BE1019541A3 - FLEXIBLE COOLING ELEMENT. - Google Patents

Abstract

The invention relates to an LED lamp construction comprising a housing for holding an LED lamp and at least one flexible conductor for the dissipation of heat generated by the LED lamp to a cooling element, the flexible conductor comprising a heat conductor from a solid. The invention also provides a method for cooling a heat source, the method comprising the following steps: a) connecting one or more flexible heat conductors from a solid to a heat source for dissipating heat, and b) connecting that one or more flexible heat conductors on one or more cooling elements for absorbing that heat. The invention also provides a flexible conductor, and its use, for cooling a heat source, the conductor being a solid heat conductor connecting the heat source to a cooling element.

Description

Flexible cooling element

The invention relates to the cooling of a heat source, for example an LED lamp.

LED lamps have a high efficiency. A crucial factor with an LED lamp is that the heat is properly dissipated. If this does not happen, the service life of the LED is considerably reduced. Good cooling is therefore required.

To date, LED lamps are usually cooled by means of cooling fins. The heat generated by the LED lamp is dissipated by cooling fins that are attached to the base of the LED lamp. US 2010/0212859 is an example of this. A disadvantage here is that this construction takes up a certain volume. This volume must also be built in and concealed in a structural element or a ceiling or wall. There must therefore be sufficient installation space. The orientation of the LED lamp at a certain angle is also limited by the size of the construction.

Other known systems provide heat dissipation via air ducts or heat pipes. US 7,144,135 describes an LED lamp provided with an air cooling whereby the warm air can escape through a space around the luminaire of the LED lamp. US 7,547,124 describes an LED lamp provided with a pulsating heat pipe in combination with cooling fins. However, it is a disadvantage that such cooling takes up a substantial space in the LED construction as a whole. Moreover, the heat dissipation is limited.

DE 102009020112 describes an LED headlight, for example for a surgeon, wherein the LED is cooled by a cooling fluid that is pumped through two flexible cooling lines between the headlight and a cooling element, with cooling fins or fan, located at a distance. A disadvantage here is the use of cooling liquid and the requirement of an external cooling element to cool the liquid.

An object of the invention is therefore to provide a highly efficient cooling and heat dissipation of LED lamps, or other structures of heat sources, wherein the cooling elements occupy a minimum of space and allow a maximum of flexibility for directing the LED lamp. The LED lamp thus requires minimal installation space. Another advantage is that with insulated installation spaces (for example a space in an insulated ceiling) the heat from the LED module is transferred to the open side of the fixture. With traditionally cooled modules, it is difficult to dissipate the heat in the insulated ceiling and there is also a fire hazard for the insulation.

Moreover, the weight of the LED lamp as a whole is lower and less raw material is needed.

This object of the invention is achieved by claim 1. This object of the invention is further achieved by the dependent claims.

The invention relates to an LED lamp construction comprising a housing for holding an LED lamp and at least one flexible conductor for dissipating heat generated by the LED lamp to a cooling element, characterized in that the flexible conductor comprises a heat conductor from a solid material.

The object of the invention is achieved by providing a heat transfer from the heat source, such as, for example, an LED lamp, e.g. flexible heat conductors. The flexible heat conductor is brought into direct contact, preferably attached to the heat source. In a specific embodiment, the flexible heat conductor is further connected to the housing of the LED module, such as, for example, the fixture. The fixture is preferably in contact with the ambient air in a room. As a result, a heat transfer takes place from the LED lamp to the open environment.

In another embodiment the heat transfer takes place via flexible heat conductors to a facility other than the housing, for example to an external heat sink, or to a (metal) profile for roof and ceiling constructions, or verandas and awnings. This external heat sink can be located in a place that does not limit the installation of the LED lamp, and which guarantees optimum cooling. Examples of external heat sinks are cooling fins, air ducts, fans. By "external" it is meant that the placement of the heat sink is separate from the placement of the LED lamp construction.

The applications are located in all luminaires where the heat must be diverted as efficiently as possible, either to the housing or an external heat sink. This applies to both built-in and surface-mounted devices.

