WO2003042607A1

WO2003042607A1 - Heat transfer fluid radiator

Info

Publication number: WO2003042607A1
Application number: PCT/FR2002/003882
Authority: WO
Inventors: Henri-Louis Russi; Gérard GENIN
Original assignee: Henri-Louis Russi; Genin Gerard
Priority date: 2001-11-13
Filing date: 2002-11-13
Publication date: 2003-05-22
Also published as: FR2832212B1; FR2832212A1

Abstract

The invention concerns a radiator comprising a heating element (2) containing a heat transfer fluid volume (4). With said heating element (2) is associated an external heat transfer fluid circuit (5), starting from the base of said heating element (2) and returning to its top. On the circuit (5) are arranged an electrical circulator (8) and a heating cartridge (12) with electrical resistance (12). Thus the thermal efficiency of the radiator is enhanced. Said radiator is particularly useful for heating premises.

Description

Heat transfer fluid radiator

The present invention relates, in general, to the field of radiators used for space heating. It relates, more particularly, to a radiator of the so-called "heat transfer fluid" type.

A heat transfer fluid radiator has a heating body, usually consisting of the assembly of a number of vertical heating body elements. The heating body contains a certain volume of heat transfer fluid, which is heated by electric heating means. Such a radiator constitutes an autonomous heating appliance, producing the equivalent of a central heating radiator, but not requiring to be connected to a "central" or "collective heating network with boiler.

In their usual embodiment, heat transfer fluid radiators have, as electrical heating means, heating cartridges placed directly inside the heating body, in the lower part of the volume occupied by the heat transfer fluid. With such a solution, the heating is effected by convection only, inside the heating body. The heat transfer fluid is properly heated but, in the absence of sufficient circulation of this fluid, a large electrical power is necessary to diffuse a given thermal power. Thus, the current calorific fluid radiators remain, despite their recognized advantages such as autonomy and quality of heat accumulation, devices which consume a fairly high electrical energy, therefore devices which are of a rather low thermal efficiency, and whose use remains quite expensive.

The present invention aims to eliminate these drawbacks, by providing a heat transfer fluid radiator with higher thermal efficiency, that is to say requiring less electrical power for the same restored thermal power, therefore a radiator providing savings in electrical consumption. , while retaining all the advantages specific to this type of radiator.

To this end, the subject of the invention is a heat transfer fluid radiator, having a heating body containing a volume of heat transfer fluid, and comprising electrical heating means of the heat transfer fluid, this radiator being essentially characterized by the fact that it includes a heat transfer fluid circuit associated with the heating body, but outside this body heating, starting from the base of said heating body and returning to its top, circuit on which are placed an electric circulator and the electric heating means.

Thus, the inventive idea consists, in comparison with conventional heat transfer fluid radiators, of separating the part carrying out the storage and diffusion of heat, from the part carrying out the heating of the heat transfer fluid, while creating a forced circulation of this fluid, both in the heating body and in the external circuit, the heat transfer fluid being heated during its passage through the external circuit. In particular, the heat transfer fluid is circulated, in the external circuit, by the electric circulator, and it is heated as it passes through the heating means placed on the same external circuit, before returning to the interior of the body. heated.

The electrical heating means, placed on the external circuit traversed by the heat transfer fluid, advantageously consist of a heating cartridge containing an electrical resistance. In particular, this is a heating cartridge which comprises, around its electrical resistance arranged along its central axis, an annular space for circulation of the hawker fluid, of constant section, in which this fluid circulates in a laminar flow.

In a preferred embodiment of the invention, the assembly constituted by the external heat-transfer fluid circuit, by the electric circulator and by the heating cartridge is attached to the heating body, preferably at one end of this heating body, the heating cartridge surmounting the circulator, which makes said assembly particularly compact, and makes it possible not to modify the structure of the heating body.

The heating body usually being constituted by an assembly of vertical elements of heating body, arranged in line, the assembly constituted by the external circuit of heat transfer fluid, by the electric circulator and by the heating cartridge can be accommodated and concealed in an additional dummy element of the heating body, arranged at one end of the heating body, following the other elements of this heating body.

According to another characteristic, the external heat transfer fluid circuit is extended, at its termination at the top of the heating body, by a tube placed horizontally inside the heating body, at the top of the latter, and ensuring the distribution of the heat transfer fluid over the length of the heating body, in particular in the various vertical elements of this heating body.

