Patent Grant
7478932
1. Field of the Invention
The invention relates generally to a headlamp assembly for a motor vehicle. More specifically, the invention relates to the providing of airflow to cool the headlamp assembly.
2. Related Technology
Headlamp assemblies have a light source, such as an incandescent lamp, a light emitting diode (LED) or high intensity discharge (HID) lamp, positioned within a headlamp chamber and electrically connected to a power source. The headlamp chamber is typically defined by a transparent or translucent lens, located forward of the light source, and a reflector located rearward and/or surrounding the light source. As used herein, the terms forward and rearward are referenced with respect to the position of the light source and the direction in which the light from the source is intended to be seen. Thus light from the assembly is intended to be seen from a forward position.
During an operation cycle of the headlamp assembly, the light sources and other components of the lamp generate heat while “on” and cool while “off”, causing the chamber to undergoes temperature fluctuation and causing the air located within to expand and contract. To maintain a relative-constant chamber pressure, the chamber typically includes at least one opening that permits an air exchange between the chamber and the ambient air. However, to prevent contaminants, such as dust and debris, from entering the chamber, the opening is typically relatively small and is covered with an air-permeable membrane.
In order to attain designed optimal performance of newer light sources, LED'S and their electrical components in the lamp assembly, it is desirable to maintain the internal temperature of the lamp assembly below the maximum operating temperature Therefore, it is advantageous to provide the headlamp assembly with a mechanism that cools the chamber and the LED'S located therein.
Headlamp assemblies are typically secured to a portion of the vehicle frame that is adjacent to the engine compartment. The temperature within the engine compartment is often significantly higher than the temperature outside of the engine compartment (the ambient temperature). For example, during operation of the vehicle various components, such as the engine and the engine cooling system, output heated air into the engine compartment. As another example, during periods of vehicle use and nonuse, the air trapped within the engine compartment may become heated by solar energy. Therefore, it is advantageous to provide the headlamp assembly with a mechanism that isolates the chamber and the light sources located therein from the relatively high temperatures of the engine compartment.
In view of the above, it is beneficial to have a headlamp assembly that has a mechanism that effectively cools the mechanism's internal components while minimizing air exchange between the headlamp assembly chamber and the atmosphere and while isolating the chamber from the engine compartment and the relatively high temperatures associated therewith.
In overcoming the above limitations and other drawbacks, a headlamp assembly for a motor vehicle is provided that includes a light source, a chamber that receives the light source, and a cooling channel for removing heat from the chamber. The headlamp assembly also includes a conductive wall and an insulating wall that cooperate to define the chamber and the channel. For example, the conductive wall has a first surface defining the chamber and a second surface that cooperates with the insulating wall to define the cooling chamber. The conductive wall has a substantially higher thermal conductivity than the insulating wall to promote the heat exchange between the chamber and the cooling channel and to reduce heat exchange between the cooling channel and the relatively hot engine compartment.
In one aspect of the present invention, the insulating wall thermal conductivity is less than or equal to 5.0 W/(m·K), where W=Watts, m=meter and K=Degrees Kelvin and the conductive wall thermal conductivity is greater than or equal to 10.0 W/(m W/(m·K). In a more preferred design, the insulating wall thermal conductivity is less than or equal to 1.0 W/(m·K) and the conductive wall thermal conductivity is greater than or equal to 20 W/(m·K). In an even more preferred design, the insulating wall thermal conductivity is less than or equal to 0.5 W/(m·K) and the conductive wall thermal conductivity is greater than or equal to 50 W/(m·K).
The conductive wall is made of a conductive material, such as a metal, a metal alloy, or a graphite material. In one design, the conductive wall includes a plurality of conductive materials, such as metal, metal alloy, silicon, or graphite materials, embedded within a base material, such as a polymer. In this design, the conductive components improve the conductivity of the wall, while base material serves as a relatively light, moldable support structure for the conductive components. The insulating wall is made of an insulating material, such as a glass or polymer material.
In another aspect, the headlamp assembly includes a divider extending between the conductive wall and the insulating wall to define a plurality of cooling channel portions. The divider extends into the chamber to promote the heat exchange between the chamber and the cooling channel. More specifically, the portion of the divider extending into the chamber conducts heat from the chamber into the cooling channel.
In yet another aspect, an inlet is located adjacent to a bottom portion of the headlamp assembly and an outlet is located adjacent to a top portion of the headlamp assembly. This configuration promotes the migration of relatively hot air towards the outlet by utilizing natural properties of fluids. Furthermore, the inlet and the outlet are configured so that air currents caused by the movement of the vehicle naturally flow in the upward direction, from the inlet to the outlet.
