistance radiates heat and however this resistance remains invisible in darkness. In this range of voltages between zero and the voltage, TEC limit, the heating device is characterized in that the electrical energy consumed passing through the resistor is transformed 100% into thermal energy. The thermal energy without light radiated by the heating device is characterized by the fact that it can be directed in the desired direction, even from top to bottom.

Table No. 1 indicates the characteristics of a resistor which has a variable thermal power between zero and 10 kcal / h (11.57 watts), and the TEC, 14 volts.

Table No. 2 indicates the characteristics of a resistor which has the same variable thermal power between zero and 10 kcal (11.57 watts), and which has the TEC, 24 volts.

The notions given previously, inclusive of the two tables, specify in the construction of the resistance, the important role played by the TUI and the TEC, which demonstrate that the ohmic resistance and the supply voltage, need the TUI and TEC to specify the operation of the heating device.

The resistance of the heating device which has the characteristics given in table No. 1, requires a glass bulb with a diameter of

2.5 cm., Because this resistance crossed by the voltage of 14 volts, has 16.939 ohms, and it radiates only 10 kcal / h, and this radiated heat does not heat the glass of the bulb. The same resistor connected to the voltage of

220 volts rises to 70.2727 ohms and gives 689 watts. Its color becomes bright and it suddenly consumes a power of 550 kcal / h. This heat diffused by convection, heats the glass of the bulb. For the transfer of this heat it is necessary to have a bulb with a diameter of 16 to 18 cm. . The small 2.5 cm bulb. cannot transfer heat, the resistance overheats and melts. A sudden relaxation of the protective atmosphere breaks everything by explosion.

In conclusion, the bulb of the heating device is characterized by a small volume, and this volume is yet another means among others, of highlighting the dissimilarity between an electric lighting lamp and the bulb of the heating device.

The resistance of the heating device can be manufactured for voltages between zero and 220 volts. If, for example, it has a power of 30 kcal, h (34 watts), for the reasons given above, it will not require a bulb with a diameter larger than 3 cm.

Through studies and research, we can find the resistance of the most suitable heating device from the point of view of cost price, quality and the possibility of implementation. The resistance of the heating device is not solicited for incandescence, and its temperature rarely exceeds 150 ° C. For this it was not necessary to use only metal as a material and not just tungsten or tantalum, like the filament of a lamp for lighting.

Once the resistances have been determined, the heating device can be easily manufactured, in an order of power standardized from the electrical or caloric point of view, respecting the established premises.

The final conclusion considering the thermoelectric particularity of the resistance of a heating device concerning the material and the quantity of energy radiated, is determined by the change of the voltage and ohmic variation of the resistance, respecting despite all the limits imposed by the TEC and by the TUI. The glass bulb of the heater can have any imaginable format, but there. shape of a headlight of an automobile, or a reflector is 1a, more effcient for the transmission of heat by radiation on an object or on a determined surface. The side walls of the glass bulb, elliptical, hyperbolic or conical, covered with a reflective metallic layer, increases the transmission efficiency and the ability to concentrate heat. The shape of the bulb does not influence the thermal efficiency which is always 100%. The shape of a lighthouse is only a recommendation and therefore is not the subject of the Patent. Similar forms are used by de. many other inventions and are also used for lighting lamps. The shape was inspired by the mirrors of Archimedes before JC By a base and a socket we can plug the bulb and its resistance, but like the shape, this is not the subject of the Patent, this means being used by many other inventions.

For applications on the outside of the human body, the shape of a flattened bulb like a disc is most suitable. This flat shape, used inside, of the body, does not require a base and a socket, to be connected.

The energy which feeds the heating device, is the energy of the sector, via a transformer in turn in secondary, can supply several safety voltages, which cannot electrocute. On one of these safety voltages, using a switch switch, the heating device can be supplied with greater or less power by changing the voltage, depending on the need.

An energy source is also wind or hydro electric energy, a very simple rudimentary installation, with or without a voltage regulator, for example in an isolated farm, can feed unpretentious receivers, like a greenhouse , a fruit depot, a workshop, a garage, an installation for drying fruit, a breeding, etc., receivers which can accept a wide variation of the heating temperature.

Another source is an accumulator or an electric battery, energy sources which do not need, of course, a transformer The heat radiated at low temperature by the heating device provides great energy savings and in addition, as a result of its applications, can be used where other means are not applicable.

The transformation device of the heating device is provided with a switch-switch, which is either close to this device, or at a distance, within reach of the hand of the person who uses it; thus the heat can be conveniently controlled.

When this range of power is not enough, one can simply replace the bulb which contains the resistance, by another having the same TEC, but of greater or smaller power, thus offering still a wider range of power by resistance variation.

