RU2458286C2 - Modular heat-exchanging system - Google Patents

Abstract

FIELD: machine building. ^ SUBSTANCE: modular heat-exchanging system is connected to the wall (S) of air conditioned room and includes heat-exchange modules (1) each of which has tile (101) provided inside the pipelines (C) for conditioning fluid passing. The above pipelines (C) go through the holes (B) at connecting sides (220) of the said tile (101). Fixing items (19; 419) are for connecting two heat-exchange modules (1) that are adjacent and located in contact along the related connected sides (200) in assembled condition (AS) and connecting items (14; 414) for air-tight connection of the said holes (B) of two above neighbouring heat-exchange modules (1). Note that each heat-exchange module (1) has at least socket (13, 13') at each connecting side (200) that includes at least one of the said holes (B) and configured in such a way to form a cavity (130; 430) in the said assembled condition (AS) with similar socket (131, 13) of neighbouring heat-exchange module (1) which is opened and assembled to receive the said fixing items (19; 419) and said connecting items (14; 414). ^ EFFECT: possibility to attach heat-exchange modules to walls independently. ^ 34 cl, 19 dwg

Description

The invention relates to a sectional, modular type heat exchange system with limited overall dimensions, which is intended primarily for room air conditioning.

Known modular heating systems, the so-called radiating floor heaters, formed from flat and thermally insulated modules facing the floor, equipped with devices for quick and removable interconnection to form a coating or panel with the required dimensions and shape. Such modules have an upper front surface made of a material with good thermal conductivity, usually metal, and are also coated with a material having good heat dissipation properties from a surface that can allow a person to move along it, and has corresponding mechanical strength and aesthetic qualities.

A radiant floor heater made in this way has modules installed to produce heat by using combined electrical resistances, which are fed, for safety reasons, with a low voltage current.

Alternatively, the modules contain on the inside channels or pipes made with an external metal coating, which in this case are covered by a surface on which to walk, pipes of the type used for room floor heating, in which a liquid, such as glycolated water, circulates at low pressure and temperature no higher than 40 ° C, for example, from a heat exchanger and heat pump, which in the summer can also be used to cool a room with a ventilation coil blowing and / or drainage systems.

The above radiating floor heating systems, for example, designed for conference rooms, exhibition stands, outdoor events or for places of artistic, cultural or monumental interest, such as churches, museums, historical buildings, art galleries and other places where spaces, which must be conditioned, often contain extensive horizontal and vertical areas, as well as for places where it is necessary to limit the height of the convection conveying to a few meters s that lift up air pollutants.

Radiant floor heating systems with electrical resistance have a high consumption of electrical energy, since heat is generated by the thermal action of the current. In addition, electrical transformers designed to generate low voltage and very high electric currents are needed in order to achieve the power needed to power very large flat surfaces.

With this solution, it is difficult to combine the suitability of the floor for walking on it with good thermal conductivity, while electromagnetic pollution is inevitably produced due to the supply of alternating electric current.

In addition, the system requires careful selection of materials and the use of expensive refractories in order to avoid fire caused by electric heating resistances, which as a result of local damage can cause overheating and arc discharges.

Such deficiencies are overcome by radiant floor heating systems with pipes for circulating liquids, the pipes of which can also be used to cool the surrounding area.

However, such systems are not suitable for heating systems that also use gas boilers, which are usually installed in buildings, the boilers of which generally do not use a process step in which liquid is supplied at low pressure.

Another disadvantage of heat exchange systems using liquid circulation is the fact that, due to the connection between the pipes, the modules become very complex and time-consuming to assemble and disassemble. In particular, the above-described modules cannot be dismantled separately, for example, in case of damage, but only in groups, thus requiring time and increasing cost.

In addition, the above-described modules embedded in the supporting structure, fluid circulation pipes and a walkable coating are very complex and expensive to manufacture.

In order to limit the thickness of the modules, the pipes for the circulation of the liquid basically have a reduced diameter, thus causing small values of the conditioning fluid flow, and, conversely, large load losses.

In addition, both known radiating floor heating systems are not suitable for placement in other places except on the floor, for example on vertical walls and ceilings.

The objective of the present invention is to improve modular heat exchange systems for air conditioning of buildings, in particular, increasing the versatility and flexibility of their application.

Another task is to obtain a modular heat exchange system, the heat exchange modules of which can be assembled together and subsequently disassembled in a quick, simple and easy way, separately and independently from each other.

An additional task is to produce a modular heat exchange system that provides effective and durable sealing between the pipes of various heat exchange modules, even if the fluid is supplied at high pressures and temperatures.

Another task is to obtain a modular heat exchange system that allows high values of the flow of conditioning fluid inside the heat exchange modules and reduces load losses.

Another objective is to invent a modular heat exchange system equipped with heat exchange modules having a simple, robust and cheap design.

Another additional task is to obtain a modular heat exchange system, which can be assembled in such a way as to form modular panels of the desired shape and size that are applicable to any wall of the surrounding space that needs to be conditioned.

Another task is to create a modular and composable heat exchange system with liquid circulation, which has great technological reliability, can be equally installed on the floor, wall or ceiling and can be reliably covered with traditional coatings, such as gypsum board panels, ceramic tiles.

