ES2609627T3 - Light module capable of adjusting the angle of illumination and using phase dissipation thermal dissipation - Google Patents

Abstract

A light module (10), capable of adjusting the illumination angle and utilizing phase change thermal dissipation, comprising: an illumination component (12); and a heat dissipation component (14), with a side that is in thermal contact with the lighting component, in which the heat dissipation component (14) comprises a first chamber (145), and a second chamber ( 146), in that the distance from the second chamber (146) to the lighting component (12) is greater than that of the first chamber (145) to the lighting component (12) and a working liquid (19) that is filled in the first chamber (145); in which the lighting module is characterized in that the heat dissipation component (14) further comprises two flexible channels that flexibly connect the first chamber (145) and the second chamber (146); each of the two flexible channels (148) comprises a plurality of rings (1481) that are connected to each other in series, respectively; wherein the lighting component (12) has a light-emitting surface (125), and the two flexible channels (148) can be bent to adjust an angle between a normal vector of the light-emitting surface (125) and a direction absolutely vertical in a range from 0 to 90 degrees; in that, when the working liquid (19) absorbs heat generated from the lighting component (12), the working liquid (19) vaporizes from a liquid state to a gaseous state and flows into the second chamber (146) at through one of the flexible channels (148) for heat dissipation, and after the working liquid (19) in the second chamber (146) condenses from the gaseous state to the liquid state, it flows back to the first chamber (145) through the other flexible channel (148).

Description

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Description

Light module capable of adjusting the lighting angle and using thermal dissipation of phase change. Technical Field

The description refers to a light module that uses thermal phase change dissipation, more particularly, to a light module that is capable of adjusting the angle of illumination and the use of thermal phase change dissipation.

Background

Despite not having replaced all traditional incandescent lamps, light emitting diodes (LEDs) have become popular lighting devices. Compared to traditional incandescent lamps, LEDs have the advantages of being environmentally friendly and energy saving. In addition, LEDs have a longer lifespan than incandescent lamps. A plurality of LEDs mounted together can be a source of high power and high brightness light, thus being able to replace indoor and outdoor incandescent lamps. Since LEDs are ecological, they are expected to be the future of the lighting industry.

However, the current LED heat dissipation process is applied by thermal conduction, but its results are not satisfactory. On the other hand, the LED comprises fins for heat dissipation. However, the fins require a large amount of space for disposal, which affects the space allocation of the LED components. In general terms, a region of illumination of an LED lamp is fixed so that users have to arrange additional lamps when the region that is illuminated needs to be changed, thereby increasing the cost of the arrangement of the lamps. Therefore, it is crucial to design a heat dissipation system for the LED to improve the flexibility of the region that illuminates.

US 2011/0267815 A1 describes a motor and a thermosiphon lamp that includes a condenser, an evaporation chamber and a connection element between them. The condenser converts a gaseous substance located therein into a liquid substance. The evaporation chamber includes a solid state light source, a working liquid and an optical element that shapes the light emitted by the at least one solid state light source. The solid state light source is immersed in the working liquid so that the heat generated by the solid state light source converts the work light into a gaseous substance. The gaseous substance passes through the condenser connection element, which converts the gaseous substance into a liquid substance. The liquid substance then passes through the connection element and returns to the evaporation chamber. However, the heat dissipation process is not very flexible and can be improved.

TW M 468 784 U describes a lighting component and a heat dissipation component with a first and a second chamber. However, the heat dissipation process is not very flexible and can be improved.

SUMMARY

The description is a light module to solve the unsatisfactory performance of heat dissipation and the angle of illumination not adjustable.

A light module that is capable of adjusting the angle of illumination and that uses thermal phase change dissipation comprises a lighting component and a heat dissipation component with a side that is in thermal contact with the lighting component. The heat dissipation component has a first chamber, a second chamber and two flexible connection channels that flexibly connect the first chamber and the second chamber. The distance from the second chamber to the lighting component is greater than that of the first camera to the lighting component, and a working fluid is filled in the first chamber. When the working liquid absorbs the heat generated in the lighting component, the working liquid vaporizes from a liquid state to a gaseous state and flows to the second chamber through one of the two flexible channels for heat dissipation. After the working liquid in the second chamber has condensed from a gaseous state to a liquid state, it flows back to the first chamber through the other flexible channel.

Therefore, a dclic loop is formed by means of the arrangement of the two flexible channels, the first chamber and the second chamber, and a convection induced by a phase change of the working liquid conducts heat in the first dclic loop. This design of the structure can omit the active heat dissipation component and can significantly improve the heat dissipation effect. In addition, the first camera connected to the lighting component can be moved to change a relative position of the lighting component and the second camera by folding the two flexible channels. For the

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Therefore, users can manually change a lighting zone of the lighting component to improve the viability of the light module.