Overall, this produces a heat transfer fluid radiator which, while remaining compact, simple and aesthetic, has a significantly improved thermal efficiency thanks to the circulation of the heat transfer fluid and its heating outside the heating element, in a high-efficiency heating cartridge, the electrical consumption of the circulator remaining negligible so that the overall energy balance remains particularly advantageous. The improvement in thermal efficiency results, in particular, from the configuration of the heating cartridge which provides direct heating of the heat transfer fluid, to a suitable temperature, while maintaining this fluid at a low pressure.

The invention will be better understood with the aid of the description which follows, with reference to the appended diagrammatic drawing representing, by way of examples, embodiments of this radiator with heat-transfer fluid:

Figure 1 is a perspective view of a heat transfer fluid radiator according to the present invention;

Figure 2 is a schematic front view of this radiator, with representation of its fluid and electrical circuits;

Figure 3 is a front view, partly in section and in exploded form, of another embodiment of the radiator object of the invention;

Figure 4 is a cross-sectional view of the heating cartridge, along IV-IV of Figure 3. As shown in particular in Figure 1, the heat transfer fluid radiator has a heating body 2, constituted in a manner known per se the assembly of vertical elements 3 of heating bodies, arranged in line. Thus, the heating body 2 defines an interior volume 4 (see also Figure 2), filled with an appropriate heat transfer fluid. According to the invention, the radiator also has an external circuit 5 of heat transfer fluid, which is attached to the heating body 2, at one end of this heating body 2.

The starting point of the external circuit 5 is a suction duct 6, connected to the base of the heating body 2, at the relevant end of this heating body 2. The suction duct 6 is connected to the inlet 7 of an electric circulator 8. The outlet 9 of the circulator 8 is connected, by a conduit 10, to the fluid inlet 11 of a heating cartridge 12. The fluid outlet 13 of the heating cartridge 12 is connected, by a rejection conduit 14, to the top of the heating body 2. The heating cartridge 12 contains an electrical resistor 15, equipped with a thermal fuse (not shown) intervening in the event of overheating thereof. The cartridge 12 itself is made of a material which is a good conductor of heat, for example aluminum, the fluid inlet 11 and the fluid outlet 13 being drilled respectively at the two ends of this cartridge 12.

The electric circulator 8 and the heating cartridge 12 are fixed to the relevant end of the heating body 2, the cartridge 12 surmounting the circulator 8.

FIG. 2 also represents, in the form of a block diagram, the electrical circuits of the radiator. The circulator 8 and the resistor 15 of the heating cartridge 12 are electrically supplied in parallel, from the alternating voltage of the network (220 volts), by conductors 16 suitably arranged. A safety thermal switch 17, fixed on the heating body 2 at an intermediate height (see also FIG. 1), is also provided to cut the supply of the electrical resistance 15, in the event of a predetermined limit temperature being exceeded , for example 70 ° C. Finally, the operation of the entire radiator is controlled by a thermostat 18 located remotely, inside the room to be heated by the radiator

At the top of the heating body 2, the rejection duct 14 is extended, inside this heating body 2, by a horizontal tube 19 which distributes the heat transfer fluid, over the length of the heating body 2, in the various elements 3 of this heating body 2.

The heating body 2 may include a last dummy vertical element (not shown in FIGS. 1 and 2), of external appearance identical to the other elements 3, but here serving to house and conceal the various components of the external circuit 5: circulator 8 , heating cartridge 12, connection conduits 6, 10 and 14, and electrical components (except thermostat 18).

The overall operation of the heat transfer fluid radiator, previously described, is established as follows: The electric circulator 8 being in operation, the heat transfer fluid is sucked at the base of the heating body 2, through the conduit 6, and this fluid is discharged, via the conduit 10, towards the heating cartridge 12. The fluid then crosses the cartridge 12, heating up in contact with the electrical resistance 15. Leaving the cartridge 12, the heated fluid travels through the rejection conduit 14 , then it enters the heating body 2 where it is distributed, by the tube 19, at the top of the different elements 3 of the heating body 2.

In the interior volume 4 of the heating body 2, the heat transfer fluid circulates slowly, from top to bottom, in the various elements 3. It cools there by yielding the heat which it received during its previous passage in the cartridge heating 12. Finally, reaching the base of the heating body 2, the heat transfer fluid is sucked back through the conduit 6, and so on ...

The balance obtained between the power of the electrical resistance 15 of the heating cartridge 12, the flow rate of the circulator 8 and the volume of heat transfer fluid to be displaced makes it possible to stabilize the maximum temperature of the heating body 2, an optimal temperature value being d 'approximately 55 to 60 ° C. The thermal contactor 17 cuts the power supply to the electrical resistance 15, when this temperature becomes unnecessarily high (a high operating temperature signifying a poor efficiency). The position of the thermal contactor 17, halfway between the rejection and the aspiration of the heat transfer fluid in the heating body 2, makes it possible to capture a significant value of the average temperature of the heating body 2. However, this thermal contactor 17 could also be placed on the heating cartridge 12.