If ten people are in the same room, can choose by making use of the heating device, each of them the desired heating temperature. It is a possibility that cannot be obtained by any other means and can be easily obtained by the heating device without the slightest disturbance, with incomparable simplicity and ease.

Heating the volume of a bed represents

1/60 of the volume of the bedroom, which becomes less than 2% of the amount of heat needed to heat the whole room, and this heating is used only when the bed is occupied.

A turbo-alternator group, equipment of an electrical factory, located in a hall (which usually has a volume of two hundred to a thousand times greater), requires during assembly at least 16 ° C. To heat the hall, a large hall, it is necessary to build a real annex factory: a very expensive and often impractical means, because of the height.

Heating only the groupa is a solution interesting that has no equivalent.

In winter a country house which is only inhabited during the weekend is inhospitable if it has not been heated during the week. When the house begins to be heated by conventional heating, the cold walls, absorb for 30 to 35 hours the heat of the air which begins to heat up first.

The layers of air supersaturated due to the temperature difference, cover the walls with a film of water.

Although the space around the table in the dining room, the armchairs, the space around the television, the beds, etc. is heated by using the heating device, the air is not heated in the rooms: this temperature difference does not exist, and the walls do not "sweat".

The passage space between the bedroom and the bathroom (or other rooms) can be heated only at the time of passage.

The bathroom can be heated in seconds to the desired temperature, requiring heating only during use (radiant heating which is not prevented by water vapors).

The penetrating humidity, unpleasant, in summer as in winter, suitable for rheumatism, pulmonary diseases, etc., no longer exists with this heating device, which gives the possibility of living in a damp, uninhabitable house, a house with very, high ceilings, or even a cellar.

Heating with the heating device is felt in a few minutes, it becomes acquiring. It is efficient, having an energy consumption which represents less than 1/20, even 1/40 of the energy necessary to heat an entire house. In addition it is clean, hygienic and the investment is very inexpensive.

It goes without saying, that we can also heat an entire room or apartment, store, hall, etc. But in this case the efficiency of the heating is due to the fact that it first heats the object to be heated and then the heat dissipates in the surrounding environment. Despite all the amount of energy consumed in this case, is much greater than heating the object.

Example of a heating modality using the heating device: a person sitting in front of the table in the dining room.

The person occupies 0.1 m ³ , that is, about 2/1000 of the volume of the dining room. A volume much smaller than the volume of the room. This heated volume, without heating the room, certainly represents a real energy saving. The bulb of a heating device, mounted below the horizontal part of the chair, radiates heat on the carpet. Another, mounted below the table, facing the person, radiates heat between the carpet near the person's shoes, up to their waist.

The carpet under the chair heated by radiation, in turn diffuses by convection the same amount of heat. This convective heat rises like the smoke of a cigarette. When meeting the chair (especially the chair seat), heat surrounds the chair and the person with a layer of warm air.

The heat radiates towards the carpet under the table and towards the clothes of the person, heats them and thus because of the difference in temperature, the carpet and the clothes diffuse the same amount of heat by. convection. This heat while flowing, heats the front of the person, and hot it embraces with a small layer of air the table, as well as the chair.

Another heating modality is the radiated source directly towards the person: one below the table, and two others placed at 120 ° behind the person.

Heating from top to bottom towards the carpet has the advantage that the radiated heat which is concentrated, becomes after the meeting of the carpet, a heat diffused by convection, which it is not concentrated, and it rises in waves more and more wider, surrounding the person.

The temperature of the hot air which bypasses the person can be adjusted by the person, since the table as well as the chair can be provided with switch switches. The person can regulate the temperature at ease, because the sources of heat, can raise the temperature around him, between zero and more than 24 ° C, above the ambient temperature.

So you can heat several people, being in different places in the house.

We can heat the beds, by radiating the heat from top to bottom, or laterally, by four sources (or more), beds of course conditioned with a good mattress.

The source of heat of the device, usually does not exceed 15 watts, and it radiates a pleasant heat for living beings. A temperature that resembles that of the sun in autumn. A temperature that does not burn, which does not damage either the leaves of a plant or the petals of a flower at a distance of 4 to 5 cm.

This attractive, joyful warmth is well accepted by young people, adults, the elderly, and especially by children and the sick.

Heating from the ceiling to the floor, using vertical rays, is only recommended when a person is in the horizontal position. Physiologically, a person does not like the rays of heat that fall vertically on the top of their head. So such heating will only be used for a short period, for example at places of the passage. With fall come cold, rain, rheumatism and lung disease also arrive.

Usually it is believed that humidity causes illness. However, with regard to rheumatism, it is a thing noted: although at the equator the humidity is very high, rheumatism does not exist. The conclusion is very simple: cold helped by humidity (maybe), is the culprit. The body of a person needs to live, to move, to work, an energy of about 100 kcal / h. This energy is necessary for the combustions that occur in the human body. A multitude of functions governs the means of maintaining a constant temperature necessary for life and health. Breathing and especially the skin direct the transfer of heat to the outside.

