ITVI20130271A1 - VARIABLE POWER DEVICE FOR HOMOGENEOUS HEATING OF FLUIDS - Google Patents

Description

VARIABLE POWER DEVICE FOR HEATING

HOMOGENEOUS OF FLUIDS

The present invention generally refers to a variable power device for the homogeneous heating of fluids.

More specifically, the invention relates to a resistor device which, suitably made, has a considerable exchange surface with the fluid, so as to obtain instant and homogeneous heating of the fluid that passes inside the structure, maximizing the pressure drops. and also saving in terms of space and / or bulk. Hot water for sanitary uses is normally obtained by passing cold water through a plate heat exchanger, inside which a hot fluid is sent through a secondary circuit of the exchanger, in order to maintain a substantially constant temperature of the fluid in exit.

In fact, for such sanitary uses, it is preferable to keep the outlet water temperature constant, usually between 55 and 60 ° C, and, for many applications, it is preferable to directly heat the outgoing fluid flow, in order to avoid the use of containment tanks.

As previously mentioned, the use of plate heat exchangers makes it possible to obtain a rather efficient heat exchange and allows to supply a fairly considerable amount of hot fluid, however, using a minimum amount of fluid that is stored inside the exchanger. However, one of the major drawbacks in the use of heat exchangers for the supply of fluids and, in particular, for the supply of hot water, is determined by the fact that each time the tap is opened again the water flows out, for a certain period of time, at a substantially higher temperature than the predetermined one and this can constitute a danger for the user.

This happens because the heating fluid that is sent inside the heat exchanger must have a temperature of about 10-20 ° C higher than the preset one leaving the tap and, since, when the tap is closed, the water is present in the exchanger it is brought to the temperature of the heating fluid, when the tap is reopened, the water at the outlet has, for a certain time interval, a temperature 10-20 ° C higher than the predetermined one of 55-60 ° C.

This drawback can be limited by using a hot water tank or container (such as a pipe) placed between the exchanger and the tap; however, the use of this pipe results in considerable bulk and substantial production costs, which it is desirable to reduce or eliminate altogether.

Furthermore, by using this tank or pipe, the water that reaches the tap when it is opened, after a certain period of time from the last hot water withdrawal, will be substantially cold.

The present invention therefore intends to obviate the drawbacks of the prior art mentioned above and, in particular, the main purpose of the invention is to provide a variable power device for the homogeneous heating of fluids, which instantly supplies a flow that is always uniformly heated to one or more supplies, at a predetermined, controlled and substantially homogeneous temperature.

Another purpose of the invention is to provide a variable power device for the homogeneous heating of fluids, which can be used in combination with a heat exchanger, in order to obtain an extremely efficient and compact device, capable of delivering almost immediately a flow that is always uniformly heated.

Another object of the present invention is to provide a variable power device for the homogeneous heating of fluids, which allows to obtain a total heat exchange circuit, without the use of any reservoir and / or container of fluid, nor any connection between the resistive structure and the heat exchanger, minimizing the overall dimensions and saving in terms of time and / or fluid dispensed.

A further object of the invention is to provide a variable power device for the homogeneous heating of fluids, which is particularly effective, reliable, convenient and economical, with respect to the known art, and which can be used for any new or existing water supply. .

These and other purposes are achieved by a variable power device for the homogeneous heating of fluids, according to the attached claim 1.

Further detailed technical characteristics of the device object of the invention are reported in the dependent claims.

Advantageously, the device according to the invention allows a fluid to be quickly heated and an homogeneous and controlled temperature of the entire quantity of incoming fluid to be obtained instantly at the outlet, practically using a resistor made of a labyrinth, which functions as a heat exchanger. inside a total heat exchange device; the heat exchange takes place in practically instantaneous times, thus obtaining a consequent and significant saving in terms of fluid delivered and the time taken to heat a certain amount of fluid, compared to the known art.

Furthermore, it is not necessary to use tanks and / or containers to store the fluid to be heated, nor particularly long and / or bulky pipes.

Finally, the device object of the invention can be used in particular for the supply of domestic hot water, but can similarly be used for any other private and / or industrial use (for example, as a heat exchanger for plastic material molding machines) therefore it is necessary to have a continuous quantity of fluid at a homogeneous and controlled temperature value.

Further objects and advantages of the present invention will become clearer from the following description, relating to a preferred embodiment of the variable power device for the homogeneous heating of fluids, according to the invention, given by way of example and by way of example, and to the attached drawings, also provided purely by way of a preferred and non-limiting example, in which:

Figure 1 shows a schematic side view of a first embodiment of the variable power device for the homogeneous heating of fluids, according to the present invention;

Figure 2 shows a schematic side view of a second embodiment of the variable power device for the homogeneous heating of fluids, according to the present invention;

Figure 3 shows a schematic side view of a third embodiment of the variable power device for the homogeneous heating of fluids, according to the present invention;

Figure 4 is a partial exploded perspective view of a detail of the variable power device for the homogeneous heating of fluids, according to the present invention;

Figure 5 is a schematic longitudinal sectional view of the variable power device for the homogeneous heating of fluids of Figure 2, according to the present invention;

figure 6 is a schematic sectional view taken along the line VI-VI of figure 5;

figure 7 is a partial side view of a further embodiment of the variable power device for the homogeneous heating of fluids, according to the present invention;

Figure 8 is a plan view of the variable power device for the homogeneous heating of fluids of Figure 7, according to the present invention.