With regard to the overall operation of the radiator, it will also be noted, with regard to the circulator 8, that it is better to have a fluid flow which is too strong than too low, so as to favorably influence the heating efficiency of the electrical resistance 15. In fact, a too low flow rate of the heat transfer fluid induces a high operating temperature, therefore a poor efficiency as already indicated above.

Of course, the overall operation of the heat transfer fluid radiator is also controlled by the thermostat 18, so as to operate this radiator according to the heating needs of the room concerned.

FIG. 3 represents, in more detailed form and in an "exploded" manner, another embodiment of this radiator with heat transfer fluid, the components corresponding to those previously described being designated by the same reference numerals. The external circuit 5 is here produced in a particularly simple and compact manner, the heating cartridge 12 being directly connected to the output of the circulator 8, without any interposition of any leads. This FIG. 3 also shows the dummy vertical element 20 of the heating body, which takes place after the ordinary elements 3 of the heating body 2 to accommodate and conceal the external circuit 5. It will be noted that, taking into account the configuration elements 3 of the heating body, the components of the external circuit 5 can take place, in part, in a recess of the last element 3, and for the rest, in the dummy element 20. In this latter embodiment, the compactness of the external circuit 5 provides not only an ease of accommodation of this circuit, but also an improvement in the yield, by minimizing the heat losses in said external circuit 5, therefore diffusion of a maximum of heat in the heating body 2.

In all cases, as illustrated more particularly in FIG. 4, the heating cartridge 12 forms, around the electrical resistance 15, an annular space 21 of constant section, which is delimited externally by the cylindrical wall of the heating cartridge 12, and inside which the heat transfer fluid circulates, from bottom to top, in a laminar flow symbolized by the arrow F (see also Figures 2 and 3). This conformation of the heating cartridge 12, and the laminar flow which results therefrom, ensure maximum efficiency of the heat exchange which occurs at the level of said heating cartridge 12. In comparison, a turbulent flow regime, such as it occurs in particular in the case of "coil" heating elements, is very unfavorable from the point of view of thermal efficiency.

It would not depart from the scope of the invention, as defined in the appended claims, by modifying the detail arrangement of the external heat transfer fluid circuit, or by modifying the detail of the electrical circuits, or even by designating the same device to radiators with more or less voluminous heating bodies, with more or less numerous heating body elements.

Claims

1 - Radiator with heat transfer fluid, having a heating body (2) containing a volume (4) of heat transfer fluid, and comprising electrical heating means (12, 15) of the heat transfer fluid, characterized in that it comprises a circuit (5) of heat transfer fluid associated with the heating body (2), but outside this heating body (2), starting from the base of said heating body (2) and returning to its top, circuit (5) on which are placed an electric circulator (8) and the electric heating means (12, 15). 2 - Radiator with heat transfer fluid according to claim 1, characterized in that the electrical heating means, placed on the external circuit (5) through which the heat transfer fluid, consist of a heating cartridge (12) containing an electrical resistance (15 ).

3 - Heat transfer fluid radiator according to claim 2, characterized in that the heating cartridge (12) comprises, around its electrical resistance (15) disposed along its central axis, an annular space (21) for circulation of the heat transfer fluid, constant section, in which this fluid circulates in a laminar flow (F).

4 - Heat transfer fluid radiator according to claim 2 or 3, characterized in that a thermal contactor (17) is fixed on the heating body (2), at an intermediate height, to cut the power supply to the electrical resistance ( 15), if a predetermined limit temperature is exceeded.

5 - Heat transfer fluid radiator according to any one of claims 2 to 4, characterized in that the assembly constituted by external circuit (5) of heat transfer fluid, by the electric circulator (8) and by the heating cartridge (12) is attached to the heating body (2), preferably at one end of this heating body (2), the heating cartridge (12) surmounting the circulator (8). 6 - Heat transfer fluid radiator according to claim 5, characterized in that, the heating body (2) being constituted by the assembly of vertical elements (3) of the heating body, the assembly formed by the external circuit ( 5) of heat transfer fluid, by the electric circulator (8) and by the heating cartridge (12) is housed and concealed in an additional dummy element (20) of the heating body, arranged at one end of the heating body (2), following the other elements (3) of this heating body (2).