A person is at ease, in the range between 19 to 26 ° C, that is to say at this level our organism is the temperature at which is adapted to optimal conditions, conditions which help the best transfer of heat , without any functional effort. However, the human body has an amazing adaptive power. In addition, to accommodate the surrounding environment, man also uses clothing: when it is cold, that is to say below 19 ° C, because of the difference in temperature, the body loses an amount greater heat than that to which the organism is adapted and thus it feels cold. To prevent heat loss, a person dresses more or less warmly, depending on the temperature difference between the body and the surrounding environment.

Despite everything, the prominent parts, the knees, the elbows, the shoulders, are less protected, as well as the because the clothes, (blanket when the person is lying down), touch these parts, during that the other parts are additionally protected by a layer of air, which is always between the skin and the clothes. One can also wonder if rheumatism is not facilitated by this difference in protection. What is interesting to note, is the fact that, the heat radiated by the cuffing device, first touches the prominent parts of the body which are also the most easily penetrated by the heat, not being doubled by a layer of air (the parts which are less protected by clothes). So heating with the heating device, a heat source that is a way to save a lot of energy, has the additional advantage that it heats better the parts of the body that are disadvantaged by the protection of clothing.

But, if the syllogism that rheumatism among others is generated by the humidity associated with cold is true, then heating by radiation from the heating device which is a heat source, can largely avoid rheumatism. In addition, the layer of air around a person once heated, however also becomes less humid (we change the saturation index), that is to say we change the skin and lung breathing medium.

If the rheumatism already contacted is incurable, it is known, that there is the possibility of improving the pains, and the heating of the sick part is one of these possibilities. With regard to lung diseases, the premise regarding the saturation index of the surrounding medium is also valid.

When the temperature of the whole human body exceeds 42 ° C, this temperature is harmful, because stationary, the cell suffers from irreversible changes. But there are also cases where the temperature exceeds 42 ° C, and it is not harmful: hot tea (or coffee), swallowed sometimes at 60 ° C without hurting. If the hand is immersed in water which has 50 ° C, the hand easily supports this temperature. It is possible to draw the conclusion that a part of our body is not damaged by temperatures exceeding 42 ° C, even if these temperatures are applied for a long time. The phenomenon has an explanation: in the heated part the blood circulation becomes more active. The blood carries heat, which is scattered throughout the body. This heat does not influence the body temperature, and is eventually eliminated by breathing and sweating if the heat is important.

In spite of everything, the heated part maintains a temperature which maintains, exceeds the normal temperature of the body, even the temperature of 43 - 44 ° C.

Scientifically it is found that there are tumors and diseases which, heated above 42 ° C, not only do not progress, but they are removed by the body, without requiring surgery.

By applying the bulb which is the thermal source of the heating device on a tumor, using the temperature which is tolerable by the patient, the temperature can be raised locally. The flat bulb can have any imaginable shape (round like a coin, square, toric, etc.). The bulb is provided with one transparent side and the other reflecting side. The transparent side is directed or pressed directly against the diseased part, or against a sterile dressing or compress. By increasing the voltage, the quantity of radiated heat is greater and thus, the temperature rises. We can easily find the safety voltage that the patient can bear for a power whatever resistance, more precisely for a quantity of heat per cm ² . This amount of heat per cm ² of heated area, which can be is the same for each person, once determined, the application of heating is simplified. Thus one can use a battery or an accumulator which gives the necessary voltage without using a transformer and without a switch switch, or one can find for any voltage of a battery, the resistance and the surface of the balloon which gives the quantity of heat per cm ² , exactly that which is necessary for the fight against the disease, and which is also tolerated without any difficulty by the patient. In the case where there is a difference in the possibilities of supporting the heating (difference from one person to another), the heating temperature can be reduced by putting a bandage, two ... in addition, between the heating source and the patient (application outside an organism).

The resistance which can use an infinity of combinations, (metals with carbon and other metalloids), can also use hydrargyre, in a bulb of the heating device, for a stage of research. The problem of resistance being already established, experience and research will follow their path concerning diseases.

A heater that is powered by battery power, and which has the heat source attached in a bandage (or by other means), can be used to heat a part of the body 24 hours a day, without disturb the patient, who can walk, work, sleep, etc., at ease.

Regarding the treatment of a tumor or disease using the heat source inside the body, there is the possibility of considering two hypotheses which are contradictory.

When the organism cannot eliminate a foreign element, for example a bullet, introduced into the body of a mammal, it covers it with a protective layer to isolate it. The same phenomenon is also possible with a heating device.