To further promote heat exchange between the chamber and the cooling channel, the headlamp assembly further includes a thermoelectric device (TED) coupled to the conductive wall. For example, the thermoelectric device has a plate with a first portion positioned within the cooling channel and a second portion positioned within the chamber, and the thermoelectric device (TED) is in electrical connection with a power source. An electrical current is provided from the power source to the TED such that the first portion becomes cooler than the second portion, thus promoting air from the chamber to undergo heat exchange with the air in the cooling channel.
As another aspect, the mechanism for promoting heat exchange between the chamber and the cooling channel, also includes a plurality of fins extending from the light source to promote heat transfer from the light source to the chamber. For example, the fins conduct heat away from the light source, in the direction of the cooling channel, into the chamber air. Therefore, the fins are preferably formed of a conductive material, such as metal.
Further objects, features and advantages of this invention will become readily apparent to persons skilled in the art after a review of the following description, with reference to the drawings and claims that are appended to and form a part of this specification.
Referring now to the drawings,
The headlamp assembly 10 includes surfaces that cooperate to focus the light rays into a beam having desired characteristics and direct the light rays towards the lens 14. For example, an interior reflector 20 is positioned within the chamber 16 for re-directing the forward-directed rays at the thermally conductive wall inner surface 12a, which is preferably a light-reflecting surface. Inner surface 12a reflects the rays in the forward direction toward and through the lens 14.
The thermally conductive wall 12 and the lens 14 are connected with each other such that the chamber 16 is substantially sealed from the atmosphere. The chamber 16 is, however, provided with a pair of pressure vents 22, 24. Both vents 22, 24 are relatively small openings between the thermally conductive wall 12 and the lens 14 that permit a relatively small amount of airflow into and out of the chamber 16 to account for air pressure fluctuations during temperature changes within the chamber 16. Alternatively, the number of vents in the headlamp assembly 10 and their location may be varied as required by various design criteria.
In order to restrict contaminants such as dust and debris from entering the chamber, vent covers 26, 28 are positioned over the vents 22, 24. The vent covers 26, 28 also substantially prevent moisture from accumulating within the chamber 16 by permitting moisture to permeate and drain out of the vents 22, 24 and while preventing water from entering into the chamber 16. The vent covers 26, 28 shown in the figures are thus composed of an air/moisture-permeable membrane, such as GORE-TEX®, but any appropriate material may be used.
The light source 18, hereinafter just “LED 18”, is attached to a printed circuit board (PCB) 32 that includes electronic controls and connections for the LED 18. Furthermore, the LED 18 and the PCB 32 are supported by a heat sink 34 having heat exchange fins 38 that conduct heat away from the LED 18, as will be further discussed below. The heat sink 34 is constructed of a material having a relatively high thermal conductivity, and is connected to the thermally conductive wall 12 by a support post 36. The post 36 thus supports the LED 18 and contains the electrical connectors (not shown) extending between the LED 18 and a power source. The support post 36 is preferably connected to the thermally conductive wall 12 by any suitable connection, such as welding or fastening. Alternatively, the respective components 12, 36 are formed as a single, unitary component.
During operation of the headlamp assembly 10, the LED 18 generates heat and increases the temperature of the air, components and structures located within the chamber 16. However, the LED 18 and/or other electronic components may experience diminished performance or failure if their maximum operating temperature is exceeded. To reduce the temperature of these components, the headlamp assembly 10 of the present invention therefore includes a cooling channel 40 that extends adjacent to and extracts heat from the chamber 16.
The cooling channel 40 is defined in part by a thermally insulating wall 42 having an inner surface 42a and an outer surface 42b, wherein the insulating wall inner surface 42a cooperates with the thermally conductive wall outer surface 12b to define the cooling channel 40. Additionally, the cooling channel 40 includes an inlet 50 for receiving a relatively cool inlet airflow 51 from the atmosphere and an outlet 52 for venting a relatively warm outlet airflow 53 back into the atmosphere. The inlet 50, which is positioned adjacent to the bottom 54 of the headlamp assembly 10, is lower than the outlet 52, which is positioned adjacent to the top 56 of the headlamp assembly 10. This construction promotes natural convective airflow through the channel 40. Therefore, even while the vehicle is stationary, the cool inlet airflow 51 is naturally drawn into the channel 40 from the atmosphere.
The thermally conductive wall 12 and the thermally insulating wall 42 are preferably spaced apart from each other along their respective lengths so that the cooling channel 40 has a substantially constant width; thereby minimizing flow loss across the cooling channel 40.
