FR2790819A1 - Heat exchanger assembly for use on suspended floors or embedded within the ground, comprises a pipe circuit mounted between a substrata and a floor facing - Google Patents

Abstract

The heat exchanger assembly comprises of a substrate (10) upon which are mounted pipes (6) for conveying a heated liquid. The pipes are supported on the substrate by a grill (3) and are embedded within a floor facing layer (7). The heat exchange units can be linked such that a continuous circuit can be formed. Fixings (8) enable each exchanger assembly to be mounted to the ground or floor suspension.

Description

INTEGRATED HEAT EXCHANGE STRUCTURE ON

  WALLS, FLOORS AND CEILINGS FOR TEMPERATURE REGULATION PURPOSES

SUMMER AND WINTER OF PREMISES

  The present invention relates to temperature regulation throughout the year of premises for residential or other use such as office, store,

workshop, etc ...

  The known systems used to ensure both the heating of the air and its cooling, are mixed systems implementing two

standard principles.

  One is to perform air conditioning by blowing air through a network of ducts with a mouth in each room, the air being taken up by

  an air handling unit located outside the air-conditioned area.

  The other principle implements air conditioning by heating or cooling the ambient air by recirculating it through a water exchanger located in the room to be conditioned, constituted for example by

  a wall-mounted fan coil or an air heater.

  These two principles have many well-known drawbacks: circulation of dust by the movement of air, which can cause allergy problems; - noise of fans and air flows - irritation of the throat due to the drying of the air due to its treatment; - microbial pollution by bacteria which develop on the exchangers and in the sheaths due to condensation phenomena; - difficulty and cost of cleaning the exchangers, filters and in particular the ducts; - problems of installation and aesthetics of the material, for example

  ducts and vents in the false ceilings to be made or the ventila-

convectors on the walls.

  The present invention aims to propose a new mode of regulation throughout the year of the temperature inside any room, for residential, professional or other use, not creating air movements.

  and avoiding the drawbacks mentioned above, of traditional techniques.

  To this end, the invention relates to a structure of heat exchanges which can be integrated into walls, floors and ceilings, for the purpose of temperature regulation in summer and winter, of premises, characterized in that it is consisting of: - a metal grid for thermal diffusion, - one or more circuits of tubes attached to the face of the grid turned towards the interior of said room and in heat exchange contact with said grid in a substantial way, - a means for coating the grid-tube assembly, having good conductivity and thermal homogenization properties, - and means for fixing said assembly to the material of said walls, floor, ceiling, said grid being dimensioned to form a structural section capable of covering the total surface of the wall, floor, ceiling to be fitted and having, by an appropriate determined arrangement of said tubes, at least one fluid circulation circuit extending regularly rement over the entire surface of said section, one end of the circuit being connected by collectors to a source supplying throughout the year a fluid whose temperature remains within a narrow range of values, however that the other end of said

  circuit is connected by collectors to the return circuit of said source.

  Thus, in accordance with the invention, one does not intervene on the air contained inside the room to add or remove calories from it, but a thermal barrier is confined to the right of the walls of the room. room air in a narrow temperature range and preventing the penetration of cold or hot from the outside to the inside of said room. Such a principle is indeed quite contrary to that of known systems which

  fight hot or cold after it enters the room.

  Indeed, the heat exchange structure of the invention, when it covers all or almost all of the unopened internal surface available for this purpose of a living room for example and that a fluid, for example of water at a relatively constant temperature, around 20 C to 22 C for example, circulates permanently in the circuits of the various sections lining the walls, floor and ceiling of said room, makes it possible to maintain the entire volume d room air at an average temperature

  substantially constant in winter and summer.

  The importance of the heat exchange surface, the good thermal homogeneity of all the parts of the exchange structure and the good quality of heat exchange creates a multidirectional radiation between this structure and the internal volume, almost entirely enveloped by the structure, with the inevitable exception of window and door openings for example, ensures very good thermal regulation by a substantial limitation of the temperature excursions of the air volume, both winter and summer. Thus, in winter, water simply at 22 C is enough to maintain the air in the room at a temperature of about 20 C, while, in summer, water at 20 C

  enough to keep the air in the room at around 22 C.

