DE102018114765A1 - Motor vehicle headlamps - Google Patents

Abstract

Motor vehicle headlight (1) with a headlight housing (2), in which headlight housing (2) at least one light module (3) is arranged, the light module (3) having a lamp (4), and at least one cooling element (7), which is provided for this purpose is to extract heat from the light module (3), the cooling element (7) being arranged on the headlight housing (2) in such a way that the heat extracted from the light module (3) is emitted outside the headlight housing (2), the cooling element (7 ) arranged at a distance from the light module (3) and connected to the light module (3) via a connecting device (11), the connecting device (11) being thermally conductive.

Description

The invention relates to a motor vehicle headlight with a headlight housing, in which headlight housing at least one light module is arranged, the light module having a light source, and at least one cooling element which is provided to extract heat from the light module, the cooling element being arranged on the headlight housing in this way that the heat extracted from the light module is emitted outside the headlight housing.

In the case of the typical motor vehicle headlights disclosed in the prior art (for example in the WO 2015/024839 A1 shown) in which the light module as a light source, for example light emitting diodes, laser diodes, DLP (Digital Light Processing) elements or the like. appropriate cooling of the illuminant must take place. For this purpose, a cooling element, which is attached to the light module, is usually provided. Peltier elements or heat sinks with cooling fins are used as the cooling element, for example, when using a heat sink with cooling fins, an additional fan often guides an air flow in the direction of the cooling fins.

Disadvantageously, attaching a heat sink to the light module increases the weight on the one hand and the dimensions of the light module on the other hand, making the installation of the light module in the headlight housing more difficult. As a result, the attachment of a heat sink to the light module is particularly disadvantageous even if the light module can be pivoted to adjust the emitted light.

The object of the present invention is therefore to alleviate or eliminate the disadvantages of the prior art. The invention therefore has the particular aim of creating a motor vehicle headlight in which the light module on the one hand has the lowest possible weight and dimensions, and on the other hand has efficient cooling.

This object is achieved with a motor vehicle headlight with the features of claim 1. Preferred embodiments are specified in the dependent claims.

According to the invention, the cooling element is arranged at a distance from the light module, and is connected to the light module via a connecting device, the connecting device being thermally conductive.

The light module and the cooling element are arranged in a contactless manner in the motor vehicle headlight according to the invention. The spatial separation between the light module and the cooling element results in the advantage that the weight and the dimensions of the light module are not increased by a heat sink attached to it. The light module is therefore spatially spaced from the heat sink within the headlight housing. In other words, the light module and the cooling element are not connected directly to one another, but indirectly by means of a connecting device which is essentially arranged between the light module and the cooling element. One end region of the connecting device is preferably connected to the light module, and a second end region of the connecting device is connected to the cooling element. The connections between the light module and the connecting device and between the cooling element and the connecting device are preferably detachable, as a result of which an exchange of the cooling element, the light module and / or the connecting device is possible in a particularly simple manner. In order to conduct heat from the light module to the cooling element, the connecting device is designed to be thermally conductive. Furthermore, the contact points between the connecting device and the light module and between the connecting device and the cooling element are thermally conductive. This allows the light module to be cooled efficiently without the cooling element being attached directly to the light module. In order to cool the light module, the heat generated by the light module, which is conducted from the light module to the cooling element via the connecting device, is emitted by the cooling element outside the headlight housing. Accordingly, the cooling element is arranged on the headlight housing in such a way that the heat extracted from the light module is emitted outside the headlight housing. The cooling element preferably has a heat sink and cooling fins, the cooling fins being arranged essentially outside the headlight housing in order to dissipate the heat to the surroundings or outside the headlight housing. In other words, the cooling element is essentially arranged on the headlight housing or on a headlight housing wall. A portion of the heat sink preferably projects into the interior of the headlamp housing and is connected to an end region of the connecting device.