BRIEF DESCRIPTION OF THE DRAWINGS

The present description will be more fully understood from the detailed description given below, together with the accompanying drawings, which are for illustration only, and therefore are not limiting of the present description, and in which:

FIG. 1 is a perspective view of a light module that is capable of adjusting the illumination angle and using the thermal phase change dissipation according to a first embodiment of the description;

FIG. 2 is a sectional view of the light module in FIG. 1 when a first main body is located in a first position;

FIG. 3 is a sectional view of the light module in FIG. 1 when the first main body is located in a second position; Y

FIG. 4 is a sectional view of the light module in FIG. 1 when the first main body is located in a third position.

DETAILED DESCRIPTION

In the following detailed description, for purposes of explanation, numerous specific details are set forth in order to provide a complete understanding of the described embodiments. It will be evident, however, that one or more embodiments can be practiced without these specific details. In other cases, well-known structures and devices are shown schematically in order to simplify the drawings.

FIG. 1 is a perspective view of a light module that is capable of adjusting the illumination angle and using the thermal phase change dissipation according to a first embodiment of the description. As seen in FIG. 1, in this embodiment, the light module 10 comprises a lighting component 12 and a heat dissipation component 14. One side of the heat dissipation component 14 is in thermal contact with the lighting component 12. The component Illumination 12 is a solid state light emitting element. In this embodiment, the lighting component 12 is a light emitting diode, but the description is not limited thereto.

FIG. 2 is a sectional view of the light module in FIG. 1 when a first main body is located in a first position. As seen in FIG. 2, the heat dissipation component 14 has a first main body 141, a second main body 142, a first chamber 145, a second chamber 146, two flexible channels 148, a group of fins 149 and a working liquid 19.

One side of the first main body 141 is in thermal contact with the lighting component 12. The first chamber 145 is located in the first main body 141, while the second chamber 146 is located in the second main body 142. The two channels flexible 148 are located between the first chamber 145 of the first main body 141 and the second chamber 146 of the second main body 142 and connects them flexibly. The fin group 149 is disposed in the second main body 142. The fin group 149 extends outwardly from the second main body 142. The second main body 142 has a lower surface 1425. The lower surface 1425 is located between the second chamber 146 and the first main body 141, in front of the first main body 141. The first chamber 145 may be moved to a position in relation to the second chamber 146 by folding the flexible channel 148. In this embodiment, the number of flexible channels 148 is two, but the description is not limited to them. In other embodiments, the number of flexible channels 148 can be adjusted if necessary. The distance from the second chamber 146 to the lighting component 12 is greater than from the first chamber 145 to the lighting component 12, and a working fluid 19 is filled in the first chamber 145. In this embodiment, the working liquid 19 is water, but the description is not limited to it. In other embodiments, the working liquid 19 can be refrigerant, methanol, ethanol, diethyl ether or any other liquid substance that is favorable for heat conduction. Furthermore, in this embodiment, a cross-sectional area A1 of each of the two flexible channels 148 is much smaller than a cross-sectional area A2 of the second chamber 146. In this embodiment, the two flexible channels 148 comprise a plurality of rings 1481 connected to each other in series, respectively. Therefore, the flexible channel 148 is able to bend and prevent the working liquid 19 from escaping from the rings 1481. In other words, the flexible channel 148 is a flexible bellows or a flexible metal channel.

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Next, a function of the lighting component 12 for adjusting the lighting angle is described. In this embodiment and in some other embodiments, the lighting component 12 has a light emitting surface 125. For example, in FIG. 2, normally, an angle 01 between a normal vector N1 of the light emitting surface 125 and an absolutely vertical direction V is 45 degrees. A user can manually move the first main body 141 to bend the flexible channel 148, thereby changing a relative position of the first chamber 145 and the second chamber 146 in order to adjust the corresponding position of the light emitting surface 125. FIG . 3 is a sectional view of the light module in FIG. 1 when the first main body is located in a second position. FIG. 4 is a sectional view of the light module in FIG. 1 when the first main body is located in a third position. For example, in FIG. 3, a normal vector N2 of the light emitting surface 125 is parallel to the absolutely vertical direction V, but the description is not limited thereto. For example, in FIG. 4, an angle 02 between the normal vector N2 of the light emitting surface 125 and the absolutely vertical direction V is 90 degrees, but the description is not limited thereto. That is, the angle between the normal vector N2 of the light emitting surface 125 and the absolutely vertical direction V can be optionally adjusted to a range of 0 to 90 degrees. Therefore, the light module 10 can illuminate directly downwards and does not influence the thermal dissipation. The absolutely vertical direction V thereof is the same as the direction of gravity. The lighting component 12 can be highly efficient so that the light module 10 can be applied to a focal point.

