ITVI20120093A1 - A GROUP OF HEATING OF ENVIRONMENTS - Google Patents

Description

â € œA GROUP FOR HEATING OF ENVIRONMENTSâ €

DESCRIPTION

Field of application

The present invention is generally applicable to the technical sector of room furnishing and, in particular, it refers to the construction of electrically powered room heating units.

More in detail, the present invention relates to the realization of room heating units by irradiation.

State of the art

The use of room heating units having substantially laminar bodies has been known for some years.

In particular, these groups have electrically conductive portions that are used as electrothermal transducers: the electrical power with which they are powered is transduced, thanks to the resistivity they present, into heat that is radiated into the external environment.

An example in this sense is described in the patent document FR 2 817 947 where an electrothermal transducer is enclosed between a glass plate and an aluminum sheet.

Totally glass heating units are also known. They are generally composed of two laminated glass plates. Among them, a plate is treated to make it conductive so that an electric current passing through it generates heat. The other slab covers the first and faces outwards. In this sense it is electrically insulating and thermally conductive to radiate heat into the environment and, at the same time, electrically secure the heating unit.

This solution therefore has the advantage of having a good yield and of being unobtrusive to the environments in which it is used, being extremely thin. It is applied to the perimeter walls of the rooms exactly like the current radiators or similar. Being made of glass, the aforesaid group can be transparent, in order to limit the visual impact, or decorated.

In any case, whatever the material with which the described heating unit is made, it has as a recognized drawback the fact that the heat emitted by the electrothermal transducer is diffused from both sides, the one facing the room to be heated and the one facing the room to be heated. towards the rear of the heating unit. Since generally on the back there is a wall or in any case an area that does not need to be heated, the heat radiated in this direction is considered partially lost unnecessarily.

This results in non-optimized heating costs due to dispersion. From the current perspective of energy saving with reference also to the saving of electricity consumed by users, the drawback highlighted becomes even more important.

The drawback of the little optimization of consumption of the heating units described above is evident also for their other characteristics.

The heat emitted is closely linked to the type of transducer, to its size (a transducer in any case exploits the ohmic effect so that the heat generated is directly dependent on the length of the path of the electric currents) and to the regulation of the electrical power supply . The most influential of these parameters is, as can be easily understood, the type of transducer which in the known art is difficult to control.

Presentation of the invention

The object of the present invention is to at least partially overcome the drawbacks highlighted above by providing an electrically powered heating unit of the radiation type which is substantially sheet-like.

Another purpose is that the heating unit presents, in the operating phase, optimized electrical consumptions and that it produces a quantity of heat that responds as much as possible to the actual needs.

A particular purpose of the invention, within the scope of the general purpose just mentioned, is that the heating unit radiates heat mainly towards the environment and not towards other directions.

Another purpose is that the heating unit can be made entirely of glass. In this sense, a further purpose of the invention is that the heating unit can be used as an interior furnishing element for rooms or as an integral part of frames such as doors, French windows, windows or the like.

These aims, as well as others which will appear more clearly in the following, are achieved by a room heating unit in accordance with the following claims which are an integral part of the present description.

In particular, the heating unit may comprise at least three substantially sheet-like elements arranged superimposed on one another. In particular, there may be a first and a second plate-like elements between which the third plate-like element can be included.

Furthermore, layering elements can be interposed between the sheet-like elements to join them together to form a substantially full multilayer body.

According to an aspect of the invention, the first sheet-like element can be turned towards the room to be heated, while the third sheet-like element can include an electrothermal transducer connected to an electrical power source to emit heat and heat the entire heating unit. .

According to another aspect of the invention, the second sheet-like element could be at least partially thermally insulating, typically but not necessarily infrared reflective so that the heat directed towards it is mostly reflected towards the first sheet-like element from where can be irradiated.

From what has been said it emerges that a heating unit made in this way will be distinguished by the small size of the space occupied, with particular reference to the thickness.

Furthermore, it will be able to rationalize electricity consumption since most of the heat generated can be radiated towards the environment, being the second sheet element scarcely radiant and reflecting infrared towards the third element.

Typically, but not necessarily, the sheet-like elements may be made of glass or other equivalent generally transparent materials.

Brief description of the drawings

Further characteristics and advantages of the invention will become more evident in the light of the detailed description of some preferred, but not exclusive, embodiments of a heating unit according to the invention, illustrated by way of non-limiting example with the aid of join tables of drawings in which:

FIG. 1 represents a space heating unit according to the invention in axonometric view;

FIG. 2 represents the space heating unit of FIG. 1 in exploded view;

FIG. 3 shows a detail of the space heating unit of FIG.1.

Detailed description of some preferred embodiments With reference to the cited figures, and in particular to figs. 1 and 2, a space heating unit 1 of the electrically powered type is described.

This group 1 is made up of a multilayer 2 composed of a plurality of sheet-like elements 3 superimposed on each other and assembled by means of layering elements 4.