The first object of the invention is a modular heat exchange system that connects to the wall of an air-conditioned room, containing heat exchange modules, each of which contains a tile, provided with piping for the passage of conditioning fluid from the inside, the above-described pipelines (C), which are passed through openings on the connecting sides of the above-described tiles , fixing means for connecting two heat-exchange modules, which are adjacent and are located in mutual contact l the respective adjacent sides in the assembled state, connecting devices for waterproofing the connection of the above-described openings of two adjacent above-described heat-exchange modules, characterized in that each heat-exchange module contains on each connecting side at least one socket containing at least one of the above holes and configured in such a way as to form, under the above-described assembly conditions, with a similar socket of an adjacent heat exchange module awn which is open and is configured for receiving the above-described fixing means and the above-described connecting devices.

The connecting devices comprise a connecting element having a shape that is complementary and can be inserted into the above-described cavity, while provided with through-holes for allowing fluid to flow to connect the corresponding holes of two adjacent heat-exchange modules described above.

When the fixing means are located inside the cavity, it can be driven in such a way that, with the possibility of forward and reverse, to fix together the two heat-exchange modules described above. The locking means comprise, in particular, a locking sleeve that is rotatably mounted in the central recess of the connecting element and provided with mating means arranged for engagement in a fixed position using additional mating means of the above-described sockets.

The abutting means and / or additional abutting means are formed in such a way that when the above-described locking sleeve rotates from the inserted position in which the above abutting means are released from the above additional abutting devices into a locked state in which the adjacent heat exchange modules are gradually fastened together and attached to the above connecting element.

In this way, a plurality of heat exchange modules 1 can be joined together and modular panels having various shapes and sizes can be composed.

The modular heat exchange system of the invention, due to the advantages of the arrangement of heat exchange modules and corresponding connecting and fixing means, makes it possible to assemble the heat exchange modules in a quick and easy way, which makes it possible to independently mount the heat exchange modules on the room wall, and then they can be connected and fixed together. When the heat exchange system has been installed so as to form a modular panel of the desired shape and size, it is possible to dismantle the heat exchange module separately equally quickly and easily, for example, by moving the modules, without having to dismantle the adjacent heat exchange modules.

The heat exchange system thus provides a simple, quick and cheap assembly / disassembly procedure.

In addition to this, connecting and blocking means provide effective and reliable insulation between the pipelines of various heat exchange modules, as well as with conditioning fluid supplied at high pressure and temperature.

The modular heat exchange system of the invention has great technological reliability, can be installed equally successfully on the floor, wall or ceiling and can be coated with a traditional coating, for example, gypsum board panels or any other suitable material, ceramic tile or other type of tile.

The second object of the invention is a modular heat exchange system, which is connected to the wall of an air-conditioned room, containing heat exchange modules, each of which contains a tile, inside which pipelines for the passage of conditioning fluid are provided, while the above-described pipelines (C) pass through openings on the connecting sides of the above-described tiles, characterized in that the above-described pipelines are made in such a way that they are completely formed in the above-described tile.

Pipelines contain, in particular, longitudinal walls, which are located in relief on the rear outer side of the above-described tiles. Overlapping devices are mounted on the longitudinal walls to overlap and form pipelines.

Thanks to this object of the invention, it is possible to obtain a modular heat exchange system, the heat exchange modules of which can be easily and quickly manufactured, for example, by injection molding from a metal with good thermal conductivity, in particular from an aluminum alloy, thereby significantly reducing the cost of production. It is also possible in this way to obtain pipelines with a rectangular cross section of large sizes, making possible high values of the flow of conditioning fluid obtained by reducing load losses. A greater fluid flow leads to higher heat transfer rates and, consequently, higher performance of the heat exchange system.

A third object of the invention is a heat-emitting panel that connects to a heat exchange module of a heat exchange system connected to the wall of an air-conditioned room, the panel comprising a plate provided with an inner surface that is opposite to the outer, radiating surface of the heater, with a plurality of elongated partitions.

The attachment devices are located on the inner surface to attach the heat-emitting panel to one or more heat exchange modules.

The heat-emitting panel is made of metal, in particular aluminum alloy.

As soon as the heat-emitting panel is mounted on the corresponding heat-exchange module, the heat-radiating panel heats up quickly, due to the good thermal conductivity of the metal. Partitions form many channels, inside which the air is heated or cooled and spreads into the surrounding space with the help of convective motion, providing a significant and effective heat exchange of the heat exchange module.

The outer radiating surface of the panel may also emit heat propagating through radiation.

The invention will be better understood when referring to the accompanying drawings, which illustrate an embodiment of the invention as a non-limiting example, in which:

figure 1 is a schematic front view of a modular heat exchange system of the invention mounted on the wall of the room;

FIG. 2 is a perspective view of a heat exchange module of a heat exchange system of the invention; FIG.

figure 3 and 4 illustrate the details of the heat exchange module of figure 2, shown in cross section, respectively, along the line III-III and line IV-IV of figure 2;

5 is a top view of the inner face of the heat exchange module with a pipeline blocked by a corresponding overlapping element;

6 is a section along the line VI-VI of the details of the module of figure 5;

7 is an incomplete perspective view of a heat exchange module in which the connecting and fixing devices are shown in a disassembled state;

Fig. 8 is an incomplete top view and a partial cross-sectional view of the outer front surface of two adjacent heat exchange modules, which are mutually connected and connected to the connecting and fixing devices of Fig. 7;

