NL2004738C2 - PANEL AND DEVICE SUITABLE FOR THE EXCHANGE AND / OR TRANSPORT OF THERMAL ENERGY AND METHOD OF COMPOSITION OF THE DEVICE. - Google Patents

Description

Panel and device suitable for exchange and / or transport of thermal energy and method for assembling the device

The invention relates to a panel of heat-conducting material suitable for exchange and / or transport of thermal energy, comprising at least one gutter-shaped recess and at least one panel part that is in thermal contact with the gutter-shaped recess, wherein the gutter-shaped recess is arranged for taking up a fluid line. The invention also relates to a device which comprises one or more panels according to the invention and a fluid conduit and to a method for assembling a device for collecting and / or exchanging thermal energy.

Thermal energy for domestic and industrial applications can be supplied by solar collectors that are generally referred to as low and medium temperature collectors. In densely populated areas, such as the Netherlands, such collectors are preferably placed on a substantially south-facing side of a roof of, for example, a home. These collectors are thereby directed towards the sun in such a way that an optimum heat output is obtained.

For the purpose of collecting thermal energy, the above-described, generally known collectors are provided with collectors comprising one or more connected flat metal plates. Pipes are provided at the rear of these metal plates which are in heat-exchanging contact with the metal plates because they are fixedly connected to the metal plates, for example by means of welding connections. A fluid is passed through these pipes, which form part of a pipe path of the collector, for example water to which an additive such as antifreeze may or may not have been added. The water contained in the pipes is heated by transporting and exchanging the thermal energy collected by the flat metal plates. The heated water is transported via the pipe path to a heat-insulated storage vessel for storage there since supply and demand of water heated via such a collector are generally not in agreement with each other.

A drawback of the collectors according to the above-described prior art is that the metal plates are available as standard modules with only a limited number of dimensions. For example, in order to cover the roof of a house, it is necessary to connect several of these standard modules to each other through connecting elements, in which connection elements in particular are required to connect consecutive pipes attached to the metal plates. Due to the large number of connecting elements required (for each set of two plates with pipe, at least one connecting element is always required for pipes to be connected to each other), the installation is labor-intensive, partly because the connecting elements must be carefully installed in order to reduce the risk of fluid leaks . As a result, the costs for the installation of such a collector will be relatively high.

A further drawback of the collectors according to the state of the art is that the use of the standard modules often means that an available roof surface cannot be completely covered. This can have both an adverse effect on the heat yield per available installation surface and on the payback period of the investment made. An additional drawback of using the standard modules is that customization with regard to a layout of the pipes, for example the pattern in which the pipes are laid, is at least made more difficult. This can have an additional adverse effect on the heat output per available installation surface.

It is an object of the present invention to provide a panel suitable for exchanging and / or transporting thermal energy that overcomes the abovementioned drawbacks or at least reduces that the number of connecting elements required to connect different fluid lines can be connected to each other. reduced. As a result, the installation will be at least less labor-intensive.

It is also an object of the present invention to provide a device which offers the possibility of covering an available installation surface, for example a roof of a house, at least to a greater extent than is possible with the standard modules according to the prior art. . The aim here is also to offer improved flexibility with regard to the realization of a suitable layout of the pipes.

It is a further object of the present invention to provide a method for assembling a device according to the invention.

3

At least one of these objectives is achieved with a panel according to the present invention, wherein the fluid conduit when included in the trough-shaped recess is in thermal contact with the trough-shaped recess.

This provides a panel that makes it possible to use fluid lines 5 of in particular any desired length. The number of connection elements can be reduced significantly because the line path of the collector can be realized at least with a more limited number of longer fluid lines and connection elements. If the application makes it possible, a continuous fluid line is preferably used.

Due to the greater flexibility with regard to length and shape of the fluid conduits, they can be arranged in such a pattern for each specific situation that an optimum performance of the collector can be achieved. Since the fluid lines and panels according to the invention can be laid in almost any corner or rounding of, for example, a roof surface, it is also possible to realize a maximum degree of coverage of the roof surface. This makes it possible to deliver customized work, which can have a beneficial effect on the performance of the collector and the return on investment of the investment.

