DE202016007072U1 - cooler - Google Patents

Abstract

A radiator (1) for cooling a fluid flowing through the radiator by means of an airflow, the radiator comprising a plurality of fins (3) adapted to direct the flow of air from a first side through the radiator to a second side of the radiator wherein each blade (3) comprises a leading edge (7) facing the airflow, an intermediate part and a trailing edge, the leading edge (7) of the blade (3) being reinforced compared to the part therebetween.

Description

Technical part

The present invention relates to a radiator for cooling a fluid flowing through the radiator. The cooling is accomplished by means of an air flow, the radiator comprising a plurality of fins adapted to direct the flow of air from a first side through the radiator to a second side of the radiator, each louver having a leading edge facing the airflow, an intermediate edge Part and a trailing edge includes.

Background of innovation

Coolers adapted to cool a fluid flowing through the radiator by means of an air flow are known and available in numerous different embodiments thereof.

However, it is also a known fact that coolers must be serviced regularly so as not to lose their efficiency over time. The maintenance of coolers is difficult, however, they are also occasionally damaged, whereby the efficiency decreases over time.

There is therefore a need for a cooler that has a more robust construction and thus retains its efficiency over time.

Brief description of the innovation

The object of this innovation is to provide a cooler with a robust construction, which essentially retains its cooling surface and thus its efficiency and efficiency of the cooling surfaces over time.

Another object of this innovation is to provide a cooler that is resistant to extreme weather conditions.

To solve this object, this utility model provides a technical solution for a radiator for cooling a fluid flowing through the radiator by means of an air flow, the radiator comprising a plurality of vanes adapted to supply the air flow from a first side through the radiator a second side of the radiator, wherein each louver comprises a leading edge for air flow, an intermediate part and a trailing edge, wherein the leading edge of the lamella is reinforced compared to the intermediate part.

By reinforcing the leading edge of the blade thus the entire air inlet is reinforced in the radiator. This provides a more robust cooler. In other words, it may be resistant to possible blows or impacts that occur when it is exposed to hail, for example. and when other elements are in the airflow. This is advantageous because the entrance is not damaged and the air inflow is not unintentionally obstructed, whereby the efficiency is substantially maintained over time.

In addition, the leading edge may be reinforced to increase the resistance to impact of possible elements in the airflow.

Furthermore, it is advantageous to reinforce the leading edge by folding the leading edge. Since the cold transport, d. H. the cooling, takes place primarily at the intermediate part, the efficiency of the cooler would be reduced if the intermediate part made of a thicker material would be made to avoid damage.

This provides a method of reinforcing the leading edge that is easy to integrate into production.

The bending may advantageously be 0.2-2 mm or more advantageously 0.4-1.5 mm.

The bending may advantageously be 0.6 mm or more.

The bending can advantageously be 0.8-1 mm. It has been found that this very bending provides a favorable relationship between resistance to impacts by, for example, hail and the maintenance of a high cooling effect.

The leading edge can also be reinforced by adding material to the leading edge.

In another embodiment, the leading edge is reinforced by covering the leading edge with a mold of lining.

Furthermore, the leading edge can be reinforced by increasing the thickness of the blade at the leading edge. This can be done for example by gluing or welding of additional material at the front edge.

The blade is preferably made of a metal such as aluminum. Metal has a good one Thermal conductivity and is also easy to work.

The leading edge can also be enhanced by changing the properties of the metal.

The properties of the metal can be changed, for example, by hardening, welding, sintering, forging, rolling or similar processes.

The lamella can also be made from a bent sheet metal.

In a further embodiment, the trailing edge may also be reinforced compared to the intermediate part.

The sipe may have a ribbed shape between the leading edge and the trailing edge to create turbulence in the air flow along the sipe. The lamella may thus be designed to act as a swirler.

The ribbed shape may be a herringbone pattern, jagged or wavy.