The connecting device preferably comprises at least one heat pipe. The use of a heat pipe ensures a particularly efficient heat transfer between the light module and the cooling element, since heat pipes have a particularly high thermal conductivity. Furthermore, heat pipes are characterized in that heat transfer between the light module and the cooling element already takes place at small temperature differences of 0.5 ° C - 2 ° C. In addition, heat pipes are free of moving components, which means that they are low-wear and low-maintenance, and heat pipes are essentially silent. Water is preferably used as the working medium. In order to guarantee the functionality of the heat pipes even at particularly low temperatures, a working medium can be used as an alternative to water, which is still capable of working at low temperatures (e.g. methanol). The cross section of the heat pipe can be circular, oval, flattened or the like. his. The diameter of the heat pipe is preferably between 0.6 mm and 25 mm.

In order to ensure a particularly efficient heat transfer between the light module and the cooling element, the connecting device can comprise two or more heat pipes, the heat pipes preferably being arranged parallel to one another. By using several heat pipes, the heat-conducting surface can be enlarged, whereby the cooling of the light module can take place more efficiently.

The two or more heat pipes are preferably arranged vertically one above the other or horizontally next to one another. The arrangement of the heat pipes within the headlight housing can thus take place as space-saving as possible. A spacing between the individual heat pipes which is equidistant in the vertical direction is particularly preferred. Should it be advantageous for reasons of space, the two or more heat pipes can also be arranged one above the other in a cross.

In a preferred embodiment, the at least one heat pipe is made of copper or a copper alloy. Copper is advantageously easily deformable, has a high thermal conductivity and is also corrosion-resistant. Cu-OF (unalloyed oxygen-free copper) is preferably used, since it has improved hydrogen resistance compared to oxygen-containing copper. The material properties (for example deformability, thermal conductivity, corrosion resistance, etc.) of the heat pipes can be further improved by coatings or through the use of copper alloys, for example copper cast iron, copper zinc, copper tin, copper nickel nickel zinc. , Copper-nickel or copper-aluminum alloys. Possible coating methods include, for example, nickel plating, painting or powder coating. Alternatively, the at least one heat pipe can also be made of a plastic.

The at least one heat pipe preferably has at least one bend, the bending radius preferably being substantially greater than or equal to three times the heat pipe diameter. This minimum bending radius is due to the fact that the heat conductivity of the heat pipe decreases as the bending radius decreases. In order to ensure a sufficiently high thermal conductivity of the heat pipe, a minimum bending radius is advantageous. The at least one heat pipe can, for example, be U, S, W, or spiral-shaped. In the event that a plurality of heat pipes connect the light module to the cooling element, it is advantageous if the plurality of heat pipes each have the same bend or the same bends, and thus the same geometric shape. If several heat pipes are used instead of a single heat pipe, the respective diameters of the several heat pipes are preferably smaller than the diameter of the individual heat pipe.

In order to be able to change the angle of the light emitted by the light module (for example onto a roadway), it is advantageous if the light module is arranged pivotably in the headlight housing. The light module can preferably be pivoted about a horizontal and / or a vertical pivot axis. By pivoting the light module around the horizontal pivot axis, the angle of the emitted light can be adjusted relative to the road (this corresponds to pivoting the light module in a vertical plane). By pivoting the light module around the vertical swivel axis, e.g. an adaptive headlights can be realized (this corresponds to a pivoting of the light module in a horizontal plane).

A pivoting device is preferably provided for pivoting the light module in the headlight housing about a pivot axis, a servomotor being preferably provided as the pivoting device. A technically simple and precise pivoting of the light module is thus advantageously possible. The servomotor is essentially intended to carry out a linear movement, wherein preferably a force transmission element converts the linear movement of the servomotor into a swiveling movement and then transmits it to the light module. The servomotor can be provided to pivot the light module preferably about a vertical and / or a horizontal pivot axis. In the non-pivoted state, the light module can be present in a basic setting in the headlight housing, and the servomotor can be used to dynamically pivot the light module from the basic setting to a pivoting setting. If the motor vehicle headlight is installed in a motor vehicle, for example, the pivoting of the light module due to cornering can be uneven Load condition of the motor vehicle, an ascent or descent, etc. respectively.

