ITBS20130181A1 - ELECTRIC STOVE - Google Patents

Description

Electric stove

DESCRIPTION

Field of the invention

The present invention refers to an electric stove, in particular a high efficiency heat storage electric stove, for civil and industrial uses.

State of the art

Electric stoves are widely used in the civil field, for example for domestic use, in offices, public places, etc., and in the industrial field, for example in laboratories, workshops, etc., to heat the rooms where people stay. .

These stoves differ from other types of heating devices that use fluids other than air, such as liquids, or that involve internal combustion, such as gas stoves. In the context of the present invention, the expression 'electric stove' identifies a device configured to heat the air by exploiting the heat produced by one or more resistors, more commonly referred to as 'resistances', without combustion.

Normally electric stoves comprise a body in which the resistances are housed. A traditional electric stove heats the environment in which it is located thanks to two effects linked to the high temperature of the electrically powered resistances: the heating of the air, which in turn generates convective motions in the environment, and the direct radiation of the surfaces. and people, even with infrared light.

To obtain the two effects, the resistances are positioned in the body of the stove in such a position as to be visible from the outside; suitable protection grids prevent people from touching the resistances. The mesh of the grids is however large enough not to significantly shield the radiation generated by the resistances.

In a typical and decidedly widespread embodiment, the body of the stove has a reflective concave surface and the resistances are positioned between the reflective surface and a protective grid that looks outwards. For example, Japanese patent application JP 2005-180840 describes a solution of this type.

Solutions have also been proposed that provide for the installation in the body of the stove of one or more fans that force the air drawn in from the environment to pass through the electrical resistances before being reintroduced into the environment. A solution of this type is described for example in US 6973260.

Traditional electric stoves suffer from at least two drawbacks.

First, they mostly have low energy efficiency. The market demands low-cost stoves and this limits the freedom of the designer. The elements that normally make up an electric stove do not create a great synergy; this means that only part of the heat generated by the electrical resistances due to the Joule effect is rapidly transferred to the air and to the surfaces of the surrounding environment. Part of the heat is 'lost' to heat the body of the stove. Certainly the body, cooling down when the stove is turned off, in turn transfers heat to the environment, but this happens at a time when the transfer of heat is not needed. In these terms, the efficiency of a traditional stove is low, because not all the heat generated by the resistances is immediately transferred to the environment. Instead, it is desirable to have stoves configured for high efficiency.

Secondly, traditional electric stoves do not have a particular aesthetic value and certainly do not constitute appreciable objects from a visual point of view. On the contrary, in the domestic environment, users tend to hide the stoves from the view of the guests.

Summary of the invention

The object of the present invention is therefore to provide an electric stove which solves the drawbacks of traditional solutions in a simple and effective way, resulting simple to produce, reasonably cheap, and at the same time having high efficiency and aesthetic value.

The present invention therefore relates to an electric stove according to claim 1.

In particular, the stove comprises a body, in which a containment chamber is defined, and one or more electrical resistances housed in the containment chamber. Advantageously, the containment chamber is opaque to the irradiation of the electrical resistances, to favor the accumulation of heat in the same chamber. Two or more openings are provided for the fresh air inlet from the room in which the stove is located and the air heated by the resistances to exit in the same room.

Basically, the containment chamber confines the radiation of the resistances inside, preventing the dispersion of this form of heat transmission directly to the environment. A heat accumulation effect is thus created in the containment chamber, in the sense that the portion of heat that in a traditional stove is immediately transferred to the surrounding environment due to radiation, in the stove according to the present invention is used to obtain a corresponding further heating of the air, in addition to the heat released by convection.

The main advantage offered by this solution is to obtain high efficiency in the terms specified here. Tests conducted by the Applicant have shown that for the same consumption of electricity in a given period of time, the stove according to the present invention allows the surrounding environment to be heated more quickly and at a higher temperature than a traditional electric stove of the same power. .

Preferably the electric resistances are more than one and they can be selectively powered. For example, resistors are single resisting elements or groups of elements connected in series and / or in parallel.