In the embodiment described, the sheet-like elements 3 are laminated glass sheets to form a full multilayer 2. However, this should not be considered as limiting for the use of other materials. Obviously, the use of transparent materials makes it possible to create heating groups that can be used in multiple contexts compared to the use of opaque materials. It is observed, in fact, that if a decorative heating unit is required, glass is a material that can be decorated by means of digital printing processes suitable for creating heating units which, in addition to being a valuable piece of furniture, allows to freely choose the desired degree of transparency, translucency or opacity.

In the case of glass, lamination generally takes place by interposing materials such as polyvinyl butyral, ionomer polymers such as Sentry Glas Plus (SGP, Dupont), thermosetting adhesive films based on ethylene-vinyl-acetate (EVA) between the glass sheets ). The materials listed above are obviously cited purely by way of example and are therefore not to be considered as limiting for different embodiments of the invention using different materials.

From the figures it can be seen that the multilayer 2 comprises three plate-like elements 3. Also in this case it is a non-limiting example for different embodiments where the plate-like elements are greater than three.

In particular, there is a first sheet-like element 5 facing the room to be heated and from which the heat generated is radiated.

There is also a second plate-like element 6 separated from the first plate-like element 5 by a third plate-like element 11 comprising an electrothermal transducer 15 which generates heat.

Previously it was said that according to the described non-limiting embodiment, the sheet-like elements 3 are made of glass. In this sense, the third sheet-like element 11 is made of tempered glass, for example of the pyrolytic type or similar. The electrothermal transducer 15 consists of the coating of a first surface 16 of the third plate-like element 11 made with metal oxides. This coating makes the aforementioned first surface 16 electrically conductive and characterized by a resistive coefficient which transforms the electric current into heat.

Obviously, this embodiment is not to be considered limiting for different embodiments of the invention where, for example, only a portion of the third sheet-like element is coated with metal oxides or where the electrothermal transducer is made in a different way.

Furthermore, more third sheet-like elements can be present in the multilayer of the invention without departing from the scope of protection of the present invention. In this case, however, this allows a fine adjustment of the heat emitted by selecting how many transducers to feed and the power level to be supplied. The result is an optimization of electricity consumption and a greater correspondence of the heat generated with actual needs.

In this sense, the heating unit 1 of the invention conveniently comprises, even if not shown in the figures, an electrical unit for controlling and regulating the electrical power supply of the electrothermal transducer 15.

According to an aspect of the invention, this electric control and regulation unit typically comprises a microcontroller, a temperature sensor and an actuation circuit based on a per se known TRIAC technique, thus realizing the regulation of the temperature of the heating unit. and the absorbed power.

In particular, should the heating unit 1 reach potentially dangerous temperatures, the control reacts by interrupting the flow of electrical energy.

The drive with TRIAC technique provides for the control of the phase angle so as to be able to manage both the average and instantaneous power. In this way it is also possible to monitor the power peaks, improving the safety of the heating group 1 of the invention.

Advantageously, the same regulation unit also allows to regulate the heat emitted by the heating unit, optimizing electrical consumption and producing the necessary amount of heat.

Summarizing, therefore, the heat emitted by the heating group 1 of the invention is adjustable in a range determined by the number of electrothermal transducers, by the type of transducers and by the size of the group itself.

During the construction phase, therefore, in order to satisfy all the needs, it is not limited only to the choice of the most appropriate size of the heating group 1, but it is also possible to choose the number of electrothermal transducers 15 (and therefore of third ribbon-like elements 11) as well as the type of each electrothermal transducer 15.

In order to further refine the heat emitted by the heating unit 1 and to be able to adapt it to the most specific needs, the first surface 16 of the third sheet-like element 11 has, as can be seen in fig. 3, a microfracture 18. The latter interrupts the surface coating made with metal oxides and, therefore, turns out to be an electrically insulating element. Consequently, this microfracture 18 allows the path of the electric current to be shaped between the power supply poles of the first surface 16, thereby varying the electrical resistance offered by the electrothermal transducer 15. During the execution of the heating unit 1, it is therefore possible to carry out one or more microfractures 18 so as to vary the resistance value of the electrothermal transducer 15 without necessarily varying the coating, maintaining an optimal range for the correct operation of the triacs.

This expedient also allows to obtain further advantages. The electrical power supply of the electrothermal transducer 15 occurs by means of two poles 19 which are connected to the first surface 16 on opposite sides with respect to its maximum size so that the current runs along its entire length. The realization of microfractures 18 allows to realize suitable paths so that the poles 19 are arranged close to each other. In this way there will be no cables, screen-printed conductive tracks or in any case electrical connections that go from one point to the other of the heating group 1.

The heat generated by the transducer 15 spreads over all the sheet-like elements 3 that make up the multilayer 2. Once the first sheet-like element 5 is reached, it is radiated outwards to heat the environment. In this sense, the first sheet-like element 5 is made of tempered float glass. It is therefore electrically insulating in order to secure the transducer 15. Being exposed to the outside, it is suitably mechanically resistant. It is also thermally conductive in order to satisfy the functionality of heating group 1.