Fig.9 is an enlarged view from below and in perspective of the locking sleeve for locking the locking devices of Fig.7;

10 and 11 are enlarged partially cut views along, respectively, lines X-X and lines XI-XI of FIG. 8;

Fig.12 is an enlarged section along the line III-III of Fig.2;

FIG. 13 is a perspective view of a version of a heat exchange module, connecting and fixing devices of the modular heat exchange system of FIG. 1;

Fig.14 is an enlarged partial view of the part shown in Fig.13;

Fig. 15 is an enlarged partial perspective and bottom view of the heat exchange module, the connecting and fixing devices of Fig. 13;

Fig is a partial top view and partially cutaway view of two adjacent heat exchange modules that are mutually connected and connected by connecting and fixing devices;

Fig.17 is an enlarged partial section along the line XVIII-XVIII in Fig.16;

FIG. 18 is a perspective view of radiating devices used in the heat exchange module of FIG. 13;

Fig. 19 is a perspective view of the radiating devices of Fig. 18.

Fig. 1 shows a heat exchange system comprising a plurality of heat exchange modules 1 that are connected to each other and connected in such a way as to form a modular panel, i.e. a chain or mosaic, which can be located on the wall S of the room, for example a colder wall facing out, to create suitable temperature conditions in the room, taking into account the volume of the building and its purpose, as well as taking into account the presence of doors, windows and possible equipment, which can be installed opposite the above wall S.

The modularity of the heat exchange system 100 makes it possible to create a heat exchange panel, which is formed according to customer requirements, and will meet the requirements necessary for an air-conditioned room. The heat exchange system 100 is applicable not only to the surfaces S of the walls, floors or ceilings of the building, but also to any supporting surface intended for placement in any room that needs to be thermally conditioned.

The heat exchange modules 1 are arranged for individual fastening to the wall S, or to the ceiling, or to the floor of the building, or to the assembly sections of the aforementioned building, as explained in detail below in the description.

The heat exchange modules 1 can, for example, have a square or rectangular shape or other shape suitable for creating a chain or mosaic composition, and are provided with channels or pipelines “C” in the interior for circulation of a temperature-regulating fluid located or passing on opposite and / or the following one after the other side of the above modules.

Locking devices are designed for connecting and fastening two-way way of two heat exchange modules 1, which are adjacent in the assembled state.

The connecting means are designed to tightly connect the ends of pipelines “C” of two adjacent heat exchange modules 1 so that after assembly of the heat exchange system 100 in the form of a modular panel, a circuit C 'is formed for the circulation of the conditioning fluid.

The circuit C 'can be powered from any suitable source and connected, for example, to a suitable pipeline D of a known type and not shown in detail in the drawings, the circuit can be made as a whole or mounted from one or more heat exchange modules 1 for connection to fluid circulation devices, which are also devices of a known type and are not shown in the drawings.

Depending on the purpose of use for which the modular panel 100 is formed, the heat exchange modules 1 can have pipelines C having a shape that corresponds to different methods: straight pipelines open from opposite sides of the same module, intersecting pipelines open from four sides of the module , "T" -shaped pipelines open on three sides, for example, on the consecutive sides of the module, "L" -shaped pipelines open on two consecutive sides of the same mode lei.

Figure 2-6 shows the heat transfer module 1 of the heat transfer system 100 of the invention, made with straight pipelines, the design features of which are also applicable to other types of heat transfer modules made with pipelines having various configurations.

The heat exchange module 1 comprises a tile 101 made, for example, of metal, in particular of an aluminum alloy, made, for example, by injection molding. The tile 101 is provided with a protruding and continuous edge 201 along the entire perimeter, which forms the inner or rear inner surface 101b of the box-shaped module 1, suitable for receiving an insulating layer 2 of heat-insulating material with good resistance to compression. The insulating layer 2 combines the relief parts made on the above-described rear outer surface of the heat exchange module 1, and protrudes from the edge 201 to a specific area, for example, hanging over it.

The heat exchange module 1 is placed in contact with the wall or surface S of the building with the inner surface 101b, supporting the insulating layer 2 so that the front face radiating surface 101a, which is opposite to the above inner surface 101b, covers the air-conditioned room and the conditioning heat is not released / not removed from the wall S of the room.

On the inner surface 101b of the heat exchange module 1, the longitudinal walls 3 of the conditioning pipes C for circulating liquid are made in the form of monoblocks, which may be, for example, at least two or more, and thus, it is not necessary that there are four of them, as shown figure 2 and 5.

The ends of pipelines C extend into corresponding cutouts or holes B at the edges 201 of module 1.

The pipelines C are arranged so that they are closed at the bottom of the module 1, and their cylindrical shape is thus determined by the overlapping elements or the bottom 4, hermetically applied and attached with a suitable adhesive or adhesive.

The overlapping elements 4 are arranged longitudinally with edges having a profile 104 with grooves that are connected at the edges of the walls 3 of pipelines C (Fig. 6). The ends of the overlapping elements 4 contain flat parts 204 that are supported on the steps 5 and attached to them, the steps being made at the bottom, in the perimeter region of the heat exchange module 1, in which the holes B of the above-described pipelines C are made.