  Due to the low temperatures of the regulating fluid, there is no problem of condensation, because the temperature differentials are too

weak.

  As for the costs of maintaining the temperature of the regulating fluid, they are low compared to those of traditional systems whose temperature

  is very high in winter and low in summer.

  Furthermore, the exchange structure according to the invention is simple to implement. It attaches to any structure, whatever its material, constituting the walls, floors and ceilings to be covered, whether these are of

flat, concave or convex shape.

  The finished heat exchange structure has a surface that is easy to cover with a traditional coating such as paint, tapestry,

tiling, etc ...

  The structure finally adapts easily to the morphology of the wall to be fitted and to the possible presence of obstacles (doors, windows, sockets, switch, etc ...) or reservation areas (for fixing a table for example). It suffices to compose the structural part accordingly by the appropriate arrangement of the constituent elements and the choice of the placement on the latter of the sections of tube to bypass an obstacle or avoid

a zone.

  This placement is facilitated by providing each grid with a plurality of fixing members, for example by clipping, tubes, distributed over the surface of the grid so as to allow different arrangements, as desired, sections of tube for composing different geometries of the path of the regulating fluid circulation circuit, as we will see in the

description which follows.

  Other characteristics and advantages will emerge from the description which

  will follow embodiments of the structure according to the invention, description

  given by way of example only and with reference to the appended drawings in which: - Figure 1 is a schematic perspective view of a grid of the heat exchange structure of the invention; - Figure 2 shows the grid of Figure 1 attached to a wall material and provided with tubes, the assembly being coated - Figure 3 is an elevational view of the structure of Figure 2, - Figures 4a, 4b show a structure freestanding factory made where the grid is pre-molded; - Figures 5a, 5 and 6a, 6b respectively illustrate two stages of finishing on site, namely installation of the tube circuit and coating of the assembly; - Figure 7 shows in perspective a structural section comprising a grid and a set of tubes before covering with a finishing coating; - Figure 8 shows three structural sections intended for example to cover the ceiling, the floor and one of the walls of a living room (3 surfaces in contact with the outside playing the role of heat shield or anti-cold), and - Figure 9 shows an alternative embodiment of the grid of the

figure 1.

  In FIG. 1, a module of a grid 1 of a structure according to the invention is shown, the pattern of the module being repeated to constitute a grid in

  plate for example about 2 m x 1 m.

  Grid 1, of square module in the illustrated embodiment, is a flat square mesh, made for example by cutting and stamping

  of a metal sheet of a material which is a good thermal conductor.

  The manufacturing process makes it possible to project, below the general plane of the grid 1, tabs 2 for spacing the grid to facilitate its subsequent sealing in a coating material as well as two bending cross alignments 3 of certain strands of the mesh, for better coating as will be seen below. This strengthens the structure and

avoids blowing the coating.

  This same manufacturing technique makes it possible to constitute curved portions in the shape of a trough 4, four in number in FIG. 1, intersecting at right angles and intended to serve as a cradle for circulation tubes of a thermal regulating fluid. The troughs 4 are turned on the side of the grid 1 opposite the legs 2. They are provided, in the central part, with legs

  elastic 5 to receive by clipping and hold the tube trapped.

  The grid 1 is first fixed, for example using stirrups 8 and screws 9, on the raw material 10 of the wall to be covered with the structure of the invention. This material 10 can be stone, concrete, brick, wood, plaster, etc. Tubes 6 are then placed in some of the troughs 4 and, finally, the grid-tube assembly is embedded in a surface coating 7, by

example a plaster coating.

  Figures 4a, 4b; 5a, 5b and 6a, 6b illustrate the stages of production

  of a self-supporting structure and pre-insulated in the factory.

  In FIGS. 4a, 4b, there is shown a panel 11 made of insulating material on one of the faces of which is deposited in the factory, for example by dipping a first layer of plaster 12 on which is placed a grid 1, i15 slightly pressed into the layer 12 so that the grid is held captive and the troughs 4 are released for fitting, during a second step (FIGS. 5a, 5b) of tubes 6 at the desired locations. The soaking technique thus makes it possible to produce a self-molded grid without

  fixing by screw on the material 1 1 for example a glass wool mattress.