However, the same heat also reaches the second sheet-like element 6 through which it would radiate towards the rear of the heating unit 1. Typically in this position there is a wall or in any case a support whose heating is useless. In other words, as previously highlighted, the heat radiated by the second sheet-like element 6 would be lost unnecessarily, reducing the efficiency of the heating unit 1.

According to one aspect of the invention, therefore, the second sheet-like element 6 has a thermally insulating portion thereof so that the heat generated by the third sheet-like element 11 is diffused by radiation mostly through the first sheet-like element 5, limiting the dispersion of heat in unwanted directions.

In particular, according to one aspect of the invention, the second sheet-like element 6 is made of pyrolytic tempered glass or similar having the surface 8 facing the external environment coated with metal oxides. These create, while maintaining the transparency of the second sheet-like element 6, a barrier reflecting the infrared or, in other words, a barrier that breaks down the radiation of heat in this direction by reflecting it towards the first sheet-like element 5.

Advantageously, therefore, the dispersion of the heat generated in non-useful directions is limited. This results in a considerable increase in the yield of the heating unit 1 of the invention.

The coating or coating with metal oxides of the surface 8 of the second sheet-like element 6 makes this surface 8 electrically conductive. In this sense, currents induced by the electromagnetic field generated by the electrothermal transducer 15 develop on it. Therefore, there is conveniently a ground connection for this surface 8.

According to a further aspect of the invention, a decoration is applied on the internal surface 10 of the first sheet-like element 5, typically but not necessarily by silk-screen technique, which allows to improve the aesthetic aspect of the heating unit 1 without affecting its appearance. ™ efficiency.

As previously pointed out, the embodiment described up to now is with three plate-like elements. However, this should not be considered limiting for different embodiments of the invention according to which the plate-like elements are greater than three. Previously it was said, for example, that more than a third sheet-like element may be present. In addition to this, it is evident that further sheet-like elements may also be present without electrothermal transducers or thermally insulating portions. Such further plate-like elements can be interposed between third plate-like elements, between these and the first and second plate-like elements and / or, again, between the first and second plate-like elements and the outside. In other words, the fact that up to now we have dealt with an embodiment where the first and second sheet-like elements are at the ends in the multilayer must not be considered limiting for different embodiments of the invention where between the first and / or the second sheet-like element and the end of the multilayer are additional sheet-like elements.

In the light of the foregoing, it is understood that the heating unit of the invention achieves all the intended purposes by overcoming the aforementioned drawbacks of the known art.

In particular, it is particularly compact and thin, thus maintaining minimum dimensions.

Nevertheless, it has an optimized rendering. Electricity consumption for heating, in fact, is reduced with the same amount of heat radiated into the environment thanks to the thermal insulation present on the second sheet-like element as well as thanks to the measures to make the generation of heat as adjustable as possible.

The heating unit of the invention is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept expressed in the attached claims. All the details can be replaced by other technically equivalent elements, and the materials can be different according to the requirements, without departing from the scope of the invention.

Although the heating unit of the invention has been described with particular reference to the attached figures, the reference numbers used in the description and in the claims are used to improve the intelligence of the invention and do not constitute any limitation to the scope. of protection claimed.

Claims (9)

â € œA GROUP FOR HEATING OF ENVIRONMENTSâ € R I V E N D I C A Z I O N I 1. A room heating unit comprising a plurality of plate-like elements (3) among which at least one first (5) and at least one second plate-like element (6) are identified with at least a third plate-like element (11) interposed, said elements slabs (5, 6, 11) being arranged superimposed on each other, to form a multilayer body (2) by interposition of stratification elements (4) in which: â ’said first sheet-like element (5) is intended to be turned towards the room to be heated; ∠’said third plate-like element (11) comprises at least one electrothermal transducer (15) that can be connected to an electrical power source in order to heat all said plate-like elements (5, 6, 11); Said second sheet-like element (6) has at least a thermally insulating portion so that most of the heat generated by said third sheet-like element (11) is diffused by irradiation from said first sheet-like element (5). 2. Group according to claim 1, wherein said first sheet-like element (5) is made of tempered float glass. Group according to claim 1 or 2, wherein said third sheet-like element (11) is made of tempered glass and coated at least partially with metal oxides to make said electrothermal transducer (15). Group according to any one of the preceding claims, in which said second sheet-like element (6) is made of tempered glass at least partially coated with metal oxides to reflect the infrared rays by providing thermal insulation. 5. Assembly according to claim 4, wherein said coating with metal oxides of said second sheet-like element (6) has an electrical connection to ground for discharging the induced currents. Group according to any one of the preceding claims, wherein said coating with metal oxides of said third sheet-like element (11) has at least one electrically insulating microfracture (18) to provide an obligatory path for the currents circulating on said coating. 7. Unit according to any one of the preceding claims, comprising an electric unit for controlling and regulating the electric power supply of said electrothermal transducer (15). 8. Group according to any one of the preceding claims, in which said layering elements are made of thermosetting plastic material. 9. Assembly according to any one of the preceding claims, in which said first sheet-like element (5) has one or more decorative elements.