The use of monoblock longitudinal walls made on tile 101 makes it possible to manufacture pipelines C with a large, for example, almost rectangular cross-section, in order to have high flow rates of conditioning fluid with reduced load losses. A larger fluid flow entails higher rates of heat exchange and, therefore, higher performance of the heat exchange system.

As shown, in particular, in FIGS. 5 and 6, the overlapping elements 4 are mechanically reinforced by external ribs 6, for example, in the form of a grating or other suitable shape.

Similarly, additional ribs 106 of any suitable shape are formed on the inner surface 101b of tile 101. The above-described additional ribs 106 are attached to the perimeter edge 201, as well as to the longitudinal walls 3 of conduits C and comprise a plurality of conical protrusions 7, each of which forms on the front face surface 101a tiles 101, lining the room, the corresponding nest or cavity 8.

The aforementioned cavities 8, having, for example, a circular cross section, form a protrusion 7 and are preferably open by the corresponding bottom opening 108. The bottom openings 108 allow coating means P and / or radiating devices 60 to be attached to the outer surface of the heat exchange module 1.

In the cavities 8, glue 9 is dispensed, for example, on a silicone base, which can be used for fixing in the bottom hole 108 and attaching to the mosaic tiles 101 of the modules 1, covering means P containing tiles P or other suitable covering material.

Some of the cavities 8 can be used differently to attach the heat exchange modules 1 of the heat exchange system 100 to the room wall S with suitable screw anchor bolts 10. Such screw anchor bolts 10 have a first part 110 that is mushroom-shaped and made of a suitable rigid plastic, the first the part is inserted into the cavity 8 until it reaches the wall S, after which it is crossed by the clamping screw 210. In addition, the screw anchor bolts have a protruding part 310, which can deform when the above-described bolt 210 advances, and which engages with a hole 11 made in the wall S by a drill that is inserted through the bottom hole 108 of the cavities 8. The mushroom portion 110 acts as a spacer sleeve, so that it is positioned so that it does not enter the hole 11, and limits the compression process exerted on the heat-insulating layer 2 by the axial stress of the clamping screw 210 (figure 4).

Spacer sleeves 12 can be attached to the bottom of the protrusions 7 of the cavities 8 and inserted, for example, by means of a snap-in headset into the hole 108, while they are arranged so as to lean on the wall S of the room without forming thermal bridges towards the outside (Fig. 12) . When the heat exchange modules 1 are placed on the floor, the spacer sleeves 12 prevent the loads exerted on the heat exchange modules when people are walking and objects subjecting the insulating layer 2 to excessive and non-distributed pressure on the surface, which can expose the modular panel formed by the heat exchange modules 1 to uneven voltage, especially to connecting devices.

Spacer sleeves 12, which, for example, are made of suitable rigid plastic, can be provided with a through axial cavity 112 in order to be effectively fixed with fixing adhesive 9.

Spacer sleeves 12 can also be axis-adjustable, which, for example, contains a screw and a nut, so that the sleeve has the ability to touch the wall S of the room selectively, and also when the wall S is not flat enough, for example, having uneven surfaces.

In the case of the heat exchange module 1 shown in the figures, the openings B of the ends of the pipelines C extend to the side walls 113 of the recessed sockets 13, made on two connecting sides 202, which are parallel and opposite to the heat exchange module 1. Such sockets 113, for example, are two in number each connecting side 202, and with each of them are connected two holes B.

Each rectilinear nest 13 is open upward and on the side opposite to the side wall 113, while it is closed below the bottom wall 213.

Assembled AS, in which two heat exchange modules 1 are arranged side by side and correctly aligned in a row for mutual fastening, the socket 13 of the heat exchange module 1 is opposite to the socket 13 'of the adjacent heat exchange module 1 (Fig. 8) to form a socket or cavity 130 that is open only on one side perpendicular to the modules on the outer faces 101a of the aforementioned heat exchange modules 1.

The connecting means 14 are inserted into the aforementioned cavity 130 for hermetically connecting the holes B directed by the front side and opposite to the pipelines C of the above-described heat exchange modules 1.

The connecting means 14 comprise a tab or connecting element which rests on the bottom walls 213 of the sockets 13, 13 'and which has through holes 15 having the shape and dimensions of the openings B of the piping C. The above-described through holes 15 are furthermore arranged appropriately to connect by means of a jumper when the above-described connecting element 14 is correctly inserted, the openings B of the pipes C. The sealing gaskets 16 are installed frontally around the above-described through-holes 15 to provide a seal chnoe In connection with the holes (10).

The connecting element 14 is provided with an intermediate part of the Central cutout 17, which is suitable for accommodating the corresponding locking sleeve 19 of the fixing means.

The central cutout 17 has an enlarged upper portion 117 and a bottom wall in which a protrusion 18 is provided in a central position, having a substantially circular shape, in which the lower cylindrical sleeve of the tank 119 or the locking sleeve 19 with a circular flat surface can be rotatably placed, the housing of the tank or locking sleeve 19 is rotatably engaged with the above-described central cutout 17. The above locking sleeve 19 includes a flange or upper shelf 219 which engages the extension the upper upper portion 117 of the central cut-out 17, and two protruding elements 319, 319 'protruding laterally from the lower part of the housing of the above-described locking sleeve 19. The above-described protruding elements 319, 319' are 180 ° identical and opposite to each other and are provided with a corresponding through hole 20 .