The at least one heat pipe can preferably be designed as a spring element, which is provided to dampen the pivoting of the light module. The damping effect of the heat pipes during the pivoting of the light module by the pivoting device can advantageously minimize the “play” (that is, the freedom of movement of the light module within the headlight housing and the freedom of movement of the mounting points of the light module in the headlight housing) of the headlamp leveling control. The spatial orientation of the light module within the headlight housing, and thus the adjustment of the angle of the light emitted by the light module, can thus be changed particularly precisely. So that the at least one heat pipe or the several heat pipes that connect the light module to the cooling element can produce a spring action, these are preferably U, S, W or spiral-shaped. However, depending on the requirement (for example, space requirement in the headlight housing , Arrangement of the light module in relation to the cooling element, desired spring return force, etc.), other shapes for the heat pipes are also possible. Likewise, the material of the heat pipe or the heat pipes can be selected such that it has the required thermal conductivity on the one hand and the elastic properties required for the effect as a spring element on the other hand. The design of the heat pipe as a spring element has the surprising effect that the connecting element, which connects the light module to the cooling element and is intended to transport the heat extracted from the light module to the cooling element, simultaneously dampens the pivoting of the light module and additionally that Game of headlamp leveling minimized. This advantageously results in a significant reduction in the number of components required and a simplification of numerous mechanisms. In addition to efficient cooling and a damped (and therefore very precise) swiveling of the light module, as well as minimal play of the headlamp leveling control, the production costs and the weight of the headlamp are also reduced.

At least one light-emitting diode or at least one laser diode is preferably provided as the illuminant. Essentially, laser diodes or high-current light-emitting diodes are particularly preferred, since they bring with them numerous advantages, such as, for example, high brightness, a long range of the emitted light and a particularly compact design of the light sources.

In order to optimize the cooling performance of the cooling element, the cooling element is preferably arranged in the vertical direction above the light module. The position specification “vertically above” relates to a motor vehicle headlight that is installed as intended in a motor vehicle. The preferred arrangement of the cooling element above the light element promotes heat transport within the heat pipe, since the working medium, which dissipates heat from the light module, is conveyed upwards (to the cooling element) in the vertical direction by the steam pressure within the heat pipe. The amount of heat transported by the working medium is subsequently released to the cooling element, the cooled and condensed working medium then being returned to the light module via the heat pipe. This return process of the working medium takes place on the one hand through the capillary force which arises within the heat pipe, and on the other hand is additionally favored by gravity in the preferred vertical arrangement of the light module and cooling element. This advantageously favors the movement of the working medium within the heat pipe in both directions (from the light module to the cooling element and vice versa), as a result of which the heat transport, and thus the cooling of the light module, can take place more efficiently. Should it be advantageous for reasons of space, the cooling element can also be arranged in the vertical direction below or at the same height of the light module. In these cases, the capillary force can be increased by reducing the heat pipe diameter in order to at least partially compensate for the missing effect of gravity.

In order to be able to give off the heat extracted from the light module outside the headlight housing, the cooling element is preferably arranged on an edge region of the headlight housing are. The cooling element can also be arranged outside and only one contact point to the heat pipe inside the headlight housing.

In order to additionally promote the cooling of the light module, the headlight housing preferably has an air duct, which is provided to direct an air flow, which is caused by a movement of the headlight, to the cooling element. In this context, the movement of the motor vehicle headlight is a consequence of a movement of the motor vehicle. The air flow directed from the air duct to the cooling element causes the heat to be dissipated by the light module and released via the cooling fins released to the environment faster and more efficiently. Furthermore, an additional cooling fan, which directs an air flow in the direction of the cooling fins, can be dispensed with.

The air duct preferably runs along an outer surface of the headlight housing. The position of the air duct on the headlight housing is particularly preferably selected such that part of the air flow which enters the engine compartment via cooling air inlets on the front of the motor vehicle can be guided into the air duct on the headlight housing. With such an arrangement, the airstream that arises when the motor vehicle is moving can advantageously be used at least partially for cooling the light module. The air duct can also be designed as an additional component, the additional component preferably being arranged within the engine compartment in such a way that the air flow is conducted to the cooling fins of the cooling element. The additional component can, for example, be configured in the form of a tube.

