The present invention relates to a modular panel for thermal energy transfer particularly configured for being used in ceilings and walls, comprising a heat-insulating layer (2) forming a supporting structure demarcated by a lower face (2A), an upper face (2B), two side faces (2C, 2D) and two end fa
The present invention relates to a modular panel for thermal energy transfer particularly configured for being used in ceilings and walls, comprising a heat-insulating layer (2) forming a supporting structure demarcated by a lower face (2A), an upper face (2B), two side faces (2C, 2D) and two end faces (2E, 2F). Said panel (1) comprises at least one conducting plate (3) attached to the lower face (2A). Said conducting plate (3) is formed by a groove (31) embedded in the heat-insulating layer (2), defining a longitudinal cavity (32) which is configured to house a hydraulic pipe (6), and defining a longitudinal opening (34) which allows inserting the hydraulic pipe (6); a transfer plate (35) extending on the lower face (2A) and closure means (4) configured to seal the longitudinal opening (34) and press the hydraulic pipe (6) against the groove (31).
대표청구항▼
1. A modular panel for thermal energy transfer, particularly configured for being used in ceilings and walls, comprising: a heat-insulating layer forming a supporting structure demarcated by at least a lower face, an upper face, two side faces and two end faces;at least two spatially separated condu
1. A modular panel for thermal energy transfer, particularly configured for being used in ceilings and walls, comprising: a heat-insulating layer forming a supporting structure demarcated by at least a lower face, an upper face, two side faces and two end faces;at least two spatially separated conducting plates, each conducting plate disposed on and attached to only the lower face of the heat-insulating layer without covering said end faces and only partially covering the surface of said lower face, each conducting plate being formed by: a groove embedded in the heat-insulating layer defining a longitudinal cavity which is configured to house a hydraulic pipe, said groove in turn being finished by two longitudinal edges which are flush with the lower face, said groove defining a longitudinal opening which is configured to allow inserting the hydraulic pipe;a transfer plate prolonging from at least one of the longitudinal edges and extending on the lower face; anda closing device disposed in said longitudinal opening and configured to seal the longitudinal opening and press the hydraulic pipe against the groove. 2. The modular panel for thermal energy transfer according to claim 1 wherein the closing device comprises: a longitudinal embossment having a toothed profile arranged in each of the longitudinal edges; andwherein said closing device is an elastic closure element configured to compensate for the expansions of the hydraulic pipe caused by temperature changes thereof, wherein said elastic closure element is formed by: two longitudinal sides having a toothed profile fitting with the longitudinal embossments to allow securing the closure element to the conducting plate and sealing the longitudinal opening, assuring the leak-tightness of the longitudinal cavity;a longitudinal seat which is configured to press the hydraulic pipe against the groove, assuring the thermal energy transfer between the hydraulic pipe and the conducting plate; anda lower base which is flush with the lower face. 3. The modular panel for thermal energy transfer according to claim 1, comprising a fixing support attached to the upper face. 4. The modular panel for thermal energy transfer according to claim 3, wherein the fixing support is embedded in the heat-insulating layer and is U-shaped. 5. The modular panel for thermal energy transfer according to claim 1, wherein the groove of at least one conducting plate follows a straight path starting in the end face and ending in the end face. 6. The modular panel for thermal energy transfer according to claim 1, wherein the groove of at least one conducting plate follows a 90° path starting in an end face and ending in a side face. 7. The modular panel for thermal energy transfer according to claim 1, wherein the groove of at least one conducting plate follows a 180° path starting and ending in one of the end faces. 8. A thermal surface for the thermal conditioning of an enclosure comprising a plurality of modular panels according to claim 1, wherein the modular panels are arranged adjacent to one another, their conducting plates being linked to one another and the grooves of said plates forming a continuous longitudinal cavity which is configured to house the hydraulic pipe, wherein said longitudinal cavity defines a continuous longitudinal opening which is configured to allow inserting the hydraulic pipe therein, forming a hydraulic circuit without the need for intermediate connections between panels. 9. The thermal surface for the thermal conditioning of an enclosure according to claim 8, wherein an expansion joint made of an elastic material having the same cross-section as that corresponding to the adjacent panels is arranged at the linking points of the conducting plates of said adjacent panels. 10. The thermal surface for the thermal conditioning of an enclosure according to claim 8 comprising a metal protective part arranged in the lower face of at least one modular panel, wherein said protective part is configured to cover the lower portion of the hydraulic pipe section at the points where the fixing support intersects the groove. 11. The thermal surface for the thermal conditioning of an enclosure according to claim 8 further comprising blind panels formed by: a heat-insulating layer forming a supporting structure demarcated by at least one lower face, an upper face, two side faces and two end faces; anda fixing support attached to the upper face;wherein said blind panels are configured to fill the empty spaces remaining in the thermal surface once the modular panels are arranged. 12. An assembly process for assembling the thermal surface for the thermal conditioning of an enclosure according to claim 8 comprising: a) selecting the modular panels and adapting the dimensions thereof depending on the geometry of the enclosure and of the hydraulic circuit to be installed;b) placing the modular panels adjacent to one another on a support structure, linking their conducting plates so that the grooves thereof form the continuous longitudinal cavity and the continuous longitudinal opening;c) inserting the hydraulic pipe into the continuous longitudinal opening and housing it in the continuous longitudinal cavity, forming the hydraulic circuit without the need for intermediate connections between panels; andd) fixing the closing device to the conducting plates to seal the continuous longitudinal opening and press the hydraulic pipe against the grooves thereof. 13. The assembly process according to claim 12 further comprising: e) covering the empty spaces lacking modular panels by means of blind panels previously cut according to the geometry of said spaces. 14. The assembly process according to claim 13 further comprising: f) applying a sealing paste layer on the lower face of the modular panels and of the blind panels; andg) placing finishing elements on the sealing paste layer, fixing said finishing elements to the support structure and to the fixing supports using screws. 15. The assembly process according to claim 12, wherein step b) further comprises: b.1. placing H-beams on the support structure equidistantly at a distance coinciding with the width of the modular panels; andb.2. placing the modular panels with their side faces fitting between the flanges of two contiguous beams. 16. The modular panel for thermal energy transfer according to claim 3, wherein the fixing support attached to said upper face is positioned between respective grooves in said lower face. 17. A modular panel for thermal energy transfer, particularly configured for being used in ceilings and walls, comprising: a heat-insulating layer forming a supporting structure demarcated by at least a lower face, an upper face, two side faces and two end faces;at least one conducting plate disposed on and attached to only the lower face of the heat-insulating layer and only partially covering the surface of said lower face, each conducting plate being formed by: a groove embedded in the heat-insulating layer defining a longitudinal cavity which is configured to house a hydraulic pipe, said groove in turn being finished by two longitudinal edges which are flush with the lower face, said groove defining a longitudinal opening which is configured to allow inserting the hydraulic pipe;a transfer plate extending from at least one of the longitudinal edges and extending on the lower face; andan elastic closure disposed in said longitudinal opening in leak-tight relation to said groove and configured to seal the longitudinal opening and press the hydraulic pipe against and into the groove. 18. The modular panel for thermal energy transfer according to claim 17, comprising a fixing support attached to the upper face, wherein the fixing support is positioned between respective grooves in said lower face.
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