During the installation step, when the connecting element 14 is inserted into the cavity 130, i.e. in the slots 13, 13 'of two adjacent and adjacent to each other heat exchange modules 1, the protruding elements 319, 319' of the locking sleeve 19 are placed in the slots or side recesses 21, 21 'of the above-described connecting element 14, while open on opposite sides of the connecting element 14 (Fig.7 and 8), the locking sleeve 19 is installed in the inserted position M.

In this position, during the assembly phase, it is possible to insert the connecting element 14 and the corresponding connecting sleeve 19 into the opposite sockets 13, 13 ′ of two adjacent heat exchange modules 1, while they will be connected to each other as if they were a single unit.

The lateral and central cutouts 22, 22 ', having a flat shape in the form of a circular sector, are provided on each respective socket 13, 13'.

Assembled AS, the side cutouts 22, 22 ′ of two adjacent sockets 13, 13 ′ form, with a central cut-out 17 of the connecting element 14, a complete nest having a circular shape for the locking sleeve 19.

Each lateral cutout 22, 22 'contains corresponding upper extensions 122, 122', which are practically aligned and lie in the same plane with the expanded upper section 117 of the central cutout 17 of the connecting element 14 in assembled form AS, and arranged to receive the upper flange 219 retaining bushings 19.

Each upper extension 122, 122 'also has a corresponding lateral intermediate extension 222, 222' provided with a corresponding vertical through hole 23.

Each side cutout 22, 22 'has a corresponding side wall provided with an additional slot or recess 24, 24', which also has a circular shape, and which is located at a given angle and faces the corresponding recess 21, 21 'of the connecting element 14.

The additional recesses 24, 24 'of the adjacent sockets 13, 13' are shaped so as to enable the connecting element 14 when it is inserted into the cavity 130, i.e. in the above-described sockets 13, 13 ', rotate the locking sleeve 19 through 90 ° from the inserted position M to the locked position L. In this case, the protruding elements 319, 319' are disengaged from the recesses 21, 21 'of the connecting element 14 and inserted into additional the recesses 24, 24 'of the cutouts 22, 22' until the locked or closed position L is reached, in which the through holes 20 of the protruding elements 319, 319 'are practically aligned with the through holes 23 of the heat exchange modules 1.

In this locked position L, the locking sleeve 19 is forced to move to the heat exchange modules 1 under the action of the protruding elements 319, 319 'and at the same time blocks the connecting element 14 in the sockets 13, 13', firmly connected together of the heat exchange modules 1, which remain in the same plane .

In addition, it is possible to firmly fix the locking sleeve 19 in the locked position L by inserting rivets or screws 27 into the line holes 20, 23, as schematically indicated by a dash-dot line in FIG. 11.

Fig. 9 shows a locking sleeve 19 provided with mating means, comprising two lower cavities 25, 25 'that are symmetrical to each other, the corresponding outer walls 125, 125' of which are in the form of an eccentric, i.e. variable thickness so that you can make the profile of an eccentric or cam. When the connecting element 14 and the locking sleeve 19, while in the inserted state M, are inserted into the cavity 130 formed by two opposite sockets 13, 13 ′ of the respective heat exchange modules 1, the lower cavities 25, 25 ′ are engaged by additional connecting means containing protruding parts or protrusions 26, 26 'made at the bottom of the side cutouts 22, 22' of the sockets 13, 13 'and performing the function of a valve.

When the locking sleeve 19 is rotated ninety degrees into the locked position L to attach the connecting element 14 to two adjacent heat exchange modules 1, the protrusions 26, 26 ′ are gradually engaged by the eccentric outer walls 125, 125 ′ of the lower cavities 25, 25 ′ of the locking bushings 19 (Fig. 11); this causes a twisting or clamping torque applied to the above locking sleeve 19 to transform it into a pulling force that pushes the heat exchange modules 1 against the connecting element 14 and against each other. This compressive force provides an effective and tight connection between the holes B of the piping C and the through holes 15 of the connecting element 14, with the corresponding compression of the gaskets 16 (Fig.10).

This compound has proven to be reliable as well as able to withstand very high pressures when circulating conditioning fluid.

In order to rotate the locking sleeve 19, a locking sleeve 19 is provided that is opposite to the lower hub 119 with a hexagonal socket 28 into which a corresponding hex wrench can be inserted.

As shown in FIG. 7, in order to facilitate insertion and removal of the connecting element 14 in and out of the cavity 130, i.e. opposite sockets 13, 13 'of two adjacent heat exchange modules, the end walls 114 of the above connecting element 14 may be slightly hidden or taper down. Similarly, the additional end walls 313 of each socket 13 may be slightly hidden or deviate from the bottom wall 213.

Using the procedure described above, it is possible to connect together a plurality of heat exchange modules 1 and create modular panels having various shapes and sizes.

The heat exchange system 100 of the invention, due to the arrangement of the heat exchange modules 1 and the corresponding connecting devices 14, as well as the fixing means 19, makes it possible to assemble the heat exchange modules 1 in a quick and easy way that allows them to be mounted independently from each other to the room wall S, and then connected and fix them together using the connecting means 14 and the fixing means 19. Similarly, when the heat exchange system 100 is assembled by forming a modular panel of the desired shape and size, it can be equally fast and in a simple way, separately remove the heat exchange module 1, for example, in order to replace it, without having to dismantle the adjacent heat exchange modules.

