ITMI20121039A1 - SHEET CONVECTOR PANEL FOR A RADIATOR FOR THE HEATING OF AN ENVIRONMENT - Google Patents

Description

DESCRIPTION

The present invention relates to a sheet metal convector panel for a radiator for heating an environment, particularly but not necessarily of the type with radiant plates or of another type, for example with flat tubulars, to a process for its realization, and to a method of optimization of its convective exchange efficiency.

A convector consisting of a sheet steel panel generally applicable to a radiator has been on the market for some time.

The panel has a substantially more or less rounded square wave bending profile which defines, on the side facing the plate, a series of parallel and separate convective channels, along which an upward laminar flow of air is created by the chimney effect.

A traditional convector panel to perform well the function it is responsible for, must have convection channels with a minimum height not less than a certain threshold value, which can lead to a significant consumption of raw material with an impact on both weight and cost. of the finished product.

To obviate this inconvenience, sometimes we tend to use a thinner thickness plate, but this expedient in turn complains of the drawback that below a certain thickness of the plate the thermal conduction through the thickness of the plate is strongly penalized. .

The technical task proposed by the present invention is, therefore, to provide a sheet metal convector panel for a radiator for heating an environment, a procedure for its realization, and a method for optimizing its convective exchange efficiency which allow to eliminate the technical drawbacks complained of of the known art.

In the context of this technical task, one of the purposes of the invention is to create a convector panel in sheet metal for a radiator for heating an environment which, with the same thickness of the sheet metal compared to a traditional panel, to maintain the € ™ conductive exchange efficiency through the thickness of the sheet, jointly achieves an optimization of the convective exchange efficiency and a reduction in raw material consumption.

Another purpose of the invention is to provide a simple and economical method for manufacturing convector panel in sheet metal with high convective exchange efficiency.

The technical task, as well as these and other purposes, according to the present invention are achieved by making a convector panel in sheet metal for a radiator for heating an environment, characterized by the fact that it comprises a plurality of longitudinal and parallel channels laterally separated from each other. by means of longitudinal separation walls, each channel comprising in its longitudinal development direction an alternating succession of first delimiting walls which develop on one side of the separation walls and second delimitation walls which develop on the opposite side of the separation walls.

The present invention also discloses a method of optimizing the efficiency of the convective exchange of a sheet metal convector panel installed on a radiator for heating a room, said convector panel comprising a plurality of parallel longitudinal channels, characterized by the fact that it opens laterally each channel along a succession of its longitudinal sections separated and sized in such a way as to obtain the maximum turbulence with the minimum loss of flow rate due to the upward air flow that is established in the channels due to the natural convective exchange triggered by the convector panel.

Finally, the present invention discloses a process for manufacturing a convector panel for a radiator, characterized in that it comprises a step of shearing and bending a flat sheet in which the bending lines are straight parallel which delimit a succession of longitudinal strips of sheet metal, and the blanking lines selectively affect groups of consecutive longitudinal strips of sheet metal which are divided by the blanking lines into a longitudinal succession of cells, the bending phase being performed with bending forces orthogonal to the plane of the flat sheet and operating opposite direction on the adjacent cells of each group of longitudinal strips in such a way as to generate along each group of longitudinal strips a corresponding channel having alternating first boundary walls which develop on one side of the plane where the sheet is laid and second boundary walls which s i extend from the opposite side of the plane where the sheet lies.

The invention achieves numerous advantages including the fact that the material savings achievable allows to expand the design choices and adopt a more noble material, such as aluminum or copper instead of steel, for the ™ optimization of thermal output.

The specific conformation of the convector panel itself offers other advantages, including the possibility of directly exploiting its parts in relief as hooks for fixing the radiator to a wall.

The possibility of having an extremely compact convector panel configured in this way also makes it possible to guarantee uniform application of the protective paint along the channels and easier accessibility to all its parts for effective cleaning.

Finally, such a convector panel, while normally providing for a vertical installation with the channels oriented vertically, is equally well suited to a vertical installation rotated by 90 ° with the channels therefore oriented horizontally.

In fact, even in this last case it is possible to advantageously obtain an upward convective flow of air suitably turbulent due to the fact that the first and second delimiting walls of the channels create an obstacle path for the flow of air. ascensional which determines greater turbulence and ultimately a benefit in terms of convective exchange yield.

Other characteristics of the present invention are also defined in the dependent claims.

Further characteristics and advantages of the invention will become more evident from the description of a preferred but not exclusive embodiment of the convector panel according to the invention, illustrated by way of non-limiting example in the attached drawings, in which:

Figure 1 shows an isometric view of the convector panel arranged vertically with the channels vertically, in which the convective upward flow of air is illustrated by bold directional lines;

figure 2 shows an enlarged detail of the convector panel of figure 1;

figure 3 shows a front view of the convector panel of figure 1;

Figure 4 shows a plan view of the convector panel of Figure 1, applied to the vertical wall of a radiating plate of a radiator with the channels arranged vertically;

figure 5 shows a side elevation view of the convector panel of figure 1;

figure 6 shows a plan view of a portion of the flat sheet panel from which the convector panel is obtained, with the fold lines and cut lines indicated;

Figure 7 shows an isometric view of the convector panel arranged vertically with the channels horizontally, in which the convective upward flow of air is illustrated by bold directional lines.