The flexible cooling element of the invention comprises good heat-conducting materials. The thermal conductivity or heat conductivity coefficient is preferably at least that of steel or 50 W / mK (at 293 K), preferably higher than 100, more preferably higher than 200. Examples of suitable materials for the flexible cooling element of the invention are (with thermal conduction coefficient in brackets): metals such as preferably aluminum (237) and copper (390), but also gold (310) and silver (417), or bronze (190) and zinc (116), or optionally other materials such as diamond ( 165) and graphite (160). The thermally conductive materials used in the invention are typically classifiable among the solid materials, as opposed to the liquid and gaseous materials. So no coolant or cooling gas is used.

Heat transfer preferably takes place by conduction or conduction between two solid media.

The term "flexible" means movable in all or many possible degrees of freedom, deformable, minimum volume taking up, adjustable or rollable. Examples of flexible embodiments are wires (round or flat), ribbons, chains, pliable materials such as, for example, aluminum, mechanical joints, etc. A specific example is litze wire, eg silicon-litze cable of 8 mm2 with a construction of 2056 conductors r = 0.035 mm. Mechanical joints can allow both rotation and translation, or a combination of both.

The flexible cooling elements can assume a different degree of flexibility, so that any shape can be assumed, e.g. bent, folded, rolled, rolled up. The shape is preferably adapted to the space available for cooling.

The invention thus provides a flexible conductor for cooling a heat source, characterized in that the conductor is a solid-state heat conductor, which connects the heat source to a cooling element. Characteristic here is that the cooling element is not traditionally attached to the heat source and thus forms a whole, but that the cooling element is typically either an existing element of the structure (housing, profile), which is not as such a cooling element, or an external cooling body where "external" means that the heat sink is at a distance from the heat source, the distance being bridged by the flexible heat conductor.

In a specific embodiment, the flexible cooling element consists of thermally optimized or heat-conducting flexible mechanical joints, such as balls and hinges, for example.

In a more specific embodiment, a heat source comprises one or more flexible cooling elements according to the invention.

In another embodiment, known cooling systems such as cooling fins or cooling channels, such as, for example, air channels, are combined or supplemented with the flexible cooling elements of the invention. For example, in a specific embodiment, the flexible cooling elements can also be arranged on the cooling fins so as to guarantee an improved heat transfer from the cooling fins. The walls or ends of air ducts can also be provided with flexible cooling elements of the invention to ensure further cooling, or to, for example, minimize the fixed length of the air duct.

In yet another embodiment, one or more, whether or not identical or different, flexible cooling elements are provided. The cooling elements can have different flexibility, and / or consist of different heat-conducting materials depending on the required cooling and available location of installation and / or heat dissipation. Different flexible cooling elements can possibly take different forms. The flexible cooling elements can be installed at different places in the heat source depending on the room or method of attachment and / or heat quantity.

In yet another embodiment, one or more flexible cooling elements from different heat sources are coupled to each other and further derived via flexible cooling elements or any other cooling system. This is an application of, for example, a light source consisting of a plurality of LED lamps, wherein the individual LED lamps are each cooled via a flexible cooling element, wherein the separate flexible cooling elements come together and further heat dissipation takes place via a central cooling system or flexible cooling element.

In a particular embodiment, the flexible heat conductor is guided or supported by the necessary structural elements.

The flexible cooling elements of the invention find use in both low and high power LED lamps.

The invention also provides a method for cooling a heat source, the method comprising the steps of: a) connecting one or more flexible heat conductors from a solid to a heat source for dissipating heat, and b) connecting said heat source one or more flexible heat conductors on one or more cooling elements for absorbing that heat.

The invention also provides a flexible conductor for cooling a heat source, characterized in that the conductor is a solid-state heat conductor, which connects the heat source to a cooling element.

The invention further provides for the use of a flexible conductor as described above for cooling a heat source.

The invention will now be further elucidated with reference to the following detailed description and drawings, wherein Figure 1 represents an embodiment of an LED lamp construction comprising a flexible cooling element connected to the fixture; Figure 2 shows a photo of a prototype version of an LED lamp construction of Figure 1.

Figure 3 represents an LED lamp construction comprising a flexible cooling element connected to an external cooling element; Figure 4 represents a compact installation of an LED lamp construction according to the invention;

A preferred embodiment of an LED lamp construction according to the invention, as shown in Figure 1, consists of an LED lamp base (1) and fixture (2). A flexible cooling element (3), in the form of a litz wire, connects the base (1) of the LED lamp and the luminaire (2). This results in a heat transfer from the LED lamp to the fixture, which is in contact with the ambient air and temperature. The flexible cooling element is optionally supported here again.