But, we can also think that the more active circulation of the blood, to dissipate the heat produced by the heat source of the heating device (and which is not normal in the body), can lead in another way the phenomenon, because, while trying to isolate it, the temperature rises as in a closed box, insulated thermally (see page 7).

There is therefore the hope that the organism, trying to adapt to the situation, is forced to scatter the heat because it cannot cover the thermal source with an insulating layer, a layer which does not resist in this case at the continuously rising temperature. On the contrary there is the certainty that the battery, (in the situation that this source of energy is also inside the body), will be covered with a protective layer, if there is no possibility of find the material accepted by the body, material which can cover the pile.

These assumptions are the conclusion of logic. It is necessary to know how the body reacts. Once the premise is accepted, a window is opened in the world of surgery. The hardworking scientists and researchers have a path which, we can hope, will lead the fight further. We have shown some applications of the heating device.

The field of applications is wide: in household life, in agriculture, in breeding, in industry, in offices, in study rooms, halls and sports fields, performance halls, churches, etc. .

It is also possible to indicate the possibility of heating with a little energy the small flowered spaces, to protect them against frost when the temperature drops below a determined limit in an uninhabited apartment. It is the same for water pipes, and also for the fluidity of liquids transported by pipes. Concrete can be protected during setting, against freezing, even in the open air. You can dry paper and sheets in printing and paints in general.

To change the supply voltage of the bulb, the heating device can also use a rheostat, but the input and output of the electric current are located in the safety voltage range (for example 4 - 20 volts,) .

The best way to use a rheostat, is to use on the mains voltage, a transformation device which in secondary gives the TEC used by the rheostat, or directly intermediate, when the energy source is a battery (or accu - emulator). at

The rheostat has the advantage that it has, with regard to the change in tension, great finesse; but the efficiency of the heating device is smaller, and often the rheostat has a consumption which exceeds that of the heating device.

Therefore the rheostat is used in special cases and despite everything the safety voltage remains an obligation, to avoid electrocution.

With regard to the future, new constructions are planned which will have updated circuits to supply the heating device with safety voltage, and likewise provide an automation to start and stop a heating.

In what characterizes the medical application inside as well as outside the body, the supply of a battery will be commonly used.

The supply of the heating device inside the body by a drain (an external energy connection), will always be a difficult hygiene problem for the patient, and the supply by an external source linked to the sector, restricts its possibility. movement, and activity; still will be the first step.

THE FINAL CONCLUSION: THE FOLLOWING QUALITIES CHARACTERIZE THE ORIGINALITY OF THE HEATING DEVICE:

- a very great energy saving, which translates into a significant saving of money, a derisory investment, a convenient, simple, space-saving heating means,

- robust system which is designed for a large number of operating hours (over 30 years), each device has a wide range of power, between zero and the nominal power of manufacture of the resistance of the bulb which is the source temperature of the device, - the possibility of easily changing the heating power, ie the temperature of the heat released,

- the change in temperature is felt in a few seconds, - the heat given off, which has a low heating temperature, does not damage furniture, lingerie, flowers, etc.,

- a way to prevent and improve certain diseases and even to cure some of the tumors and diseases,

- there is no danger of fire caused by the heating device, manufactured in compliance with the determined technological requirements concerning implementation and operation, - there is NO DANGER OF ELECTRIC SHOCK for the user of the HEATING DEVICE, because it USES ONLY A SAFETY VOLTAGE.

Claims

1. The heating device is characterized in that it comprises a thermal source, supplied with mains voltage, having a transformer and a switch-switch, and by the fact that the thermal source diffuses radiated heat, which can be directed in the desired direction, even from top to bottom, thus allowing to heat a small volume (object or surface), which is in a large space, without enclosing this volume.

2. The heating device is characterized in that it comprises a thermal source, supplied with the voltage of an electric battery or accumulator, having or not having an intermediate rheostat, and by the fact that the thermal source diffuses radiated heat, thus allowing to heat a small volume (surface, object), which can move, not being retained by the source of electrical energy.

3. The heating device according to claim 1,2, is characterized in that its thermal source is a resistor, which passes through the electric current, in the field of safety voltages, heats up, but in operation it is invisible ( or not very visible) in darkness, and said resistance is also characterized by the fact that from the thermo-energetic point of view, the quantity of radiated heat is determined by the change of the supply voltage and the ohmic variation, respecting the limits imposed by the efficient heating voltage, which is the possibility of implementing its manufacture.

4. The heating device as claimed in claim 1, is characterized by the fact that the transformation apparatus, gives secondary safety voltages.

5. The heating device as claimed in claim 1, is characterized in that the switch-switch can be replaced by a rheostat.

6. The heating device as claimed in claim 2, is characterized in that the nominal voltage of the battery (or accumulator), is a safety voltage, which can supply the thermal source via a rheostat on a voltage variable, or directly on a constant voltage, the battery voltage.