The cooler may also include one or more fluid channels provided in a plate, the plate being disposed between two adjacent plates. As a result, the air flow cools the fluid present in the fluid channel via the two adjacent lamellae.

The cooler may also include a plurality of sheets with fluid channels.

In a preferred embodiment, the front edge is arranged substantially perpendicular to the air flow.

The cooler may also have side plates and / or end blocks.

Furthermore, the radiator may have a length and the fin may extend the length of the radiator.

The blade may also have a thickness of 2 mm or less.

In an embodiment according to the invention, the cooler is provided in connection with a wind turbine, for example on the top of the nacelle.

In another embodiment according to the invention, the radiator may be provided for a mining vehicle.

Brief description of the drawing

The drawings serve only to explain the present innovation and may under no circumstances be construed as limiting the description of the present innovation. Furthermore, shapes and sizes of various parts in the drawings are intended to be schematic and to better understand the invention, and therefore they should not be used to limit shapes and sizes of various parts of this application in any particular way. The person skilled in the art will be able to choose the possible shapes and sizes in order to implement the innovation with reference to this application.

1 shows a partial view of a cooler and its construction according to the present innovation,

2 shows a section of a cooling fin for use in the radiator,

3A and 3B show two examples of the air flow through a radiator, wherein 3A an unobstructed air flow and 3B shows a restricted air flow, and

4 shows an example of the positioning of the radiator on the top of the nacelle of a wind turbine.

Detailed description of the embodiments

The innovation will be described below in detail with reference to the accompanying drawings.

1 shows a part of a cooler according to the invention 1 , The cooler 1 includes a plurality of fins 3 used to direct the flow of air from a first side through the radiator 1 to a second side of the radiator 1 are procured. Each louver includes a leading edge facing the airflow 7 , an intermediate part and a trailing edge, the leading edge 7 the slat 3 is reinforced compared to the intermediate part. In this embodiment, the radiator comprises 1 six lamellae 3 , where between five sheets 2 are arranged with fluid channels. On each side of the radiator 1 are side panels 6 intended. On the sheets 2 with the fluid channels are also Endklötze 5 provided and along the leading edge 7 the slats 3 are several vertical parts 4 for shielding the sheets 2 intended. The leading edge 7 is provided substantially perpendicular to the air flow. The cooler 1 also includes several other elements, but which are neither shown nor described in more detail here, since they are known to the person skilled in the art.

2 shows an embodiment of a blade 3 with a reinforced front edge 7 , In this embodiment, the leading edge 7 reinforced by the fact that the leading edge 7 was crimped, so a crimp 8th is formed. The curl 8th increases the rigidity of the front edge 7 so that it is more robust and resistant to shocks and impacts from elements that are transported with the airflow, but also when the radiator 1 a hailstorm or similar weather phenomenon. The flare also provides reinforcement, so less damage when handling during the production of the cooler 1 caused.

The curl 8th has a distance FD. This distance can be about 1 mm, but of course also be smaller or larger depending on the application range of the cooler.

The slat 3 is preferably made of a metal such as aluminum, which at the same time facilitates bending during production.

As in 2 recognizable, the lamella points 3 in this embodiment, a ribbed shape between the leading edge 7 and the trailing edge. The slightly ribbed shape here is a herringbone pattern, which causes turbulence in the flow over the lamella, so that it acts as a swirler.

In other embodiments, the ribbed shape may be serrated or wavy.

Currently, a reinforcement of the leading edge by bending the leading edge 7 prefers.

However, it is also possible to reinforce the leading edge in other advantageous ways. In one embodiment, the leading edge may be reinforced by adding material to or on the leading edge.

In another embodiment, the leading edge may be reinforced by covering the leading edge with a pad.

Furthermore, the leading edge can be reinforced by increasing the thickness of the blade at the leading edge.

Since the lamella is usually made of a metal, it is also possible to reinforce the leading edge by changing the properties of the metal. The properties of the metal can be changed, for example, by hardening, welding, sintering, forging, rolling or similar processes.