In the context of this description, the terms “above”, “below”, “horizontally” and “vertically” are to be understood as indications of the orientation when the motor vehicle headlight is arranged in the normal use position after it has been installed in a motor vehicle.

• 1 eine schematische, stark vereinfachte Ansicht eines erfindungsgemäßen Kraftfahrzeugscheinwerfers;
• 2 eine Seitenansicht des Scheinwerfers gemäß 1;
• 3 bis 5 mögliche Ausführungsformen eines Wärmerohrs; und
• 6 eine alternative Ausführungsform des Kraftfahrzeugscheinwerfers.

The invention is explained in more detail below on the basis of preferred exemplary embodiments, to which, however, it should not be restricted. The drawing shows:

• 1 a schematic, greatly simplified view of a motor vehicle headlight according to the invention;
• 2 a side view of the headlight according to 1 ;
• 3 to 5 possible embodiments of a heat pipe; and
• 6 an alternative embodiment of the motor vehicle headlight.

1 shows a schematic, highly simplified motor vehicle headlights according to the invention 1 with a headlight housing 2 in which headlight housing 2 at least one light module 3 is arranged. The light module 3 has a lamp 4 on, as the illuminant 4 preferably at least one laser diode 5 is provided. However, other illuminants can also be used 4 are used, such as light emitting diodes, DLP elements, or the like. The illuminant 4 is on a support frame 6 attached. The motor vehicle headlight also includes 1 at least one cooling element 7 , which is provided for the light module 3 To withdraw heat. The cooling element 7 is on the headlight housing 2 is arranged such that the light module 3 extracted heat outside the headlight housing 2 is delivered. The cooling element 7 has a heat sink 8th and cooling fins 9 on, the cooling fins 8th outside the headlight housing 2 are arranged. The heat sink 8th is at least partially inside the headlight housing 2 arranged. As in 1 and 2 the heat sink is visible 8th essentially on a headlamp housing wall 10 attached. With such an arrangement it can be ensured that the light module 3 extracted heat as completely as possible to the environment (outside the headlight housing 2 ) is delivered. The cooling element 7 is from the light module 3 spaced apart, and via a connecting device 11 with the light module 3 connected, the connecting device 11 is thermally conductive. The connection device 11 includes three heat pipes 12 (which are made of copper or a copper alloy) which are vertically one above the other and parallel to one another (see 2 ) are arranged.

In the embodiment according to the 1 and 2 are the three heat pipes 12 (viewed from above, see 1 ) S-shaped. The heat pipes 12 thus have two bends, the bending radius being greater than three times the heat pipe diameter.

Depending on the requirements, any number of heat pipes can be used 12 used to the light module 3 with the cooling element 7 connect to. The number, the geometric shape and the orientation or location of the heat pipes 12 each other can be different, and is essentially dependent on how the cooling element 7 relative to the light module 3 is arranged. An exemplary, non-exhaustive selection of possible geometric shapes for heat pipes 12 is in the 3 to 5 seen.

End sections of the heat pipes 12 are each with mounting plates 13 on a support frame 6 of the light module 3 and on a section 14 of the cooling element 7 attached. The mounting plates 13 essentially clamp the heat pipes 12 to the support frame 6 of the light module 3 or to the section 14 of the cooling element 7 , Alternative fastening methods are, for example, soldering, gluing, pressing, welding, or the like. The contact between the illuminant 4 and the heat pipes 12 or between the heat pipes 12 and the cooling element 7 is thermally conductive, which means that of the lamp 4 heat can be dissipated from this. The heat pipes 12 conduct the heat to the cooling element 7 , taking over the cooling fins 9 the heat outside the headlight housing 2 is delivered.

The light module 3 is in the headlight housing 2 arranged pivotably, wherein a pivoting device 15 is provided for the light module 3 in the headlight housing 2 to pivot a pivot axis. As a swivel device 15 is preferably a servomotor 16 intended. The servomotor 16 generates a linear movement, which is from a power transmission element 17 converted into a swivel movement, and to the light module 3 is transmitted. For this is the power transmission element 17 with the light module 3 accordingly articulated.