In the preferred embodiment, the containment chamber is defined by one or more first shielding elements, defined as external shielding elements. These elements have no through holes in order to intercept the radiation created by the electric resistances on. Furthermore, the shielding elements are configured, by number, shape, size, couplings, etc., to define a substantially closed space around the electrical resistances; the only noteworthy openings remain those for air inlet and outlet.

In one embodiment, the containment chamber is an interstice defined between the internal walls of the first shielding elements and the external walls of second shielding elements, equivalent to the first shielding elements. This configuration maximizes the effect of accumulating heat in the confinement chamber and heating the air inside it with maximum efficiency, since the resistances are in practice surrounded by surfaces that significantly reflect the radiation.

Preferably, the shielding elements are made of a metallic material, for example copper, or of stone, for example marble, or of ceramic, for example majolica, or still of another refractory material. Alternatively, the shielding elements are stratified elements, ie obtained by superimposing at least two layers, for example a layer of metallic material and a layer of a refractory material.

In the preferred embodiment, the electrical resistances develop along a longitudinal direction, for example vertically or horizontally, and the first shielding elements extend circumferentially around the resistances to shield their radiation in the radial direction. If present, the second shielding elements extend circumferentially between the electrical resistances. As described above, the gap present between the resistances and the shielding elements is dedicated to the passage of air.

More preferably, the shielding elements are cylindrical and are stackable to modify the longitudinal extension of the containment chamber in a manner corresponding to the longitudinal extension and / or the number of electrical resistances.

Alternatively, the shielding elements have different shapes, for example with a square, triangular, rhomboid, elliptical section, etc.

With this structure, the stove is substantially configured as a vertical totem, or as a substantially tubular element (even with a non-circular section) horizontal. In any case, the stove can be configured as a piece of furniture.

In this perspective, preferably the stove includes one or more external elements covering the containment chamber; the cover elements can be customized with the desired aesthetic finish, for example with painting, application of adhesive films, posters or photographs. The covering elements of the stove, for example stackable metal cylinders or design elements, constitute a support that can be decorated at will, in such a way as to integrate the stove into the environment in which it must operate, for example an apartment furnished with a particular style, or a public place, such as a restaurant. Clearly, the cover elements can also be customized in terms of shape, as well as graphics.

Optionally, the stove also includes one or more fans, housed in its body to force the flow of air to cross the containment chamber and be expelled into the surrounding environment. In other words, the fan (s) generate a forced air flow into the containment chamber. Conversely, if the fan or fans are not present, the air flow is subject to exclusively convective motions.

Optionally, the stove comprises means for connecting to external sources of a hot gas, for example a traditional heat pump, and the electric resistances are pipes in which the hot gas can be conveyed, for example hollow copper pipes, coils, etc.

The stove according to the present invention can be equipped, if necessary, with accessories such as towel holders, coat hangers, clothes hangers, etc., and can be equipped with wheels to allow easy repositioning.

Preferably, the stove is equipped with a thermostat that detects the temperature of the air in the containment chamber or at its outlet and regulates, in feedback, the selective switching on and off of the resistances and, if present, of the fan.

Short list of attached figures

Further features and advantages of the invention will be better highlighted by examining the following detailed description of a preferred, but not exclusive embodiment, illustrated by way of non-limiting indication, with the support of the attached drawings, in which:

Figure 1 is an elevation and perspective view of a first embodiment of the stove according to the present invention;

Figure 2 is a vertical sectional view of a second embodiment of the stove according to the present invention;

Figure 3 is a perspective view of the stove shown in Figure 2, partially disassembled;

Figure 4 is a vertical sectional view of a third embodiment of the stove according to the present invention;

Figure 5 is a perspective view of the stove shown in Figure 4, partially disassembled;

Figure 6 is a vertical sectional view of a fourth embodiment of the stove according to the present invention;

Figure 7 is a perspective view of the stove shown in Figure 6, partially disassembled;

Figure 8 is a vertical sectional view of a fifth embodiment of the stove according to the present invention;

Figure 9 is a perspective view of the stove shown in Figure 8, partially disassembled;

Figure 10 is a vertical sectional view of a sixth embodiment of the stove according to the present invention;

Figure 11 is a perspective view of the stove shown in Figure 10, partially disassembled.