In an embodiment which is not shown, the trailing edge may also be reinforced as compared to the intermediate part in the same way as described above in connection with the leading edge.

3A shows an air flow AF through the radiator. As in 3A Recognizable, the air flow is continuous, since the leading edge of the slats is neither damaged nor bent. In contrast, shows 3B in that the front edge of the lamellae is bent in several places, it being evident at these points that the air flow DAF is no longer continuous, because it is deflected and thereby does not flow into the intermediate part of the cooler. The efficiency of the cooler is much lower in this case. The present innovation minimizes the risk of particularly bent or damaged leading edges of the lamellae, as these are reinforced. The overall robustness of the radiator is thereby significantly increased compared to the prior art.

4 shows an example in which the renewal cooler on top of the nacelle 40 a wind turbine is attached.

In other embodiments, not shown, the cooler may be used to cool large industrial machinery, such as mining or similar industries.

Claims (19)

Cooler ( 1 ) for cooling a fluid flowing through the radiator by means of an air flow, the radiator having a plurality of fins ( 3 ) adapted to direct the flow of air from a first side through the radiator to a second side of the radiator, each louvre ( 3 ) a leading edge pointing towards the airflow ( 7 ), an intermediate part and a trailing edge, the leading edge ( 7 ) of the lamella ( 3 ) is reinforced compared to the intermediate part. Cooler ( 1 ) according to claim 1, wherein the leading edge ( 7 ) is increased to increase the resistance to impact of possible elements in the airflow. Cooler ( 1 ) according to claim 1 or 2, wherein the leading edge ( 7 ) by folding the leading edge to form a flange ( 8th ) is reinforced. Cooler ( 1 ) according to claim 3, wherein the flange ( 8th ) is substantially 1 mm. Cooler ( 1 ) according to claim 1 or 2, wherein the leading edge ( 7 ) is reinforced by adding material to or on the leading edge. Cooler ( 1 ) according to any one of the preceding claims, wherein the leading edge ( 7 ) is reinforced by covering the leading edge. Cooler ( 1 ) according to claim 1 or 2, wherein the leading edge ( 7 ) by increasing the thickness of the blade ( 3 ) of the leading edge is reinforced. Cooler ( 1 ) according to one of the preceding claims, wherein the lamella ( 3 ) is made of a metal such as aluminum. Cooler ( 1 ) according to claim 8, wherein the leading edge ( 7 ) is enhanced by changing the properties of the metal. Cooler ( 1 ) according to claim 8, wherein the properties of the metal are changed by hardening, welding, sintering, forging, rolling or similar processes. Cooler ( 1 ) according to one of the preceding claims, wherein the lamella ( 3 ) is made of a bent sheet metal. Cooler ( 1 ) according to one of the preceding claims, wherein the trailing edge is reinforced compared to the intermediate part. Cooler ( 1 ) according to one of the preceding claims, wherein the lamella ( 3 ) between the front edge ( 7 ) and the trailing edge has a ribbed shape. Cooler ( 1 ) according to claim 13, wherein the ribbed shape is a herringbone pattern, jagged or wavy. Cooler ( 1 ) according to any one of the preceding claims, wherein one or more fluid channels in the sheet ( 2 ) are provided and wherein the sheet ( 2 ) between two adjacent lamellae ( 3 ) is provided. Cooler ( 1 ) according to claim 15, wherein the cooler ( 1 ) a plurality of sheets ( 2 ) with fluid channels. Cooler ( 1 ) according to any one of the preceding claims, wherein the leading edge ( 7 ) is arranged substantially perpendicular to the air flow. Cooler ( 1 ) according to one of the preceding claims, wherein the air cooler ( 1 ) Side panels ( 6 ) and end blocks ( 5 ) having. Cooler ( 1 ) according to one of the preceding claims, wherein the air cooler ( 1 ) has a length and wherein the lamella ( 3 ) extends the length of the radiator.

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