With reference to the aforementioned figures, the device according to the invention substantially includes an external tube 10 and a first perforated dissipator element 13, made of conductive material, preferably aluminum, inside which they are inserted, in order, starting from the periphery and proceeding towards the center of the device, a first interspace 11, a resistor 12, preferably embedded within an insulating layer normally made of compressed magnesium oxide, a second interspace 15 and a second heat sink element 16, star-shaped and made of material conductor, such as aluminum. The dissipator element 16 may also be absent, in which case a circular bottom is used in contact with the walls of the interspace 15.

The pipe 10 is connected to a further length of pipe 14, by means of a connecting ring nut and / or a suitable flange, for connection with the three-phase power supply and grounding cables 21 and the connection cables 20 to a possible thermocouple. insulation (if present).

Furthermore, the aforementioned tube 10 can be associated with one or more connectors 24 for distributing fluids, for example of the T-type, and / or with a support base 25 for the connection of a possible thermostat (the support base 25 is placed in particular on a copper pad in contact with the external heat sink element 13). The described structure allows to use, within the device for the homogeneous heating of fluids, according to the present invention, a series of possible temperature control points, using, for example, a safety thermocouple 17, placed on the wire or layer resistive 18, inside the resistor 12, and a series of containment elements 19 of respective bulbs placed inside the star dissipator element 16, inside the resistor 12 and on the external dissipator element 13, in contact with the fluid .

In particular, depending on the use, the device for the homogeneous heating of fluids, according to the present invention, can provide, firstly, the inlet of the fluid F1 from a lower lateral connector 24, the passage of the fluid F1 between the internal walls of the tube 10 and the external walls of the resistance 12 and, finally, the outlet of the fluid F1 from an upper connector 26, which is opposite to the piece of tube 14 carrying the power cables 21. In this case (shown in detail in the attached figure 1), the fluid temperature is equal to 200 ° C or 300 ° C and the flow rate is over 200 l./min. (so-called “mono-flow” or single circuit).

Alternatively, if the fluid F2 enters from an upper lateral connector 24, the aforementioned fluid F2 makes a first path in a certain direction, between the inner walls of the tube 10 and the outer walls of the resistance 12, up to bottom of the tube 10 provided in correspondence with the piece of tube 14, and, therefore, a second path, in the opposite direction to the previous one, inside the openings or holes 20 made in the external heat sink element 13, before emerging from the upper connector 26 .

In this case (shown in detail in figures 2 and 5 attached), fluid temperatures of 200 ° C or 300 ° C are reached and flow rates from 100 to 200 l./min. (so-called "bi-flow" or double circuit), with the further possibility of having a double modular power.

Still alternatively, it is possible to provide that the inlet of the fluid F3 occurs at an upper lateral connector 24, in such a way that the aforementioned fluid F3 flows in a first determined direction, between the internal walls of the pipe 10 and the external walls of the resistance 12, up to the bottom of the pipe, then flows in the opposite direction to the previous one, inside the openings or holes 20 made in the resistance 12, up to the other end of the pipe, and then again according to the aforementioned first determined direction, in contact with the central star heat sink element 16, to exit from a central duct 22 connected to a lower lateral connector 24.

In the latter case (shown in detail in the attached figure 3), fluid temperatures of 200 ° C and flow rates of 90 l / min are reached. (so-called “tri-flow” or triple circuit).

As clearly visible in the attached figure 4, the peculiarity of the homogeneous fluid heating device according to the present invention consists in the fact that the resistor 12 is not in contact with the fluid, but is in direct contact with the external heat sink 13 and with the heat sink central 16, if present; this causes the heat to be distributed by the heat sink element 13, 16 to the fluid at a very large surface, while the heat sink element 13, 16 also keeps the temperature low at the surface in contact with the fluid.

In this way, a considerably extended heat exchange surface is obtained, maximizing the load losses, maintaining a compact size of the structure and at the same time avoiding direct contact between the fluid and the resistance 12.

This allows the entire amount of inlet fluid to be brought, almost instantly, to a predetermined temperature (determined by the power of the resistance 12), homogeneous and controlled, and to obtain a uniformly heated flow at the outlet.

The resulting device is thus in practice a temperature "calibrator", capable of determining an evident saving in terms of time (to make the fluid reach a determined and controlled temperature value) and quantity of fluid, as it is not it is necessary to use a containment and collection tank for the fluid to be heated.

Finally, the structural composition described allows to avoid the complete destruction of the resistive component even in the case where there is an interruption in the flow of fluid, since the metal mass of the external structure is intimately attached to the annular resistance 12.