The heat dissipation process of the heat dissipation component 14 that dissipates the heat generated by the illumination component 12 will be illustrated below. As can be seen in FIG. 2, when the lighting component 12 generates heat, it is transferred to the first chamber 145 in the first main body 141. After the working liquid 19 in the first chamber 145 absorbs the heat generated by the lighting component 12, this vaporizes, from the liquid state, to the working gas 19 '. The working gas 19 'rises and flows to the second chamber 146 of the second main body 142 along a first direction D1 (as shown in FIG. 2). In this embodiment, since the fin group 149 is arranged in the second main body 142, the heat of the working gas 19 'can be dissipated through the fin group 149. However, the description is not limited to the same. In other embodiments, the heat of the working gas 19 'can be dissipated directly to the outside environment by means of the second main body 142. Since the heat dissipates after the working gas 19' enters the second chamber 146 , the working gas 19 'gradually condenses into the working liquid 19. Subsequently, the working liquid 19 flows again to the first chamber through the other flexible channel 148 along a second direction D2. Furthermore, in other embodiments, since the cross-sectional area A1 of the flexible channel 148 is much smaller than the cross-sectional area A2 of the second chamber 146, there is a large pressure difference between them. Therefore, the working liquid 19 'flows to the second chamber 146' as a high velocity air flow R1 along the first direction D1, which accelerates the heat conduction and convection.

In the light module 10 of the first embodiment, the working liquid 19 is vaporized in the working gas 19 'to accelerate the heat conduction, and the working gas 19' flows into the second chamber 146 through one of two flexible channels 148 for heat dissipation. After the working gas 19 'condenses in the working liquid 19, it flows back to the first chamber 145 through the other flexible channel 148. In this way, a closed loop loop is created and can be contributed to a Better cooling effect due to convection. On the other hand, in this way, it is not necessary for an active heat dissipation component to be arranged in the light module 10. By arrangement of the two flexible channels 148, the light module 10 can carry out the dissipation of remote heat. That is, the part of the structure for heat conduction is separated from the part of the structure for heat dissipation. Therefore, the allocation of interior space of the entire structure is more flexible. In addition, in this embodiment, the working liquid 19 'flows to the second chamber 146' as a high speed air flow R1 along the first direction D1, which accelerates the heat conduction and convection.

To summarize, the closed loop loop is formed by the arrangement of the two flexible channels, and the convection of the working liquid, while the working gas accelerates the heat conduction. This design of the structure can omit the active heat dissipation component and can significantly improve the heat dissipation effect.

In addition, the first camera connected to the lighting component can be moved to change the relative position of the lighting component and the second camera through the flexion of the two flexible channels. Therefore, users can manually change the region that is illuminated to improve the viability of the light module.

Claims (7)

5 10 fifteen twenty 25 30 35 40 Four. Five Claims 1. A light module (10), capable of adjusting the lighting angle and using the thermal phase change dissipation, comprising: a lighting component (12); and a heat dissipation component (14), with a side that is in thermal contact with the lighting component, in which the heat dissipation component (14) comprises a first chamber (145), and a second chamber ( 146), in which the distance from the second camera (146) to the lighting component (12) is greater than that of the first camera (145) to the lighting component (12) and a working liquid (19) that is filled in the first chamber (145); in which the lighting module is characterized because The heat dissipation component (14) further comprises two flexible channels that flexibly connect the first chamber (145) and the second chamber (146); each of the two flexible channels (148) comprises a plurality of rings (1481) that are connected between sf in series, respectively; in which the lighting component (12) has a light emitting surface (125), and the two flexible channels (148) can be bent to adjust an angle between a normal vector of the light emitting surface (125) and a direction absolutely vertical in a range of 0 to 90 degrees; wherein, when the working liquid (19) absorbs heat generated from the lighting component (12), the working liquid (19) vaporizes from a liquid state to a gaseous state and flows into the second chamber (146) at through one of the flexible channels (148) for heat dissipation, and after the working liquid (19) in the second chamber (146) condenses from the gaseous state to the liquid state, it flows back to the first chamber (145) through the other flexible channel (148). 2. The light module (10) according to claim 1, wherein a cross-sectional area of each of the two flexible channels (148) is smaller than that of the second chamber (146), so that the The working liquid (19) flows to the second chamber (146) at high speed through one of the two channels (148). 3. The light module (10) according to claim 1, wherein the heat dissipation component (14) further comprises a first main body (141), a second main body (142) and a group of fins (149), in which one side of the first main body (141) is in thermal contact with the lighting component (12), in which the first chamber (145) is located in the first main body (141), the second chamber (146) is located in the second main body (142), and the fin group (149) is arranged in the second main body (142). 4. The light module (10) according to claim 3, wherein the group of fins (149) extends outwardly from the second main body (142). 5. The light module (10) according to claim 1, wherein the working liquid (19) is water, methanol, ethanol or diethyl ether. 6. The light module (10) according to claim 1, wherein the lighting component (12) is a solid state lighting component. 7. The light module (10) according to claim 1, wherein the lighting component (12) is a light emitting diode.