  In a third step (Figures 6a, 6b), we will coat the tubes 6 and

  the legs 5 with a layer of finishing plaster 13.

  The set 11-12-13 can be used to constitute for example a

  facing, or ceiling, or a wall of a partition of a living room.

  The tubes 6 are for example of plastic material such as

  cross-linked polyethylene of sufficient section for a high water flow.

  The bending and the surface of the parts 4 and 5 of the grid 1 are determined so as to have a large contact between the tubes 6 and their receiving trough and ensure good rigidity in the grid as well as good thermal conductivity. The curved parts 3 participate in the stiffening of the grid 1 while ensuring a better coating and anchoring in the material 7 by moving the grid away from the face of the support 10 together with the tabs 2, in the mode

of Figures 2 and 3.

  The legs 2 also contribute to a better distribution of the

  thermal load with respect to the support 10.

  The grid 1 distributes the thermal load in the mass of the coating 7 by conductivity for optimal exchange in winter from the tubes 6 to the surface 14 (in contact with the air in the room to be regulated) and, summer,

  from the surface 14 towards the tubes 6.

  The elastic tabs 5 allow a simple and rapid installation of the tubes and maintain a pressure on the latter thus ensuring perfect contact

  between the tubes and the metal surface (grid 1) distributing energy.

  The coating 7 (plaster, coating, plaster with or without additive, for example) allows a uniform surface temperature and facilitates the conductivity between the

grid 1 and the tubes 6.

  It also defines an ideal finishing surface for tiling, painting,

tapestry, etc ...

  On the grid 1 ′ in FIG. 7, several sections 6 ′ of parallel tubular circuit are produced with the same spacing so as to regularly cover the entire surface of the grid and to obtain excellent

  thermal homogeneity in the final structure.

  If an area of the grid 1 ′ must be located opposite an obstacle such as a socket outlet 15, it is easy to cut the grid there and to

  bypass the obstacle by slightly offset the 6 'tube laterally.

  On this part, the tube 6 'is not held by legs 5 since outside the normal receiving trough 4', but this has no effect on the

  mechanical and thermal performance.

  The large number of troughs 4, 4 'makes it possible to give the 6' circuits the

desired geometry.

  This is illustrated by FIG. 8 which represents three structural sections, respectively 16, 17 and 18, the general dimensions of which correspond to those of the surfaces to be covered, namely the floor, the ceiling and a partition with

  door, respectively, of a living room.

  As regards the floor and the ceiling, the two structural sections 16 and 17 are identical and have a surface corresponding to that of the floor and the ceiling. The set of 6 'tubes of each pan forms a unique spiral-shaped circuit from the center so as to have a perfect

  temperature uniformity over the entire extent of the surface concerned.

  Each circuit has an input E and an output S, connected to two general lines 19, 20, themselves connected to a source of regulating fluid, generally water, the source as well as the control means of

  temperature and circulation of said fluid not being shown in the drawing.

  It should be noted on the panel 17 intended for the ceiling, the arrangement in the center of a reserved zone 21, by lateral offset from the tube 6 ', for the installation of a

electrical supply point.

  Regarding pan 18, the geometry of laying the tubular circuit

  6 "takes into account the existence of a door 22 and covers the entire surface not

  open from the wall. It should also be noted that said 6 "circuit is in the form of a coil to evacuate the air bubbles upwards and bypasses certain

  reservation zones 23 intended for electrical equipment.

  The arrangement between two adjacent elements of the coil, as well as that between two turns of the spiral of panels 16 and 17, is of the order of

cm for example.

  The 6 "circuit has an input E and an output S, also

connected to the network 1 9, 20.

  The panels 16, 17, 18 form a thermal barrier which prevents any penetration from the outside of the cold, in winter, into the room and any penetration

hot, summer.

  The tubes (6, 6 ', 6 ") are of small section but sufficient for a large flow rate which allows them to be easily integrated into the plasters or

finishing coatings (7, 13).

  The heat exchanges take place between the regulating fluid and the grid (1, 1 ') via the tubes (6, 6', 6 "), in one direction or the other depending on the temperature differential between said fluid and the air of the room to be regulated, as well as between said grid and the mass of the coating (7, 1 3), in one direction or the other, so as to have constantly a very homogeneous distribution of the temperature in surface (inside of the part) of the exchange structure and

over its entire extent.