The resistive structure thus obtained can also be advantageously combined with a suitable heat exchanger for applications where electrical heating combined with effective heat dissipation is required (such as, for example, temperature control units in the molding of plastic materials). ; in this case, the tube 10 is inserted inside a container or shaped casing, preferably made of stainless steel, through the interposition of a prismatic block and a fixing flange.

According to a further embodiment of the present invention, shown in particular in the attached figures 7 and 8, the external heat sink element 13 can be constituted by a tube bundle which includes a series of hollow sections (the cavities of the sections identify and constitute the openings 20 mentioned above), each of which has the same predetermined section, such as a circular, rectangular or square section; in particular, these profiles each have a trapezoidal section and adhere laterally to each other in such a way as to obtain a maximum total contact surface.

Finally, again according to this embodiment of the heating device object of the invention, also the internal heat sink element 16 can be constituted by a tube bundle, which includes a series of hollow sections having the same characteristics as those mentioned in the case of the external heat sink 13; as already said previously, the internal dissipator 16 and, therefore, the relative tube bundle may not be present, in which case a bottom or cover cap is provided on the bottom of the structure. From the above description the characteristics of the variable power device for the homogeneous heating of fluids, which is the object of the present invention, are thus clear, as are the advantages.

Finally, it is clear that numerous other variants can be made to the device in question, without thereby departing from the novelty principles inherent in the inventive idea, just as it is clear that, in the practical implementation of the invention, the materials, the shapes and the dimensions of the illustrated details may be any according to requirements and the same may be replaced with other equivalent ones.

Claims (10)

CLAIMS 1. Variable power device for the homogeneous heating of fluids, characterized by the fact of comprising an external pipe (10), connected to a fitting or flange (14) for connection with the power supply and grounding cables (21) and to one or more connectors (24, 26) for the distribution of the fluid, which encloses a first perforated dissipator element (13), made of conductive material, inside which a first interspace (11) and a resistive element (12), of the wire or resistive layer type (18), embedded inside an insulating layer, so that said resistive element (12) is not in contact with the fluid, but is in contact with said first dissipating element (13), in order to distribute heat from said first dissipating element (13) to the fluid at an extended surface, said first dissipating element (13) also keeping the temperature low at the contact surface with the fluid. 2. Device as in claim 1, characterized in that, in contact with said resistive element and towards the inside of the tube (10), there is a second interspace (15) and at least one second shaped dissipator element (16), made made of conductive material, or a bottom or plug, placed in contact with the walls of said second interspace (15). 3. Device as per at least one of the preceding claims, characterized in that said tube (10) is connected to at least one support base (25) of at least one thermostat, said base (25) being placed on a pad made of conductive material contact with said first dissipating element (13). 4. Device as per at least one of the preceding claims, characterized in that at least one safety thermocouple (17) is placed on said resistive wire or layer (18), inside said resistive element (12). 5. Device as per at least one of the preceding claims, characterized in that a series of containment elements (19) of respective temperature control bulbs are placed inside said second heat sink element (16), inside said resistive element (12) and on said first dissipator element (13), in contact with the fluid. 6. Device as per at least one of the preceding claims, characterized in that said fluid (F1) enters inside said tube (10) through one of said distribution connectors (24, 26), passes between the internal walls of said tube (10) and the external walls of said resistive element (12) and exits from said tube (10) through one of said distribution connectors (24, 26). 7. Device as per at least one of the preceding claims, characterized in that said fluid (F2) enters inside said tube (10) through one of said distribution connectors (24, 26), completes a first path in a given towards, between the internal walls of said tube (10) and the external walls of said resistive element (12), up to an end portion of the tube (10), and, therefore, a second path, in the opposite direction to said first path , inside openings or holes (20) made in said first dissipating element (13), before coming out of said tube (10) through one of said distribution connectors (24, 26). 8. Device as per at least one of the preceding claims, characterized in that said fluid (F3) enters inside said tube (10) through one of said distribution connectors (24, 26), flows in a first determined direction, between the internal walls of said tube (10) and the external walls of said resistive element (12), up to a first terminal portion of said tube (10), then flows in a direction opposite to said first determined direction, inside of openings or holes (20) made in said resistive element (12), up to a second terminal portion of the tube (10) opposite to said first terminal portion, and then again according to said first determined direction, in contact with said second element dissipator (16), to finally exit from a central duct (22) connected to one of said distribution connectors (24, 26). 9. Device as per at least one of the preceding claims, characterized in that said first heat sink element (13) is constituted by a tube bundle, which includes a series of hollow sections, each of which has the same predetermined section and, in particular, a same trapezoidal section, so that said sections adhere laterally to one another and thus an extensive total contact surface is obtained. 10. Device as per at least one of the preceding claims, characterized in that said second dissipator element (16) consists of a tube bundle, which includes a series of hollow sections, each of which has the same predetermined section and, in particular, a same trapezoidal section, so that said sections adhere laterally to one another and thus an extensive total contact surface is obtained.