With reference to Figures 1 - 7, a convector panel 1 made of sheet metal, for example of steel, for a radiator for heating an environment, of the type for example but not necessarily with radiant plates, is shown.

The convector panel 1 comprises a plurality of longitudinal and laterally parallel channels 2 separated from each other by longitudinal separation walls 3.

Each channel 2 comprises in its longitudinal direction an alternating succession of first delimiting walls 4 which develop on one side of the separation walls 3 and second delimitation walls 5 which extend on the opposite side of the separation walls 3.

Preferably the first delimiting walls 4 and the second delimiting walls 5 generally have a checkerboard arrangement on the convector panel 1, and therefore, the first and second delimiting walls 4, 5 of the channels 2 are ordered in alternating sequences also in the long direction followed by channels 2.

The separation walls 3 are flat and in particular they are all coplanar.

The first delimiting walls 4 and the second delimiting walls 5 have the same height in a direction orthogonal to the plane of the separation walls 3.

The first delimiting walls 4 and the second delimiting walls 5 preferably have the same configuration, and in particular a rounded trapezoidal configuration. Thus, each first delimiting wall 4 comprises two flat sides 4a and 4b having an opposite angle of inclination with respect to the plane of the separation walls 3, and a flat side 4c parallel to the plane of the separation walls 3, while each second boundary wall 5 comprises two flat sides 5a and 5b having an opposite inclination angle with respect to the plane in which the separation walls 3 lie, and a flat side 5c parallel to the plane of the separation walls 3.

For each channel 2, each pair of consecutive delimiting walls 4, 5 has the adjacent longitudinal ends 4e, 5e which join at points P1, P2 in correspondence with the separation walls 3.

The adjacent longitudinal ends 4e, 5e of the consecutive delimitation walls 4, 5 have a conjugate shape, in particular the end 4e of the first delimitation wall 4 has a rectilinear edge lying in a plane orthogonal to the sides 4a and 4b. Longitudinal axis of the channel 2, and in correspondence with side 4c a concave edge, while the end 5e of the second delimitation wall 5 has a rectilinear edge lying in a plane orthogonal to the longitudinal axis at sides 5a and 5b of the channel 2, and at the side 5c a convex edge.

Advantageously, the convector panel 1 delimits a plurality of secondary channels 7 each delimited by a separation wall 3 and by the sides 5a and 5b of the second delimitation walls 5 which branch off from the separation wall 3.

The secondary channels 7 have a half height compared to the main channels 2.

In figure 4 the numerical reference 6 indicates the vertical wall of the radiator plate to which the convector panel 1 is applied with its long side in the horizontal direction. The plate generally has a heating fluid circuit comprising a plurality of longitudinal and parallel wet channels alternating with dry channels.

The wall 6 of the radiant plate closes one side of the channels 2 and 7. Preferably the main channels 2 are superimposed on the wet channels of the plate, while the secondary channels 7 are superimposed on the dry channels of the plate.

As the convector panel 1 is configured, the main channels 2 have a direct exposure to the atmosphere in correspondence with the longitudinal sections 8 where the second delimiting walls 5 are present, and are laterally in fluid communication with the secondary channels 7 in correspondence with the longitudinal sections 9 where the first boundary walls 4 are present.

We refer to the installation of the convector panel 1 with the main channels 2 oriented in the vertical direction. The convective exchange during normal operation of the radiator is due to the upward flow of air which, due to the chimney effect, goes up the main vertical channels 2, the secondary vertical channels 7, and the oblique channels that are created due to the lateral fluid communication between the main channels 2 and secondary channels 7.

Advantageously, the upward flow of air due to the chimney effect along the main channels 2 is turbulent due to the alternating exposure to the air of the external atmosphere and to the air that flows in the secondary channels 7.

The increase in turbulence has a beneficial impact on the convective heat exchange efficiency of the convective panel 1.

In particular, at least the length of the longitudinal sections 8 of the channels 2 exposed to the atmosphere is dimensioned in such a way as to obtain an upward flow of air along the channels 2 having the maximum turbulence with the minimum loss of air flow. In fact, duct sections 8 that are too short would not allow to create an appreciable turbulence in the ascending flow, while too long sections 8 would cause the cooling of the ascending flow and the consequent loss of air flow.

This innovative convector panel 1 compared to a conventional panel of the same thickness and height of the channels is able to achieve the same thermal efficiency but with a considerable saving of raw materials.

With reference to figure 7, it can be seen that the convector panel is equally suitable for vertical installation rotated by 90 ° with the channels 2 oriented in the horizontal direction.