As in 1 (or also the 3 to 5 ) are visible, are the heat pipes 12 designed as a spring element. By at least one bend or the geometric shape and the material of the heat pipes 12 can provide a spring force, the pivoting of the light module 3 through the pivoting device 15 against this spring force. This dampens the pivoting and minimizes the "play" in the headlamp leveling.

In the embodiment according to 6 is the cooling element 7 in the vertical direction above the light module 3 is arranged (the headlight housing 2 is in 6 not shown). The position specification “above” relates to a motor vehicle headlight that is installed as intended in a motor vehicle 1 , With this arrangement, the movement of the working medium (and thus the heat transfer) from the light module 3 to the cooling element 7 and the return of the working medium from the cooling element 7 to the light module 3 favored.

As in the 1 and 2 also visible is the cooling element 7 at an edge area of the headlight housing 2 arranged. So that are the cooling fins 9 outside and at least a portion of the heat sink 8th inside the headlight housing 2 arranged. This arrangement is generally provided in all of the exemplary embodiments.

The headlight housing 2 also has an air duct (not shown), which is provided for an air flow, which is caused by a movement of the motor vehicle headlight 1 (as a result of movement of the motor vehicle) to the cooling element 7 to lead. The air duct runs along an outer surface of the headlight housing 2 ,

Since the structure, the mode of operation and the configuration of heat pipes are generally known to a person skilled in the art, a detailed discussion of these subject areas is omitted in this disclosure.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• WO 2015/024839 A1 [0002]

Claims (14)

Motor vehicle headlight (1) with a headlight housing (2), in which headlight housing (2) at least one light module (3) is arranged, the light module (3) having a lamp (4), and at least one cooling element (7), which is provided for this purpose is to extract heat from the light module (3), the cooling element (7) being arranged on the headlight housing (2) in such a way that the heat extracted from the light module (3) is emitted outside the headlight housing (2), characterized in that Cooling element (7) is arranged at a distance from the light module (3) and is connected to the light module (3) via a connecting device (11), the connecting device (11) being heat-conducting. Motor vehicle headlights (1) after Claim 1 , characterized in that the connecting device (11) comprises at least one heat pipe (12). Motor vehicle headlights (1) after Claim 2 , characterized in that the connecting device (11) comprises two or more heat pipes (12), the heat pipes (12) preferably being arranged parallel to one another. Motor vehicle headlights (1) after Claim 3 , characterized in that the two or more heat pipes (12) are arranged vertically one above the other or horizontally next to one another. Motor vehicle headlights (1) according to one of the Claims 2 to 4 , characterized in that the at least one heat pipe (12) is made of copper or a copper alloy. Motor vehicle headlights (1) according to one of the Claims 2 to 5 , characterized in that the at least one heat pipe (12) has at least one bend, the bending radius preferably being substantially greater than or equal to three times the heat pipe diameter. Motor vehicle headlights (1) according to one of the Claims 1 to 6 , characterized in that the light module (3) in the headlight housing (2) is pivotally arranged. Motor vehicle headlights (1) after Claim 7 , characterized in that a pivoting device (15) is provided for pivoting the light module (3) in the headlight housing (2) about a pivot axis, a servomotor (16) preferably being provided as the pivoting device. Motor vehicle headlights (1) after Claim 8 , characterized in that the at least one heat pipe (12) is designed as a spring element which is provided to dampen the pivoting of the light module (3). Motor vehicle headlights (1) according to one of the Claims 1 to 9 , characterized in that at least one light-emitting diode or at least one laser diode (5) is provided as the illuminant (4). Motor vehicle headlights (1) according to one of the Claims 1 to 10 , characterized in that the cooling element (7) is arranged in the vertical direction above the light module (3). Motor vehicle headlights (1) according to one of the Claims 1 to 11 , characterized in that the cooling element (7) is arranged on an edge region of the headlight housing (2). Motor vehicle headlights (1) according to one of the Claims 1 to 12 , characterized in that the headlight housing (2) has an air duct which is provided to direct an air flow which is caused by a movement of the motor vehicle headlight (1) to the cooling element (7). Motor vehicle headlights (1) after Claim 13 , characterized in that the air duct runs along an outer surface of the headlight housing (2).

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