Because the fluid line is in heat-exchange contact with the trough-shaped recess, the thermal energy collected by the panel can be transported well to the fluid contained in the fluid line. The fluid is, for example, water which may or may not be provided with an additive such as antifreeze, but it may also be another suitable liquid. In another application of the panel, the fluid can be a gas that can be heated by means of the thermal energy transported through the device.

It will be clear to those skilled in the art that the panel according to the invention can also be used in systems that are suitable for cooling an environment via walls and / or ceilings and / or floors.

In addition, it will be apparent to those skilled in the art that the panel according to the present invention can also be used for applications in which an improved spread of heat to an environment is desired. Here, for example, systems for heating floors and / or walls and / or ceilings which comprise panels according to the invention can be envisaged. In such applications, a fluid with a 4 higher thermal energy than the environment can be passed through the fluid lines. The thermal energy transported from the fluid to the trough-shaped recess can be spread through the at least one panel part in thermal contact with the trough-shaped recess and be delivered to the environment as heat.

In an embodiment of the panel according to the present invention, the gutter-shaped recess can be deformed, such that an access from the gutter-shaped recess can be reduced and / or increased by deformation of the gutter-shaped recess. If necessary, the deformation of the trough-shaped recess can increase the access so that the fluid line can be arranged in the trough-shaped recess. Subsequently, by deforming the trough-shaped recess, the access can be reduced such that the fluid conduit comes into heat-exchanging contact with the trough-shaped recess. As a result, the thermal energy collected by the panel can be transported well to the fluid contained in the fluid conduit 15.

In one embodiment of the panel according to the present invention, the access in use of the panel is smaller than a maximum transverse dimension of the trough-shaped recess. As a result, the fluid line can be prevented from falling outside the trough-shaped recess, as a result of which the heat-exchanging contact is broken and the performance of the collector is adversely affected.

In an embodiment of the panel according to the present invention, the panel has two panel parts on either side of the trough-shaped recess and, in use of the panel, the panel parts make a predetermined angle relative to each other, preferably, the panel parts are substantially in the same plane. When the panel parts lie substantially in the same plane, a flat surface can be provided on which, for example, roof leather can be applied in the case that panels according to the invention are applied to a roof.

In an embodiment of the panel according to the present invention, the at least one panel part and the trough-shaped recess have a wall thickness (d) that is in a range of 0.4 mm - 3 mm, preferably 1 mm. By choosing a wall thickness in this range, it is possible to provide a panel whose channel-like recess can be deformed while maintaining sufficient rigidity for the panel as a whole.

5

In an embodiment of the panel according to the present invention, the wall thickness (d) of the at least one panel part is greater than the wall thickness (t) of at least a part of the trough-shaped recess. As a result, it can be achieved that the trough-shaped recess has a smaller rigidity than the panel parts and the trough-shaped recess can be distorted by manipulation of the panel parts. In this way the access to the channel-shaped recess can be reduced and / or increased.

In an embodiment of the panel according to the present invention, a part of the trough-shaped recess has a wall thickness (t) that is smaller than the wall thickness (d) of the rest of the trough-shaped recess and / or the at least one panel part. By providing one or more of such local weakenings in the channel-shaped floor, flexible pivot points can be obtained for deforming the channel-shaped floor.

In an embodiment of the panel according to the present invention, the part of the trough-shaped recess with the smaller wall thickness (t) is substantially opposite the entrance in the radial direction. This ensures that the trough-shaped recess can be deformed with the aid of a relatively small force. After all, an arm of the force, which extends between a flexible pivot point and an edge of the access, is relatively large in this case.

In an embodiment of the panel according to the present invention, the at least one panel part has a surface area that is in a range of 250 cm 2 - 4400 cm 2, preferably 975 cm 2.

In an embodiment of the panel according to the present invention, the heat-conducting material comprises a metal and / or a metal alloy with a heat conduction coefficient of at least 70 W / m.K at a temperature of 293 K.