The heat exchange system 100 thus provides very simple, quick and cheap assembly / disassembly procedures.

In addition, the connecting means 14 and the fixing means 19 provide effective and durable sealing between the pipelines C of the various heat exchange modules 1, as well as the conditioning liquid supplied under high pressure and at high temperatures, for example, if the modular heat exchange system is connected to a boiler operating under high pressure.

The modular heat exchange system, as disclosed in the description, can be equipped with devices of a known type, not shown in the figures, which provide forced or natural circulation in the piping C of the heating or cooling fluid.

Such devices include boilers, heat pumps, heat exchangers, or the like.

The heat exchange system 100 of the invention can be additionally used as a simple radiator, or heater, visually attached to the wall of the room, or as a solar panel to produce hot water using solar radiation, in which case the coating means P are made suitable for absorbing sunlight.

13-17, a version of the heat exchange system 100 of the invention is shown, which differs from the previously described embodiment of the invention in a different configuration of the fixing means 419, the connecting means 414 and the sockets 413, 413 'of the heat exchange modules 1.

The connecting means 414 comprise an insertion or docking element, which is basically identical to those described above, and is provided with through holes 415 of such a shape that it can be inserted into the cavity 430 formed by two opposite sockets 413, 413 'of the two adjacent heat exchange modules 1.

These sockets 413, 413 'are located, for example, on two parallel and opposite connecting sides 202 of each heat exchange module 1, two on one side.

Each socket 413 comprises a through recess provided by a transverse wall 513, in which, for example, two holes B of the pipe C are open, and provided with two front and opposite end walls 520 to form corresponding steps. The end walls 520 are arranged to engage the assembled state AS with additional end walls 420 of the connecting member 414 to support the connecting element 414. The additional end walls 420 are shaped to complement the end walls 520.

The connecting element 414 further comprises a central through hole 425 in which the locking sleeve 419 of the locking means is rotatably inserted.

The locking sleeve 419 includes a flange or outer shelf 519, which is attached using a central pin 525 to a transverse tile 526 having an almost rectangular elongated shape.

The flange 519 has a circular bulge 527 in the lower part, while the transverse tile 526 has a joining means 528, at the opposite ends containing corresponding protrusions.

The locking sleeve 419 consists of two pairs so that it can be mounted / removed on the connecting element 414, and the central pin 525 is rotatably inserted into the central through hole 425. In particular, the flange 519 and the pin 525 are separate parts and are connected to the transverse tiles 526, for example, using a screw.

Alternatively, the central pin 525 can be formed in two parts, each of which is made as a separate part, respectively with an external flange 519 and with a transverse tile 526.

The connecting element 414 is provided on the outer side of its intermediate part with a central cutout 417 arranged so as to accommodate the locking sleeve 419.

The central cutout 417 has peripheral grooves 517, 518 located so as to accommodate, respectively, the flange 519 and the circular bulge 527 of the locking sleeve 419.

A gap 530 is provided on the opposite inner side of the above-described intermediate portion of the connecting member 414, which is suitable for fully accommodating the transverse tile 526 to allow the connecting member 414 and the locking sleeve 419 mounted thereon in the inserted position M to be inserted inside the cavity 430.

At the bottom of the gap 530 there are two arched grooves 531, 532 located at an angle opposite to each other, designed to accommodate the correspondingly shaped protrusions 528 of the transverse tile 526.

Side cutouts 522, 522 ′ are provided on each respective socket 413, 413 ′ of the heat exchange modules 1 on the outer face 101a of the heat exchange module. The side cutouts 522, 522 'have corresponding peripheral grooves similar to the grooves of the central cutout 417, and are arranged so as to accommodate, respectively, the upper flange 519 and the circular convexity 527 of the locking sleeve 419.

In the assembly state AS, the side cutouts 522, 522 ′ of the two adjacent sockets 13, 13 ′ form, with a central cutout 417 of the connecting element 14, a complete round-shaped socket for the locking sleeve 419.

The recesses 426, 426 'are located in the respective sockets 413, 413' on the inner surface 101b of the corresponding heat exchange module 1.

As shown in detail in FIG. 15, each recess 426, 426 ′ has an arched shape with an eccentric profile acting like a cam. The recesses 426, 426 'act as additional mating means for mating means 528 of the locking sleeve 419.

When the connecting element 414 and the locking sleeve 419 are inserted into the cavity 430 formed by the adjacent sockets 413, 413 ′ of the two heat exchange modules 1, and the locking sleeve 419 is rotated ninety degrees from the inserted position M to the locked position L, the protruding transverse tiles 528 of a certain shape 526 are disengaged from the respective arched grooves 531, 532 and are gradually inserted into the corresponding recesses 426, 426 '.

Due to the arched shape with the eccentric profile of the above-described recesses 426, 426 ', the gradual insertion of protrusions 528 having a certain shape into the recesses 426, 426' causes the two heat exchange modules 1 'to move towards each other. Thus, the twisting or clamping torque applied to the locking sleeve 19 is transformed into traction, which pushes and supports the heat exchange modules 1 with respect to each other. Such compressive force provides an effective and tight connection between the openings B of the piping C and the through holes 415 of the connecting element 414, with corresponding compression of the gaskets 416.