Figure 2 shows a prototype version of an LED lamp construction according to Figure 1.

Figure 3 represents another embodiment according to the invention, wherein a flexible cooling element (3) provides heat dissipation from the base (1) of an LED lamp construction to an external cooling element (4) here equipped with cooling fins. The flexible cooling element (3) is designed as a heat-conducting mechanical joint.

Figure 4 shows an advantageous embodiment in which the flexibility of the heat-conducting cooling element (3) allows a compact installation in a small ceiling height (5). The flexible cooling element connects the base (1) with the fixture (2), and is also connected to an external cooling body (4) for an even more efficient heat transfer.

Claims (25)

LED lamp construction comprising a housing (2) for holding an LED lamp and at least one flexible conductor (3) for dissipating heat generated by the LED lamp to a cooling element, characterized in that the flexible conductor comprises a heat conductor from a fixed dust. LED lamp construction according to claim 1, characterized in that the flexible conductor (3) connects the base (1) of the LED lamp to the housing (2), a structural element and / or an external heat sink (4). LED lamp construction according to the preceding claim, characterized in that the external heat sink (4) consists of a cooling fin, air duct or fan. 4. LED lamp construction as claimed in claim 2, characterized in that the structural element forms part of the suspension, built-in or superstructure or is in the vicinity of the LED lamp, such as for example a preferably metal profile for roof and ceiling constructions, or verandas and sun blinds . LED lamp construction according to the preceding claims, characterized in that the flexible conductor (3) comprises one or more wires or ribbons. LED lamp construction according to the preceding claim, characterized in that the flexible conductor (3) comprises a litze wire. LED lamp construction according to the preceding claims, characterized in that the flexible conductor (3) comprises one or more mechanical joints. 8. LED lamp construction according to the preceding claim, characterized in that the mechanical joints comprise balls or hinges that allow a rotation and / or a translation. LED lamp construction according to the preceding claims, characterized in that the flexible conductor (3) is made of metal, preferably aluminum or copper. LED lamp construction according to the preceding claims, characterized in that the flexible conductor (3) has a thermal conductivity of at least 50 W / m-K, preferably at least 100 W / m-K, most preferably at least 200 W / m-K. 11. LED lamp construction according to the preceding claims, characterized in that the LED lamp construction is a built-in or surface-mounted version. LED lamp construction according to the preceding claims, characterized in that the flexible conductor (3) comprises one or more flexible heat conductors. LED lamp construction according to the preceding claim, characterized in that the one or more flexible heat conductors (3) are identical or different in terms of flexibility, material or shape. LED lamp construction according to claim 12 or 13, characterized in that the one or more flexible heat conductors (3) are attached to the LED lamp at the same or different places. LED lamp construction according to the preceding claims, characterized in that the construction comprises one or more LED lamps, each with its own housing (2) and / or a joint housing. LED lamp construction according to the preceding claim, characterized in that the one or more flexible conductors (3) of one or more LED lamps are coupled to each other. 17. Construction as claimed in the foregoing claims, characterized in that the LED lamp is replaced by a different heat source. A flexible conductor (3) for cooling a heat source, characterized in that the conductor is a solid-state heat conductor, which connects the heat source to a cooling element. A flexible conductor (3) according to the preceding claim, characterized in that the cooling element is either an external cooling body (4) or a structural element that forms part of the environment or is close to the heat source. A flexible conductor (3) according to claim 18 or 19, characterized in that the heat source comprises an LED lamp. A method for cooling a heat source, the method comprising the steps of: a. Connecting one or more flexible heat conductors (3) from a solid to a heat source for dissipating heat, and b. connecting said one or more flexible heat conductors (3) to one or more cooling elements for absorbing that heat. The method of claim 21, wherein the heat source comprises one or more LED lamps. A method according to claims 21 or 22, wherein the cooling element comprises the housing (2) of the heat source. A method according to claims 21 to 23, wherein the cooling element comprises an external cooling body (4) or other structural element. Use of a flexible conductor (3) of claims 19 or 20 for cooling a heat source, such as for example one or more LED lamps.