In fact, even in this last case it is possible to advantageously obtain an upward convective flow of air suitably turbulent due to the fact that the first delimiting parts 4 and the second delimiting walls 5 of the channels 2 create an obstacle path for the upward flow of air which determines greater turbulence and ultimately a benefit in terms of convective exchange yield. In practice, the first boundary walls 4 intercept and divert the upward flow of air which in this case has an upward path no longer predominantly straight but predominantly zig zag. The process for manufacturing the convector panel 1 comprises a step of blanking and bending a flat sheet 10 in which the bending lines 11 are straight parallel which delimit a succession of longitudinal sheet metal strips 12, 17 and the blanking lines 13 involve selectively groups of consecutive longitudinal sheet metal strips 12 which are divided by the blanking lines 13 into a longitudinal succession of cells 14, 15.

The bending step is performed with bending forces orthogonal to the plane of the flat sheet 10 and operating in the opposite direction on the adjacent cells 14, 15 of each group of longitudinal strips 12 in such a way as to generate from each group of longitudinal strips 12 a corresponding channel 2 comprising the alternating succession of the first and second delimiting walls 4, 5.

In particular, the two internal folding lines 11 of each group of three consecutive longitudinal sheet metal strips 12 constitute the joining edges of the sides 4c, 5c of the delimiting walls 4, 5 on the sides 4a, 5a and 4b, 5b of the walls edges 4, 5 themselves, while the two external bending lines 11 of each group of three consecutive longitudinal sheet metal strips 12 form the joining edges of the sides 4a, 4b and 5a, 5b of the delimiting walls 4, 5 at the separation walls 3 which in turn derive from the longitudinal strips 17 not affected by the blanking lines 13.

The convector panel thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept; furthermore, all the details can be replaced by technically equivalent elements.

In practice, the materials used, as well as the dimensions, may be any according to the needs and the state of the art.

Claims (13)

CLAIMS 1. Convector panel (1) in sheet metal for a radiator for heating a room, characterized by the fact of comprising a plurality of longitudinal and parallel channels (2) laterally separated from each other by longitudinal separation walls (3), each channel (2) comprising in its longitudinal direction an alternating succession of first boundary walls (4) which develop on one side of the separation walls (3) and second boundary walls (5) which develop on the opposite side of the walls separation (3). 2. Convector panel (1) made of sheet metal for a radiator for heating a space according to claim 1, characterized in that the first and second boundary walls (4, 5) of the channels (2) are arranged in alternating sequences also in the direction along which the channels follow each other (2). 3. Convector panel (1) made of sheet metal for a radiator for heating an environment according to any preceding claim, characterized in that said separation walls (3) are flat. 4. Convector panel (1) made of sheet metal for a radiator for heating an environment according to any preceding claim, characterized in that said separation walls (3) are coplanar. 5. Convector panel (1) in sheet metal for a radiator for heating an environment according to any preceding claim, characterized in that said first and second delimiting walls (4, 5) have the same height in an orthogonal direction to the plane of arrangement of said separation walls (3). 6. Convector panel (1) made of sheet metal for a radiator for heating an environment according to any preceding claim, characterized in that said first and second boundary walls (4, 5) have the same configuration. 7. Convector panel (1) made of sheet metal for a radiator for heating an environment according to any preceding claim, characterized in that said first and second delimiting walls (4, 5) have a rounded trapezoidal configuration. 8. Convector panel (1) made of sheet metal for a radiator for heating a room according to any preceding claim, characterized in that, for each channel (2), each pair of consecutive boundary walls (4, 5) has the ends longitudinal adjacent (4e, 5e) which join at the separation walls (3). 9. Radiator for heating an environment characterized in that it comprises at least one convector panel (1) made of sheet metal according to any preceding claim. 10. Radiator for heating a space according to the preceding claim, characterized in that said panel is applied vertically with the channels oriented horizontally. 11. Radiator for heating a space according to claim 9, characterized in that said panel is applied vertically with the channels oriented vertically. 12. Method for optimizing the efficiency of the convective exchange of a sheet metal convector panel (1) installed on a radiator for heating a room, called convector panel (1) comprising a plurality of parallel longitudinal channels (2), characterized by opening each channel (2) laterally along a succession of its longitudinal sections (8) separated and sized in such a way as to obtain the maximum turbulence with the minimum loss of flow due to the upward flow of air that is established in the channels (2 ) due to the natural convective exchange triggered by the convector panel (1). 13. Process for making a convector panel (1) for a radiator for heating an environment, characterized in that it comprises a step of shearing and bending a flat sheet (10) in which the bending lines (11) are parallel straight lines that delimit a succession of longitudinal sheet metal strips (12, 17), and the blanking lines (13) selectively affect groups of consecutive longitudinal sheet metal strips (12) which are divided by the blanking lines (13) into a longitudinal succession of cells (14, 15), the bending step being performed with bending forces orthogonal to the plane of the flat sheet (10) and operating in the opposite direction on the adjacent cells (14, 15) of each group of longitudinal strips ( 12) in such a way as to generate from each group of longitudinal strips (12) a corresponding channel (2) presenting alternately first delimiting walls (4) which develop from one side d el the plane of the sheet metal (10) and second boundary walls (5) which extend from the opposite side of the plane of the sheet metal (10).