ITMI20070188A1 - RADIATOR WITH IRRADIANT PLATE AND PROCEDURE FOR ITS REALIZATION - Google Patents

Description

Description of an invention patent in the name:

The present invention relates to an irradiating plate radiator and to a process for its realization.

As known there are radiators with radiating plate which are made by making grooves with a square section in the plate and, subsequently, by binding the ducts inside them by means of an adhesive.

Subsequently, to improve the heat exchange between the plate and the ducts, the grooves were made with a round section; the radiators made in this way therefore have plates with round section grooves inside which the ducts are bound by means of an adhesive.

However, even these radiators have numerous problems including the risk of ungluing of the ducts that can escape (at least partially) from the grooves and dimensional variations which, in addition to aggravating the risk of cleavage by stressing the glue, can generate creaking and noise.

In addition, due to the presence of the glue interposed between the plate and the ducts, the heat exchange between the aforementioned elements (plate and ducts) is not efficient.

The technical task proposed by the present invention is, therefore, that of providing a radiator with an irradiating plate and a process for its realization which allow to eliminate the technical drawbacks complained of of the known art.

Within the scope of this technical task, an object of the invention is to provide a radiator which does not present the risk of detachment of the ducts containing the heat-carrying fluid from the radiating plate.

Another object is to provide a radiator in which creaking and noise does not occur even in the presence of relative dimensional variations between the ducts and the radiating plate.

Not least object of the invention is that of realizing a radiator and indicating a process for making it which allows a very efficient heat exchange between ducts containing the heat-carrying fluid and the irradiated plate.

The technical task, as well as these and other purposes, according to the present invention are achieved by making a radiator and indicating a process according to the attached claims.

Advantageously, the radiator according to the present invention is modular, in the sense that two or more radiators according to the invention connected to each other can be used to make an irradiating surface having a predetermined size.

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

Figures 1 and 2 show the plate with which the radiator is made in a first embodiment respectively in front and side elevation;

Figures 3 and 4 show the radiator in the first embodiment respectively in front and side elevations;

Figures 5 and 6 show the plate with which the radiator is made in a second embodiment respectively in front and side elevation;

Figures 7 and 8 show the radiator in the second embodiment respectively in front and side elevation;

figure 9 shows a cross section of a radiator in correspondence with a duct containing the heat transfer fluid;

Figure 10 shows a cross section of a radiating plate at a groove; And

Figure 11 shows the radiator in a further embodiment in front elevation.

With reference to figures 3, 4 and 9, 10 a radiator with a radiating plate is shown in a first embodiment, indicated as a whole with the reference number 1.

The radiator 1 comprises a radiating plate 2 made of heat-conducting material such as, for example, a metal plate in aluminum, steel, etc.

The plate 2 is equipped (in the example shown in the figures) with two grooves 3 folded in a "U" shape, inside each of which a conduit 5 for containing a heat-carrying fluid is inserted; the ducts are made of a heat conducting material such as, for example, a copper, steel, aluminum, brass, bronze pipe, etc.

Each duct 5 has its own (external) surfaces placed in direct contact with the surfaces of the groove 3 in which it is inserted, without the interposition of adhesives; this makes it possible to make the heat exchange between the heat transfer fluid contained in the ducts 5 and the plate 2 very efficient.

Advantageously, the grooves 3 have the edges 6, in correspondence with their portion 7 open towards the outside, converging; in particular, as shown in Figure 10, the grooves are shaped like an arc of a circle.

Advantageously, the ducts 5 are inserted into the corresponding groove 3 by pressure and, preferably, by rolling.

This allows (as shown in figure 9) to insert each duct 5 inside the respective groove without it coming out of the same groove and, in addition, allows to deform the surface of the duct 5, bringing it into adherence to the surfaces of the groove 3 ; in this way the retention of the duct 5 in the groove 3 and the heat exchange between the heat transfer fluid contained in the duct 5 and the radiating plate 2 in which the grooves 3 are carved are further improved.

Furthermore, the radiator 1 comprises a first manifold 9 constrained to one end of the plate 2 by means of collars 10 integral with the same plate 2; this manifold 9 can be connected to the hot water supply system (for water radiators).

The ducts 5 are connected to the manifold 9; in particular the ducts 5 are U-folded and both ends of each duct 5 open into the manifold 9.

In this embodiment of the invention the manifold 9 is connected both to the water supply 12 and to the drain 13; in particular the supply 12 is connected to one end of the manifold 9 and the drain 13 is connected to the other end.

Figures 7, 8 show a radiator 1 having characteristics similar to those of the radiator shown in Figures 3, 4.

In addition, this radiator has a second manifold 15 placed at one end of the plate 2 opposite to that to which the first manifold 9 is connected.

The grooves 3 and the ducts 5 are straight and the ducts 5 are connected between the first and the second manifold 9, 15.