By choosing a metal and / or metal alloy with a heat conduction coefficient of at least the above-mentioned threshold value, a panel is provided which enables a good transport and / or exchange of thermal energy. Copper (390 W / m.K), aluminum (237 W / m.K), brass (122 W / m.K) and iron (79 W / m.K) are materials that can be considered for use in a panel according to the invention. The final choice for a certain metal and / or certain metal alloy also depends on the trade-off that must be made between the expected performance and the costs of the collector. This assessment will mainly be determined by the market in which the collector will be used.

6

In an embodiment of the panel according to the present invention, the trough-shaped recess has a resilient effect for resiliently receiving the fluid line. As a result, the access of the trough-shaped recess in the position of rest of the panel may be (slightly) too small to receive fluid conduit. However, because the access can be made resiliently larger, for example by manipulating the panel parts located on either side of the trough-shaped recess, it is possible to subsequently fit the fluid line into the trough-shaped recess. After springing back the gutter-shaped recess, the access is reduced and the fluid line is held clampingly in the gutter-shaped recess.

According to another aspect of the present invention, a device is provided, comprising one or more panels according to the invention and a fluid conduit, the trough-shaped recess and the fluid conduit being arranged such that the fluid conduit, if included in the trough-shaped recess, is in thermal contact with the gutter-shaped floor. Since the fluid lines and panels of the device according to the invention can be laid in almost any angle or rounding of for instance a roof surface, it is hereby possible to realize a maximum degree of coverage of the roof surface.

In an embodiment of the device according to the present invention, a heat-conducting medium can be arranged between the fluid line and the trough-shaped recess. As a result, gaps between the fluid line and the trough-shaped recess can be filled to improve the thermal contact. After all, the openings can comprise air or another medium which, due to an insulating effect, can adversely affect a good exchange of thermal energy from the trough-shaped recess to the fluid line or vice versa.

According to another aspect of the present invention, a method is provided for assembling a device according to the invention for collecting and / or exchanging thermal energy, comprising the steps of: - providing a heat-conducting material; - manufacturing a panel with at least one trough-shaped recess by pressing and / or cold profiling and / or casting; - introducing a fluid line into the trough-shaped floor; and - establishing a thermal contact between the fluid line and the trough-shaped recess by deforming the trough-shaped recess.

7

This method offers, inter alia, the advantage, as already explained above, of using fluid conduits of any desired length and / or shape, whereby the number of connecting elements can be significantly reduced.

The panel can be manufactured by means of various shaping techniques such as pressing and / or cold profiling and / or casting. A form of pressing which is very suitable for example in the case of aluminum is extrusion. Examples of cold profiles such as cold rolling and beads can also be suitable shaping techniques for manufacturing the panel. In addition, casting could be a suitable shaping technique.

Although the invention will be described with reference to specific embodiments, the invention is not limited to the embodiments shown. The invention is described on the basis of measures in which explicit advantages can be mentioned, but in which also implicit advantages may apply. The subject matter of the invention of this application or of a divisional application may be any of those measures, some of which combinations are explicitly described and / or shown in this description, but which may also be implicitly described. Although the figures show explicit combinations of measures, it will be clear to the skilled person that a number of the measures can also be taken separately.

Figure 1 shows an exploded perspective view of an embodiment of the device according to the present invention.

Figure 2 shows a perspective view of operating devices according to the embodiment as shown in Figure 1.

Figure 3 shows a variant of the device according to the invention in which a curved fluid line is completely in contact with two panels according to the invention.

The figures are not necessarily drawn to scale. Identical or similar parts can be designated with the same references in the various figures.

Figure 1 shows an exploded view of an embodiment of the device 1 according to the present invention, wherein a panel 2 comprises two panel parts 3, 4 between which a trough-shaped recess 5 is positioned, in which a fluid line 6 can be fitted. The trough-shaped recess 5 as shown 8 in figure 1 is in such a position that the fluid conduit 6 can be arranged via the access 7 in the trough-shaped recess 5. The panel parts 3, 4 are not in the same plane.