Detailed description of the invention

The following detailed description refers to several embodiments of the stove 1 according to the present invention.

Figure 1 shows a first embodiment in an elevation and front perspective view. The stove 1 comprises a body 2, which in the specific example is constrained to a base 3 provided with feet or wheels, and one or more cover elements 4. The latter are customized with the desired graphics. In figure 1 some examples are visible.

The stove 1 shown in figure 1 has a substantially cylindrical shape, since the cover elements 4 are cylindrical and are stacked on top of each other, and when positioned vertically it resembles a totem. Alternatively, the covering elements can have different shapes, for example they can be provided with clothes hangers, towel holders, flaps, etc.

Figure 2 shows a second embodiment of the stove 1, in a sectional view considered in a vertical plane. The same stove 1 is shown partially disassembled, for reasons of clarity, in figure 3, in perspective.

As can be appreciated, the body 2 includes at least two elements, one lower 2 'and one upper 2 "joined by a metal tie rod 10. If necessary, one or more intermediate septa may be present.

One or more electric resistances 5 extend vertically along a corresponding longitudinal development direction between the elements 2 'and 2' 'of the stove body 1. In the example shown in figures 2 and 3, the resistances 5 are six steel elements, powered at 220V, with a diameter between 1 and 4 cm and a length between 5-60 cm. The resistances 5 are selectively powered, in the sense that they can be powered all at the same time or one or more resistors at a time.

In general, the resistances can have different shapes, for example they can be wavy coils, square, triangular elements, finned tubes, etc.

A control panel 6 positioned at the base of the stove 1, on element 2 ', allows the user to switch the stove on and off and adjust its operation.

The base 3 defines a radial passage for the supply of ambient air, that is, a passage through which the relatively fresh ambient air is drawn back into the stove to be heated by the resistances 5. The arrows in figures 2 and 3 indicate the theoretical path fresh air C entering the stove, rising along the resistances, where it is heated and exiting as hot air H from the upper part of the stove 1.

Preferably a thermostat (not shown) is positioned at the hot air outlet to measure its temperature. The signal generated by the thermostat is used by the control panel to regulate the switching on and off of each resistance 5 in feedback so as to respect the temperature regulation set by the user, for example 250W, 300W, 430W, 550W, etc. .

Advantageously, the resistances 5 are confined in a chamber 7 defined by stacked shielding elements 8. In the embodiment shown, the shielding elements are cylindrical and surround the resistances 5 substantially for their entire length to intercept the heat produced by radiation from these. The chamber 7 is open to the environment at the opening 3 'for fresh air C and at the outlet 9 (not visible) for the hot air H. Basically, the hot air rises in the confinement chamber 7 until it exceeds the upper edge of the last shielding element 8 and exits through the slots made in the covering elements 4 at all levels.

In the example shown in the figure, the shielding elements 8 are made of a refractory material, for example ceramic. Basically, the radiant energy produced by the resistances does not escape from the confinement chamber 7 and from the stove 1 in general, but is reflected or absorbed by the shielding elements 8 to obtain maximum air heating. In this sense, the stove 1 can be defined as 'heat accumulation'.

Alternatively, the shielding elements 8 can be made of metal, for example of copper, or they can be made of stratified, with layers of different metals and / or refractory materials.

Figures 4 and 5 show another embodiment of the stove 1 according to the present invention, equivalent to that shown in Figures 2 and 3, with the difference that in this variant the customizable cover elements 4 are configured some barrel and others as hyperboloids, and are alternated to create a wavy external surface, or to define a column with section narrowings alternating with bulges. Figure 4 shows the hot air outlet 11 from the confinement chamber 7. For greater clarity, the hot air discharge slots H through the cover elements 4 are not shown. Reference 12 indicates one of the above mentioned septa.