As seen in
The headlamp assembly 10 shown in the figures includes various mechanisms for increasing the heat transfer between the LED 18 and the cooling channel 40. As mentioned above, the heat exchange fins 38 conduct heat away from the LED 18 and towards the thermally conductive wall 12. Additionally, the connector post 36 conducts heat directly to the thermally conductive wall 12. Therefore, the heat exchange fins 38 and the connector post 36 are both preferably made of a material with a relatively high thermal conductivity, such as a material having a thermal conductivity that is greater than or equal to 10.0 W/(m·K). More preferably, the heat exchange fins 38 and the connector post 36 are made of a material having a thermal conductivity that is greater than or equal to 20 W/(m·K). Even more preferably, the heat exchange fins 38 and the connector post 36 are made of a material having a thermal conductivity that is greater than or equal to 50 W/(m·K). For example, the heat exchange fins 38 and the connector post 36 are made of a metal, a metal alloy, silicon, or a graphite material. In a more specific example, the heat exchange fins 38 and the connector post 36 are made of aluminum. In another example, the heat exchange fins 38 and the connector post 36 include a plurality of conductive components, such as a metal, a metal alloy, a silicon, or a graphite material, embedded within a base material, such as a polymer. In this design, the conductive components improve the conductivity of the wall, while base material serves as a relatively light, moldable support structure for the conductive components.
After being conducted away from the heat exchange fins 38, the heat from the LED 18 is transferred to the thermally conductive wall 12 by natural convection. Although the airflow through the chamber 16 is relatively low due to its substantially sealed nature, natural temperature gradients cause the heated air near the tips of the heat exchange fins 38 to flow towards the thermally conductive wall 12; thereby improving convection between the fins 38 and the wall 12.
Next, the thermally conductive wall 12 serves as a second mechanism for increasing the heat transfer between the LED 18 and the cooling channel 40. More specifically, the thermally conductive wall 12 conducts heat from the chamber 16 into the cooling chamber 40, where heated air is distributed into the atmosphere as discussed above. Therefore, the thermally conductive wall 12 is made of a material with a relatively high thermal conductivity, such as a material having the preferred thermal conductivities previously mentioned above. Examples of materials for the thermally conductive wall 12 include metal, metal alloy, silicon, or graphite material, and more specifically, aluminum. In another example, the thermally conductive wall 12 may include a plurality of conductive components, such as a metal, a metal alloy, or a graphite material, embedded within a base material, such as a polymer. In this design, the benefits discussed above are equally applicable.
A thermoelectric device (TED) 58 serves as a third mechanism for increasing the heat transfer between the LED 18 and the cooling channel 40. The TED 58 shown in
The headlamp assembly 10 also includes various mechanisms for insulating the cooling channel 40 from the relatively hot temperatures of the engine compartment 48. First, as discussed above, the inlet 50 of the cooling channel 40 is preferably positioned away from the engine compartment 48 to reduce the likelihood that the inlet airflow 51 absorbs heat from the relatively hot components of the engine compartment 48 before entering the cooling channel 40. It may, however, be beneficial to position the outlet 52 of the cooling channel 40 adjacent to the engine compartment 48 so as to increase the temperature gradient between the inlet 50 and the outlet 52 and thereby increase the natural airflow velocity therebetween.
The thermally insulating wall 42 serves as a second mechanism for insulating the cooling channel 40 from the relatively hot temperatures of the engine compartment 48. More specifically, the thermally insulating wall 42 is preferably made of a material with a relatively low thermal conductivity, such as a material having a thermal conductivity that is less than or equal to 5.0 W/(m·K). More preferably, the thermally insulating wall 42 is made of a material having a thermal conductivity that is less than or equal to 1.0 W/(m·K). More preferably, the thermally insulating wall 42 is made of a material having a thermal conductivity that is less than or equal to 0.5 W/(m·K) and even more preferably the thermal conductivity is less than or equal to 0.2 W/(m·K). As such, the thermally insulating wall 42 may be made of glass, such as soda-lime glass, borosilicate glass; a ceramic, such as pyroceram; or a polymer such as rubber, epoxy, nylon, phenolic, polybutylene terephthalate (PBT), polycarbonate (PC), polyester, polyethylene (PE), polyethylene terephthalate (PET), polyimide, polymethyl methacrylate (PMMA), polypropylene (PP), polystyrene (PS), polytetrafluoroethylene (PTFE), polyvinyl chloride (PVC), or silicone. In a more specific example, the thermally insulating wall 42 is made of polypropylene.
By defining the cooling chamber 40 between the thermally conductive wall 12 and the thermally insulating wall 42, the headlamp assembly 10 is able to promote desirable types of heat transfer and prevent undesirable types of heat transfer, while minimizing part complexity and part cost. For example, the cooling chamber 40 has a generally large surface because it extends along the entire surface of the thermally conductive wall 12. As another example, the cooling chamber 40 is formed with minimal part complexity and part cost because it is formed by coupling two walls 12, 42, each having a relatively low part complexity, adjacent to each other.
Referring now to
A plurality of dividers 166 extends between the thermally conductive wall 112 and the thermally insulating wall 142. The dividers define a plurality of cooling channel portions 140a, 140b, 140c, 140d, 140e, 140f, 140g, 140h, 140i, 140j, and 140k within the channel 140 itself. Although eleven cooling channel portions are shown in
It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that it be understood that it is the following claims, including all equivalents, that are intended to define the spirit and scope of this invention.
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