COOLING ARRANGEMENT

Abstract

The present invention relates to a cooling arrangement, which comprises an insulation module (1) surrounding the insulated object (7) for its main part and formed by an internal layer (8), an external layer (3) and insulation material (9) located between them. The external layer of the insulation module is adapted to be surrounded by a protective enclosure (2) in a way that at least one air gap (4) is provided between the external layer and the protective enclosure. The insulation module has at least one exchange aperture (10) penetrating it at least in part with the first cooling element (12) adapted to it. The second cooling element (12) opposite to the first cooling element is, in turn, adapted to the external air gap (4) in a way that at least one thermoelectric generator (13) is arranged between them. The protective enclosure surrounding the insulation module is provided with a venting aperture (15) penetrating it, and a fan (5) utilizing the electric power produced by the thermoelectric generator (13) is adapted to it for increasing the efficiency of the airflow in the air gap.

Claims

1. Cooling arrangement comprising: an insulation module surrounding the insulated object for its main part, which insulation module is formed of an inner layer and an outer layer with an insulation material being adapted between the inner and the outer layers, and a protective enclosure is adapted to surround at least in part the outer layer in a way that at least one air gap is provided between the outer layer and the protective enclosure, wherein the insulation module comprises at least one exchange aperture penetrating it at least in part, a first cooling element is adapted to the exchange aperture enclosing it for its most part, and a second cooling element opposite to the first cooling element is adapted to the external air gap of the insulation module so that at least one thermoelectric generator is arranged between them, wherein the protective enclosure is provided with a venting aperture penetrating it, and a fan utilizing the electric power produced by the thermoelectric generator is adapted to it for increasing the flow in the air gap.

2. Cooling arrangement according to claim 1, wherein an exchange aperture is provided in the insulation module at least in one of the following locations with respect to the insulated object surrounded by the insulation module: above it, below it or to a side of it.

3. Cooling arrangement according to claim 1, wherein the fan is adapted to draw air from the air gap.

4. Cooling arrangement according to claim 1, wherein that the fan is adapted to blow air to the air gap.

5. Cooling arrangement according to claim 1, wherein the air gap comprises several parallel channels.

6. Cooling arrangement according to claim 1, wherein the air gap comprises means for disrupting the airflow to provide a turbulent flow.

7. Cooling arrangement according to claim 1, wherein the cooling arrangement comprises a splash adapted to protect the fan so that a venting aperture is provided between the splash shield and the protective enclosure.

8. Cooling arrangement according to claim 1, wherein at least one sensor is provided in connection with the fan for locating leaks appearing inside the insulating module.

9. Cooling arrangement according to claim 8, wherein the sensor is at least one of the following: a nitrogen oxide sensor, a carbon dioxide sensor, or a temperature sensor.

10. Cooling arrangement according to claim 1, wherein the fan comprises a wireless data connection for monitoring and adjusting its operation.

11. Cooling arrangement according to claim 1, wherein when the insulation module comprises several fans, they are connected to each other with a wired connection at least for distributing electric power.

12. Cooling arrangement according to claim 1, wherein when the insulated object is covered by several insulation modules, their fans are connected to each other with a wired connection for distributing electric power.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] A certain preferred embodiment (certain preferred embodiments) of the invention is described below on more detail with reference to the accompanying drawing, in which

[0014] FIG. 1 shows a schematic a side view of a part of the insulation module,

[0015] FIG. 2 shows a schematic cross-sectional view of the insulation module according to the FIG. 1 from the section A-A of the Fig. A,

[0016] FIG. 3 shows a cross-sectional view of the insulation module according to the FIG. 2 as an exploded view,

[0017] FIG. 4 shows an alternative structure for the section Det. B shown in the FIG. 2,

[0018] FIG. 5 shows a schematic cross-section along the air gap shown in the FIG. 2 with the airflow indicated by arrows,

[0019] FIG. 6 shows another alternative schematic cross-section along the air gap with the airflow indicated by arrows,

[0020] FIG. 7 shows a schematic cross-section of another insulation module according to the FIG. 1,

[0021] FIG. 8 shows a schematic cross-section along the air gap shown in the FIG. 7 with the airflow indicated by arrows, and

[0022] FIG. 9 shows a preferred location of the cooling arrangements around, for example, the exhaust pipe of an engine.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0023] The present figures do now show the cooling arrangement in real scale, but instead, the figures are schematic to illustrate the structure and operation of preferred embodiments in principle. In this context, the structural parts shown in the figures with reference numbers correspond to the structural parts designated with reference numbers in this description.

[0024] As such, the FIGS. 1 and 2 show the basic concept of the present invention, in which the insulation module 1 surrounding the insulated object for its main parts is surrounded with a protective enclosure 2 at least in part, which provides an air gap 4 between the outer layer 3 of the insulation module and the protective enclosure for ventilating the insulation module. As such, an airflow sweeping the outer layer is generated in the air gap that proceeds in the gap, the height of which can be 10-50 mm as measured from the outer surface of the outer layer to the inner surface of the protective enclosure. In this solution, the generation of the airflow is ensured by adapting a fan 5 to the air gap, which either draws external air flowing to the air gap through venting apertures 6 provided in it between, for example, the lower edge of the protective enclosure and the insulation module, or blows external air flowing to the air gap trough the fan and exiting through the said venting apertures. Of course, other venting apertures penetrating the protective enclosure can also be provided in other parts of its surface, if necessary. As such, efficient airflow can be ensured in the air gap by using a fan.