Figures 6 and 7 show yet another embodiment equivalent to the previous ones except for the fact that the cover elements have a plurality of circular through holes for the discharge of hot air into the environment H.

Figures 8 and 9 show yet another embodiment equivalent to the previous ones except for the fact that the confinement chamber 7 is defined by shielding elements 8 which in turn consist of a multitude of interconnected profiles 8 ', for example with a coupling of shape.

Figures 10 and 11 show a double chamber variant in which the confinement chamber 7 does not extend radially up to the tie rod 10, as in the previous variants, but is limited by second shielding elements 8 ", equivalent to the elements 8 but with a smaller diameter , stacked one on top of the other coaxial to the first shielding elements 8. In this variant the shielding elements 8 are configured themselves as covering elements or, alternatively, they can be further covered by covering elements 4.

The internal covering elements 8 "define a second chamber 7 ', as best shown in figure 11.

All the embodiments can, if necessary, be provided with a fan, housed for example in the base 2 'or in the upper portion 2 "of the body 2 of the stove 1 to force the flow of air in suction or delivery through the chamber. confinement 7.

Claims (11)

CLAIMS 1. A stove (1) comprising a body (2) associated with a containment chamber (7), and one or more electrical resistances (5) housed in the containment chamber (7), characterized in that the containment chamber ( 7) is opaque to the radiation produced by the electric resistances (5), to favor the accumulation of heat in the same chamber (7), and has at least one opening (3 ') for the entry of fresh air (C) and at least one opening (11) for the outlet of the air (H) heated by the resistances (5). 2. Stove (1) according to claim 1, in which the containment chamber (7) is defined by one or more first shielding elements (8) without through holes facing the direction of irradiation of the electrical resistances (5) and configured to define a substantially closed space around the electrical resistances (5), except for said air inlet (3 ') and outlet (11) openings. 3. Stove (1) according to claim 2, wherein said containment chamber (7) extends between the internal walls of said first shielding elements (8) and the external walls of second shielding elements (8 "), equivalent to said first shielding elements (8). 4. Stove (1) according to claim 2 or claim 3, in which said confinement chamber (7) is configured to favor the overheating of the air, also due to the radiation generated by the electric resistances (5), in the relative path between the inlet opening (3 ') and the outlet opening (11). 5. Stove (1) according to any one of claims 2-4, wherein said shielding elements (8, 8 ") are made of a material selected from the group comprising refractory materials, metallic materials, ceramic, stone, or they are layered elements comprising at least two layers each of which is of one of these materials. 6. Stove (1) according to any one of the preceding claims 2-5, in which the electrical resistances (5) extend along a longitudinal direction, the first shielding elements (8) extend circumferentially around the resistances (5) to shield their 'radiation in the radial direction and, if present, the second shielding elements (8 ") extend circumferentially between the electrical resistances (5), the gap between the resistances (5) and the shielding elements (8, 8") being dedicated to the passage of air. 7. Stove (1) according to any one of claims 2-6, in which the shielding elements (8, 8 ") are substantially cylindrical and are stackable to modify the height of the containment chamber (7) in a manner corresponding to the extension and / or the number of electrical resistances (5). 8. Stove (1) according to any one of the preceding claims 1-6, in which the electric resistances (5) are more than one and can be selectively powered. 9. Stove according to any one of the preceding claims, comprising one or more external elements (4) for covering the containment chamber (7), the covering elements (4) being customizable with the desired aesthetic finish, for example with painting, application of adhesive films, poster or photo application. 10. Stove (1) according to any one of the preceding claims, further comprising a fan housed in the body of the stove to force the flow of air to cross the containment chamber and be expelled into the surrounding environment. A stove (1) according to any one of the preceding claims, comprising means for connection to external sources of hot gas and in which the electric resistances are pipes in which the hot gas can be conveyed.