By deforming the channel-shaped recess 5, the access 7 can be reduced such that the fluid line 6 comes into heat-exchanging contact with the channel-shaped recess 5. As a result, the thermal energy collected by the device 1 can be transported well to the fluid contained in the fluid line 6.

After deforming the gutter-shaped recess 5 so that the fluid conduit 6 is in heat-exchange contact therewith, the access 7 is smaller than a maximum transverse dimension 8 of the gutter-shaped recess 5. This can prevent the fluid conduit 6 from outside the gutter-shaped recess 5 can be hit, causing heat exchange contact to be broken. After the closure of the trough-shaped recess 5 around the fluid conduit 6, the panel parts 3, 4 lie substantially in the same plane as shown in figure 2.

By a suitable choice of the wall thickness (d, t) it is possible to provide a panel 2 whose channel-shaped recess 5 can be deformed while retaining the strength of the panel 2 as a whole. When the wall thickness (d) of the panel parts 3, 4 is greater than the wall thickness (t) of the gutter-shaped recess 5, the gutter-shaped recess 5 can have a lower rigidity than the panel parts 3,4. This makes it possible to deform the channel-shaped recess 5 by manipulating the panel parts 3,4. By bringing the panel parts 3, 4 into a horizontal plane shown in Figure 2, the access 7 to the channel-shaped recess 5 is reduced. In the case that a fluid conduit 6 is included in the trough-shaped recess 5, the trough-shaped recess 5 hereby closes around the fluid conduit 6. This establishes a heat-exchanging contact between the trough-shaped recess 5 and the fluid conduit 6.

By moving the panel parts 3, 4 in such a way that they are not aligned in the same plane, the access 7 of the channel-shaped recess 5 can be enlarged.

A fluid conduit 6 can hereby be provided in the gutter-shaped recess 5 or be removed therefrom.

In the case that a part (p) of the gutter-shaped recess 5 has a wall thickness (t) that is smaller than the wall thickness (d) of the rest of the gutter-shaped recess 9 and / or the panel parts 3, 4, the interfaces of these parts of flexible hinge points (11, 12) that are different in wall thickness (d, t). These flexible pivot points (11, 12) can facilitate the deformation of the channel-shaped recess 5.

Alternatively, the wall thickness (t) of the trough-shaped recess 5 can decrease as a function of the distance to the panel parts 3, 4.

As shown in Figure 1, the portion (p) of the trough-shaped recess 5 having a smaller wall thickness (t) is located in radial direction substantially opposite the entrance 7. This ensures that the trough-shaped recess 5 is relatively small force. After all, an arm of the force extending between the flexible pivot point (11, 12) and an edge of the access (13, 14) is relatively large in this case.

Figure 2 shows a perspective view of operating devices according to the embodiment as shown in Figure 1. This illustrates that a line path can be formed by a continuous fluid line 6. It is clear that this results in a significant reduction in the number of connecting elements used in the collector. It will be clear to those skilled in the art that the device according to the invention offers greater flexibility with regard to the length and shape of the fluid lines 6 that can be used in a line path of a collector than what is possible with the standard modules from which the collectors from well-known collectors. For each specific situation, the fluid lines 6 should be able to be arranged in such a pattern that an optimum performance of a collector can be achieved. After all, the fluid conduit 6 can have a large dimension and be clamped in several trough-shaped recesses 5 of several panels 2 located next to each other. This prevents relatively small pieces of fluid conduit from having to be connected to each other with separate connecting pieces, such as is necessary with prior art collectors in which the fluid conduit forms an integrated part of a panel.

In principle, the panels 2 according to the invention can also be sawn or cut into pieces 2 ", 2" such that they can easily be applied at a corner of a fluid line, as shown in Figure 3.

10

The present invention is not limited to the embodiments described above as non-limiting examples. The scope of protection is determined by the scope of the following claims, within the scope of which many modifications are conceivable.