In this embodiment of the invention the manifold 9 is connected to the water supply 12 and the drain 13 is connected to the other manifold 15.

Figure 11 shows a further embodiment of the radiator according to the invention.

This radiator has characteristics similar to those of the radiators already described above, but as a heat transfer fluid it does not use the water of the diathermic oil in a closed circuit.

This radiator has one or two manifolds (in the example shown there is only one manifold 9) and the ducts 5 start from these manifolds and run inside the grooves formed in the radiant plate 2; in the example the grooves and ducts are U-folded, however it is clear that in an embodiment with two manifolds the grooves and manifolds are both straight and connected to each of the manifolds.

Furthermore, inside the manifold 9 there is an electric resistance 17 (immersed in the diathermic oil) of an armored and waterproof type, suitable for heating the heat transfer fluid (diathermic oil) contained in the ducts 5.

Of course, more than one electrical resistance can also be provided and these can be housed in a manifold, in both manifolds or even in the ducts.

The present invention also relates to a process for manufacturing an irradiating plate radiator.

The method consists in making grooves 3 in the plate 2; in the example of figures 1 and 2 the grooves are two in number and are folded into a "U" while in the example of figures 5 and 6 the grooves are four in number and are straight (it is however clear that in other examples the grooves are in different numbers depending on the number of ducts that must be fixed to the plate and can have a different conformation).

A conduit 5 for containing the heat-carrying fluid is then inserted in each of these grooves 3.

The ducts 5 are inserted into the pressure grooves 3, without the interposition of adhesives and, preferably by rolling, causing the ducts 5 to deform so as to make its walls adhere perfectly to those of the groove 3 in which they are inserted.

Of course, the manifold 9 is also constrained and is constrained to the duct.

The operation of the radiator according to the invention appears evident from what has been described and illustrated and, in particular, is substantially the following.

In the water radiator shown in figures 3, 4 the water enters the radiator through the supply 12 as indicated by the arrow F1, circulates in the ducts 5 (as indicated by the arrows F2), heating the radiating plate 2 and, after returning to the collector 9, comes out of the manifold 9 through the drain 13.

The operation of the radiator according to the embodiment shown in figures 7, 8 is similar to that described.

In this case the water enters through the supply 12 of the manifold 9 (arrow F1), passes through the ducts 5 (arrow F2), and exits from the drain 13 of the manifold 15 (arrow F3).

In the case of diathermic oil radiators (figure 11), however, operation occurs simply by activating the resistance 17 which heats up and heats the diathermic oil in which they are immersed.

The diathermic oil in turn heats the irradiating plate 2.

In practice it has been found that a radiator with a radiating plate according to the invention is particularly advantageous because it has a very high thermal efficiency and, at the same time, does not present the risk of detachment of the ducts from the grooves.

The radiating plate radiator and the process for its realization thus conceived are 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 requirements and the state of the art.

Claims (12)

CLAIMS 1. Radiator (1) with radiating plate comprising a radiating plate (2) which is equipped with at least one groove (3) inside which a conduit (5) containing a heat-carrying fluid is inserted, characterized in that said conduit (5) has its surfaces placed in direct contact with the surfaces of said groove (3) in which it is inserted, without the interposition of adhesives. 2. Radiator (1) according to claim 1, characterized in that said groove (3) has edges (6) in correspondence with its portion open towards the outside converging. 3. Radiator (1) according to one or more of the preceding claims, characterized in that said groove (3) is shaped like an arc of a circle. 4. Radiator (1) according to one or more of the preceding claims, characterized in that said duct (5) is inserted in said groove (3) under pressure. 5. Radiator (3) according to one or more of the preceding claims, characterized in that said duct (5) is inserted into said groove (3) by rolling. 6. Radiator (1) according to one or more of the preceding claims, characterized in that it comprises at least a first manifold (9) to which said duct (5) is connected. 7. Radiator (1) according to one or more of the preceding claims, characterized in that it comprises a second manifold (15), said duct (5) being connected between said first and said second manifold (9, 15). 8. Radiator (1) according to one or more of the preceding claims, characterized in that it comprises at least one electrical resistance (17) suitable for heating the heat-carrying fluid contained in said duct (5). 9. Radiator (1) according to one or more of the preceding claims, characterized in that said electrical resistance (17) is housed in at least one manifold (9, 15). 10. Process for manufacturing a radiator (1) with an irradiating plate consisting in making at least one groove (3) in the plate (2) and inserting in each groove (3) a conduit (5) for containing the heat transfer fluid, characterized by the fact that said duct (5) is inserted into the groove (3) under pressure, without the interposition of adhesives. Method according to the preceding claim, characterized in that the duct (5) is inserted into the groove (3) by rolling. 12. Process according to claim 10 or 11, characterized by the fact of binding to the plate (2) at least one manifold (9, 15} which is connected to the duct (5).