  FIG. 9 illustrates an alternative embodiment of the grid of FIG. 1. In this variant, the grid 1 "consists of a lattice of metallic round wire, with square meshes, sectioned and bent in an appropriate manner to define means, respectively 24, 25, 26, corresponding to the legs 2, troughs 4 and elastic legs 5 respectively, for the anchoring of the

  grid 1 ", positioning and fixing the tubes 6.

  This type of grid is more economical to produce but less efficient

in power (w / m2).

  It should be noted that during the manufacture of the panels or panels of the structure according to the invention, account can be taken of the non-planar nature of the surfaces to be covered by said panels or panels, by giving the grid (1, 1 ' ,

  i ") the appropriate non-planar shape.

  The grid is fixed on the surface to be equipped on site, as illustrated

  for example by FIGS. 2 and 3, by any suitable means.

  In the version illustrated by Figures 4a, 4b; 5a, 5b and 6a, 6b, it is the assembly 1 1-12-13 which is produced in the factory, then attached, by any appropriate means, to a surface to be covered, or else directly installed as

dividing wall for example.

  Finally, the invention is obviously not limited to the embodiments shown and described above, but on the contrary covers all the variants thereof, in particular as regards the shapes, nature and dimensions of

  the grid and means for receiving and fixing the tubes.

Claims (10)

  1. Heat exchange structure that can be integrated into walls, floors and ceilings, for temperature regulation purposes in summer and winter, of residential premises, characterized in that it consists of: - a metal grid (1,1 ', 1 ") for thermal diffusion, - one or more tube circuits (6,6', 6") attached to the face of the grid facing the interior of said room and in contact heat exchange with said grid substantially, - means (7,12,13) for coating the grid-tube assembly, having good conductivity and thermal homogenization properties, - and means (8, 9) for fixing said assembly to the material constituting said walls, floor, ceiling, said grid (1.1 ′, 1 ") being dimensioned to form a structural section which can cover the total surface of the wall, ceiling, floor to be fitted and having, by an appropriate determined arrangement of said tubes (6,6 ', 6 "), at least one circulation circuit of fluid extending regularly over the entire surface of said panel, one of the ends (E) of the circuit being connected by collectors to a source supplying throughout the year a fluid whose temperature remains inside d 'a narrow range of values, while the other end (S) of said circuit is connected by collectors to the circuit of return from said source.   2. Structure according to claim 1, characterized in that said grid (1, 1 ') is formed by cutting and stamping a metal sheet   so as to define troughs (4) for receiving said tubes (6, 6 ').   3. Structure according to claim 2, characterized in that said troughs (4) are extended by lugs (5) capable of enclosing   elastically said tubes (6, 6 ').   4. Structure according to claim 2 or 3, characterized in that said grid (1, 1 ') is provided with tabs (2) or parts (3) projecting for a   good anchoring in said coating (7, 12).   5. Structure according to claim 1, characterized in that said grid (1 ") is formed of metallic round wires, sectioned and shaped to   receiving said tubes (6) and for anchoring in said coating (7, 12).   6. Structure according to one of claims 1 to 5, characterized in that   that said coating (7, 12, 13) is plaster or the like.   7. Structure according to one of claims 1 to 6, characterized in that   that said grid (1, 1 ') with its tubes (6, 6') is completely coated, then   attached and fixed by any appropriate means on the surface to be fitted.   8. Structure according to one of claims 1 to 6, characterized in that   that the grid (1) with its tubes (6) is completely coated, directly on a support made of insulating material (11), the assembly thus formed being attached and fixed by any appropriate means to the surface to be fitted or constituting a dividing wall.   9. Structure according to one of claims 1 to 8, characterized in that   that it forms a panel or panel (16, 17, 18) covering the entire surface not open from a wall to be fitted.   10. Structure according to one of claims 1 to 9, characterized in that   that said tubes (6, 6 ', 6 ") are arranged to constitute a single circuit shaped spiral or serpentine so as to regularly cover the   entire surface of said structure.   1 1. Structure according to one of claims 1 to 10, characterized in   what the regulating fluid is water whose temperature is maintained in   a narrow range, especially between 20 and 22 C.