For example, it has been described above that the trough-shaped recess 5 can be deformed such that it can be clamped around a fluid conduit 6, optionally with a heat-conducting medium between the trough-shaped recess 5 and the fluid conduit 6. Alternatively, however, the trough-shaped recess 5 can be made so that it has a resilient effect such that the access 7 in the rest position of the panel 2 is (slightly) too small to receive fluid conduit 6, but can be made resiliently larger so that fluid conduit 6 is then clamped in the trough-shaped recess 5 can be inserted.

Furthermore, the diameters of the fluid conduit 6 and the trough-shaped recess 5 are aligned so that the panel parts 3,4, when the fluid conduit 6 is inserted into the trough-shaped recess 5, form a predetermined angle with each other. For use on flat roofs (or flat parts of roofs), this angle will preferably be 180 °, but the invention is not limited thereto.

Claims (14)

A panel of thermally conductive material suitable for exchanging and / or transporting thermal energy, comprising at least one gutter-shaped recess (5) and at least one panel part (3; 4) in thermal contact with the gutter-shaped recess (5), wherein the gutter-shaped recess (5) is adapted to receive a fluid conduit (6), such that the fluid conduit (6) when received in the gutter-shaped recess (5) is in thermal contact with the gutter-shaped recess (5). 10 Panel according to claim 1, wherein the trough-shaped recess (5) is deformable, such that an access (7) of the trough-shaped recess (5) can be reduced and / or enlarged by deforming the trough-shaped recess (5). Panel according to claim 2, wherein the access (7) in use of the panel (2) is smaller than a maximum transverse dimension (8) of the channel-shaped recess (5). 4. Panel as claimed in any of the foregoing claims, wherein the panel has two panel parts (3, 4) on either side of the trough-shaped recess (5) and, in use of the panel (2), the panel parts (3, 4) predetermined angle to each other, preferably, lie substantially in the same plane. 5. Panel as claimed in any of the foregoing claims, wherein the at least one panel part (3; 4) and the trough-shaped recess (5) have a wall thickness (d) that is in a range of 0.5 mm - 2 mm, preferably 1 mm. Panel according to claim 5, wherein the wall thickness (d) of the at least one panel part (3; 4) is greater than the wall thickness (t) of at least a part of the trough-shaped recess (5). 30 Panel according to claim 5 or 6, wherein a part (p) of the gutter-shaped recess (5) has a wall thickness (t) that is smaller than the wall thickness (d) of the rest of the gutter-shaped recess (5) and / or the at least one panel part (3; 4). Panel according to claim 7, wherein the part (p) of the trough-shaped recess (5) with the smaller wall thickness (t) is located in radial direction substantially opposite the entrance (7). 5 Panel according to one of the preceding claims, in which the at least one panel part (3; 4) has a surface area (9, 10) that is in a range of 250 cm 2 - 4400 cm 2, preferably 975 cm 2. Panel according to any of the preceding claims, wherein the heat-conducting material comprises a metal and / or a metal alloy with a heat-conducting coefficient of at least 70 W / m.K at a temperature of 293K. Panel according to one of the preceding claims, in which the channel-shaped recess (5) has a resilient effect, for resiliently receiving the fluid line (6). 12. Device comprising one or more panels (2) according to one of the preceding claims and a fluid line (6), wherein the channel-shaped recess (5) and the fluid line (6) are arranged such that the fluid line (6) if included in the gutter-shaped floor (5) is in thermal contact with the gutter-shaped floor (5). Device according to claim 12, further comprising a heat-conducting medium that can be arranged between the fluid line (6) and the trough-shaped recess (5). 14. Method for assembling a device (1) for collecting and / or exchanging thermal energy, comprising the steps of: - providing a heat-conducting material; - manufacturing a panel (2) with at least one trough-shaped recess (5) as defined in any one of claims 1-11 by pressing and / or cold profiling and / or casting. - inserting a fluid line (6) into the gutter-shaped recess (5); and - establishing a thermal contact between the fluid line (6) and the channel-shaped recess (5) by deforming the channel-shaped recess (5). 5