The operation of this version of the modular heat exchange system 100 of the invention is substantially similar to the previously described embodiment of the invention.

On Fig, 19 shows the radiating device 60 of the heat exchange system 100 of the invention.

These radiating devices comprise a radiating panel 60 comprising a plate 61, for example of a rectangular or square shape, provided on the inner surface 61a opposite the outer radiating surface 61b, a plurality of elongated ribs or guide walls 62 substantially parallel to each other and to the side edge 61c of the above plate. The guide walls 62 are spaced at equal intervals from each other and have, for example, a wavy and / or rectilinear shape.

Clutch devices 63 are provided on the above-described inner surface 61a to enable the above-described radiating panel 60 to be attached to one or more heat exchange modules 1.

The clutch devices 63 comprise, for example, a plurality of pins arranged so as to engage with the cavities 8 provided on the outer face surface 101a of the heat exchange module 1. The pins 63 are inserted into the respective cavities 8 and fixed using pressure exerted on them, or using a layer of glue laid between them, or other mechanical means.

Alternatively, the clutch means may include one or more through holes located on the above-described plate 61, for the passage of the corresponding fixing screws, which are used to attach to the heat exchange modules 1.

Additional guide walls 64 are provided for connecting together sequentially arranged in the same row of pins 63. Additional guide walls 64 are parallel to and located between the guide walls 62.

The radiating panel is made of a metal material, in particular, of the same material from which the heat exchange modules 1 are made, for example, of an aluminum alloy.

Installed on the corresponding heat-exchange module (Fig. 18), the radiating panel 60, due to the good thermal conductivity of the metal, heats up quickly. The guide walls 62 and the additional guide walls 64 form a plurality of channels within which the air is heated or cooled, and by convective movement, it is scattered into the surrounding space, providing a high and efficient heat exchange.

The outer radiating surface 61a of the panel also allows heat to be dissipated by radiation.

For this reason, the use of radiating panels 60 is particularly suitable for the use of the heat exchange system 100 of the invention, which is designed to mount a plurality of heat exchange modules on predominantly vertical room walls. Radiant panels are mounted on the heat exchange modules so that the guide walls 62 and 64 are arranged vertically. Each radiating panel 60 is associated with a respective heat exchange module or two or more adjacent and connected heat exchange modules 1.

The outer surface 61a of the radiating panel 60 may be decorated as desired to suit the design of the room in which the heat exchange system is installed.

Claims (34)