[0025] As shown in the FIGS. 2 and 3, the said insulation module 1 comprises an inner layer 8 surrounding the insulated object 7 for its main part and the outer layer 3 mentioned above with some known insulation material 9 adapted between the inner and outer layers. The insulation module has at least one exchange aperture 10 penetrating the structural layers of the insulation module in part or entirely, and it is enclosed for its main part with the first cooling element 11 adapted to it.

[0026] In turn, a second cooling element 12 opposite to the first cooling element 11 is adapted to the external air gap 4 surrounding the insulation module 1 in a way that at least one thermoelectric generator 13 (TEG generator) is arranged between them. Hereinafter, this combination is referred to as the energy unit 14. The electric energy generated by the thermoelectric generator as a result of the effect of the temperature difference between the two cooling elements contacting each other is utilized in the fan 5, which is connected to the surroundings through a venting aperture 15 provided in the protective enclosure 2 and penetrating it. The structure is shown particularly well in the FIG. 3.

[0027] The exchange aperture 10 receiving the energy unit 14 can be arranged, for example, to penetrate all structural layers of the insulation module as shown in the FIG. 2. Alternatively, when the thermal load of the insulated object is sufficient, the inner layer 8 of the insulation module 1 can remain unpenetrated. Is such solution, even a thin sealing and/or insulation 16 can be arranged between the inner layer and the first cooling element 11, if necessary. Such a structure is shown in the FIG. 4. As a result of the cooling provided by the present arrangement, the connection between the exchange aperture 10 and the insulation module 1 is not required to be absolutely tight, as the airflow moving in the air gap 4 provides sufficient cooling.

[0028] The exchange aperture 10 can be formed in the insulation module quite freely with respect to the insulated object 7, and as such, it can be located, for example, above the insulated object, under it or to a side of it. Is should also be noted that while the fan 5 is located in connection with the exchange aperture and the energy unit 14 in it in the present figures, this is not obligatory at all. The fan and the energy unit can be located in different parts of the insulation module without an adverse effect on the provision of the needed airflow. Further, nothing prevents providing an additional fan to another location in the protective enclosure, if, for example, thermal load is particularly high locally or the shape of the insulation module is such that it would be difficult to achieve sufficient airflow otherwise.

[0029] In order to extend the cooling effect of the airflow to the insulation module for its most part, the air gap is preferably formed by several mainly parallel channels 17. This is shown by way of an example in FIGS. 5 and 6. While the channels are shown to have a substantially vertical orientation in the accompanying figures, the channels can also be formed more like a labyrinth. Such channels may also have even horizontal or almost horizontal sections to increase the efficiency of the heat transfer either by slowing down the flow to improve the heat transfer or by directing the flow to the parts of the insulation module 1 requiring particularly high cooling. The walls 18 separating the channels from each other can be formed like this or the cannels can be provided with separate means to disrupt the airflow moving in the air gap. As such, the purpose is to provide as abundant turbulent flow as possible instead of a laminar flow easily generated otherwise in such channels.

[0030] It is also possible to avoid locating venting apertures 6 in the lower edge of the protective enclosure 2 by utilizing the solution according to FIGS. 7 and 8. In this case, the fan 5 guides the air from the upper part and the centre of the insulation module 1 downwards, and the air is directed to exit upwards from the edges of the insulation module. In this case, the channels 17 guiding the airflow are separated from each other by the wall 18, and the lower edge 19 between the protective enclosure and the outer layer 3 of the insulation module would be closed.

[0031] As it can be seen particularly in the FIGS. 2, 3 and 7, the fan 5 of the present cooling arrangement is preferably protected by a special splash shield 20. In order to ensure sufficient airflow, which exits or is directed to the fan, a venting gap 21 is provided between this splash shield and the protective enclosure 2. The height of the venting gap as measured from the outer surface of the protective enclosure to the inner surface of the splash shield is 10-50 mm. The splash shield prevents liquid or other impurities from entering to the fan and further inside the insulation module 1.

[0032] The operation of the fan 5 can also be ensured in arrangements where the insulation module 1 comprises, due to its size or shape or the nature of the insulated object 7, more than one fan, by connecting them to each other with a wired connection 22 to distribute the electric power from one or more thermoelectric generators to several fans as shown in the FIG. 9.

[0033] When the isolated object 7 is covered by several insulation modules 1, the fans 5 in them are, as well, preferably connected to each other with a wired connection 22 to distribute the electric power from one or more thermoelectric generators 13 to several fans.

[0034] In addition to such wired connection 22, the fan 5 or the fans can be arranged to comprise a wireless data connection 23 for monitoring and adjusting the operation of the fan or fans through a shared control unit 24. In turn, the control unit can have a wired or wireless connection to a special control unit, if necessary. It is also preferable to use this wireless data connection between the fans and the control unit for monitoring at least one sensor (not shown) in connection with one or more fans. Such sensors are adapted, for example, to locate leaks appearing inside the insulation module 1. Such sensors can be, among others, a nitrogen dioxide sensor, a carbon dioxide sensor or a temperature sensor.

[0035] It is clear for a person skilled in the art that the basic concept of the cooling arrangement can be implemented in many different ways when technology develops. As such, the present solution and its embodiments are not limited to the examples described above, but instead, they can vary within the scope of the claims.