1. A modular heat exchange system connected to the wall (S) of the air-conditioned room, comprising heat exchange modules (1), each of which contains a tile (101), provided on the inside with piping (C) for the passage of the conditioning fluid; the above-described pipelines (C) conducted through the holes (B) on the connecting sides (200) of the above-described tile (101); fixing means (19; 419) for connecting two heat exchange modules (1), which are adjacent and are located in mutual contact along the respective connecting sides (200) in the assembly state (AS); connecting means (14; 414) for tightly connecting the above-described openings (B) of the two above-described adjacent heat exchange modules (1); characterized in that each heat exchanger module (1) contains on each connecting side (200) at least a socket (13, 13 '; 413, 413') containing at least one of the above openings (B) and configured in such a way as to form in the above-described assembly state (AS) with a similar socket (13 ′, 13; 413 ′, 413) of the adjacent heat exchange module (1) a cavity (130; 430), which is open and arranged to accommodate the above fixing means ( 19; 419) and the above-described connecting means (14; 414). 2. The system according to claim 1, in which the above-described cavity (130, 430) is open on the corresponding external front surface (101a) of the above-described tile (101) of each heat exchange module (1). 3. The system according to claim 1, in which the above-described connecting means (14; 414) contain a connecting element having a shape that complements the above-described cavity (130, 430) and is inserted into it, while the above-described connecting element has at least one through hole (15; 415) for connecting, with the possibility of fluid flow, the corresponding holes (B) of two adjacent heat exchange modules described above (1). 4. The system according to claim 3, in which the above-described socket (13, 13 '; 413, 413') contains end walls (313, 520) having such a shape as to facilitate insertion of the above-described connecting element (14; 414), and fit to the additional end walls (114, 420) of the above-described connecting element (14; 414), and to support them. 5. The system according to claim 1, in which the above-described fixing means (19; 419), when they are located inside the above-described cavity (130, 430), can be set in motion in order to reverse-lock together two adjacent above-described modules (1). 6. The system according to claim 5, in which the above-described connecting means (14; 414) contain a connecting element having such a shape as to complement the above cavities (130, 430) and inserted into them, while the above-described connecting element is provided at least , one through hole (15, 415) for fluid leakage connection with the corresponding holes (B) of the above two adjacent heat exchange modules (1), and in which the above fixing means comprise a locking sleeve (19; 419), placed with the possibility of rotation into the central cut-out (17; 417) of the above-described connecting element (14; 414) and equipped with connecting means (25, 25 '; 528) located for engaging in the locked position (L), with additional connecting means (26, 26 ', 426, 426') of the nests described above (13, 13 '; 413, 413'). 7. The system according to claim 6, in which the above-mentioned mating means (25, 25 '; 528) and / or the above-described additional mating means (26, 26', 426, 426 ') are shaped so that by rotation of the above-described locking sleeve (19; 419) from the inserted position (M) in which the above mating means (25, 25 ′; 528) are disengaged from the above additional mating means (26, 26 ′, 426, 426 ′) into the above locked state (L ), the above neighboring heat-exchange modules (1) are gradually bonded to each other and to the above-described connection tional element (14; 414). 8. The system according to claim 7, in which the above mating means comprise two open cavities (25, 25 '), which are basically identical and spaced apart in angular size, made in the lower section of the above locking sleeve (19) and provided with corresponding external walls ( 125, 125 ') having a variable thickness to create a substantially eccentric profile. 9. The system of claim 8, in which the above additional connecting means contain protrusions (26, 26 '), made on the bottom wall of the above sockets (13, 13'), and have such a shape as to be inserted into one of the above cavities (25 , 25 ') and gradually engage with it. 10. The system according to claim 7, in which the above locking sleeve (19) contains additional devices (319, 319 ') located so as to enter into engagement with devices (21, 21') having grooves of the above-described central notch ( 17) so as to cause the above-described locking sleeve (19) to move toward the above-described connecting element (14) to the above-inserted position (M). 11. The system of claim 10, in which the above-described socket (13, 13 ') contains additional devices (24, 24') having grooves arranged so as to accommodate the above-described additional devices (319, 319 ') in the above-described locked position (L). 12. The system of claim 10, in which the above-described additional devices (319, 319 ') contain two additional devices protruding outward and sideways from the above-described lower section of the above locking sleeve (19). 13. The system according to claim 7, in which the above-mentioned mating means contain two shaped protrusions (528), made in the lower section of the above locking sleeve (419). 14. The system according to item 13, in which the above additional connecting means contain a recess (426, 426 ') located on the above socket (413, 413') and located so as to accommodate the corresponding protrusion (528) having a certain shape, in the above locked position (L). 15. The system of claim 14, wherein the recess (426, 426 ′) described above has an arched shape, wherein the shape forms an eccentric profile. 16. The system of claim 14, wherein the above-described recess (426, 426 ') is formed on the inner surface (101b) of the above-described tile (101). 17. The system according to item 13, in which the above-described locking sleeve (419) is rotatably connected to the above-described locking element (414). 18. The system according to 17, in which the above locking sleeve (419) contains an external flange (519), attached using a central pin (525) to the transverse tile (526) provided at opposite ends of the above protrusions (528) having a certain form. 19. The system of claim 18, wherein the above-described central pin (525) of the above-described locking sleeve (419) is rotatably inserted into the central through hole (425) of the above-described locking element (414). 20. The system according to claim 1, in which the above tile (101) of each heat exchange module (1) contains a perimetric edge (201) defining a gap on the inner surface (101b), suitable for accommodating heat insulating means (2), the above-described inner surface ( 101b), designed to adjoin the above wall (S) of the room. 21. The system according to claim 1, in which the above-described pipelines (C) are completely formed as a whole part with the above-described tiles (101). 22. The system according to item 21, in which the above tile (101) of each heat exchange module (1) contains a perimetric edge (201) defining a gap on the inner surface (101b), suitable for receiving heat insulating means (2), the above inner surface ( 101b), intended to adjoin the above-described wall (S) of the room, and in which the above-described pipeline (C) contains longitudinal walls (3), embossed on the above-described rear surface (101b) of the above-described tile (101). 23. The system according to item 22, containing the overlapping device (4) attached to the above longitudinal walls (3) to form the above-described pipeline (C). 24. The system according to claim 1, in which the above-described connecting sides (200) are opposite and / or consecutive sides of the above-described tiles (101). 25. The system according to claim 1, in which the above-described tile (101) of each heat exchange module (1) contains many cavities (8). 26. The system of claim 25, wherein the above-described heat-exchange modules (1) can be attached to the above-described wall (S) of the room by fixing devices (10) inserted into at least one of the above-described cavities (8) provided with a bottom opening ( 108). 27. The system of claim 1, wherein coating means (P) are provided that can be applied to the outer face (101a) of the above tile (101) of each heat exchange module (1). 28. The system according to claim 1, containing radiating devices (60), which can be superimposed on the above-described heat-exchange modules (1) and arranged so as to increase heat exchange by convection between the above-described heat-exchange modules (1) and the above-described room. 29. The system of claim 28, wherein the above-described radiating devices include at least a radiating panel (60) comprising a plate (61) formed on an inner surface (61b) that is opposite to the outer radiating surface (61a), with many elongated dividing walls (62). 30. The system according to clause 29, in which the above dividing walls (62) are almost parallel to each other and to the side edge (60c) of the above plate (61). 31. The system according to clause 29, in which the above-described dividing walls (62) are located separately from each other and have a wavy and / or rectilinear shape. 32. The system according to clause 29, in which at least the above-described radiating panel (60) comprises coupling means (63) provided on the above-described inner surface (61b) for attaching the above-described radiating panel (60) to at least heat exchange module (1). 33. The system according to p. 32, in which the above tile (101) of each heat exchange module (1) contains many cavities (8), and in which the above coupling means (63) contain many pins that can be inserted into the above cavities (8) the above heat exchange modules (1). 34. The system of claim 28, wherein the above-described heat-exchange modules (1) and / or the above-described radiating devices (60) are made of a metal material with high thermal conductivity, in particular of an aluminum alloy.

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