FR3016022A1 - FRONTAL LAMP WITH IMPROVED MANAGEMENT OF HEAT FLOWS - Google Patents

Abstract

The headlamp has a light emitter (1) and a battery pack (2) for receiving a power source. The battery pack (2) is electrically coupled to the light emitter (1). A power circuit (4) is arranged between the light emitter (1) and the battery pack (2) and is intended to supply the light emitter (1). A management circuit (5) receives at least one user input and controls the power circuit (4). The lamp further comprises a heat radiator (7) configured to transfer heat between the light emitter (1) and the battery pack (2) by thermal conduction. The heat radiator (7) has at least one metal track for supplying the battery pack (2) for powering the power circuit (4).

Description

FIELD OF THE INVENTION The invention relates to a headlamp. STATE OF THE ART In many activities, when natural light is no longer sufficient, it is very important to be able to use one's hands while being able to illuminate objects or a path. A simple way to solve this problem is to use a headlamp that the user is wearing on his head. Thus, the lamp always illuminates where the eyes of the user are worn. The headlamp comprises, in a conventional manner, a light emitter which is powered by a power source. The lamp also includes a controller that allows the user to manage the lamp on and off and various modes of operation. Under certain conditions, it is important to emit an intense luminous flux which results in a strong emission of light from the light emitter. Expectedly, the use of a high light intensity results in an accelerated depletion of the energy source. However, it has also been observed that the prolonged use of the high intensity lamp also results in an increase in the lamp failure rate.

OBJECT OF THE INVENTION It is noted that there is a need to provide a headlamp to better withstand prolonged use at high brightness. This need is filled by means of a headlamp comprising: a light emitter, a battery pack for receiving a power source, the battery pack being electrically coupled to the light emitter, a power circuit disposed between the light emitter and the battery pack and for supplying the light emitter, A management circuit receiving at least one user input and controlling the power circuit, a heat sink configured to transfer heat between the light emitter and the battery pack by thermal conduction, the thermal radiator comprising at least one metal track for supplying the battery pack for supplying the power circuit.

BRIEF DESCRIPTION OF THE DRAWINGS Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention given by way of non-limiting example and represented in the accompanying drawings, in which: FIG. schematically, a headlamp in sectional view; - Figure 2 schematically shows a headlamp.

DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION The headlamp illustrated in FIG. 1 comprises a light emitter 1 electrically connected to a battery block 2. The light emitter 1 is formed by any means suitable for transmitting light. a luminous radiation. The light radiation can be configured to emit white and / or red light. It is also conceivable to provide lighting in another color. The light emitter 1 can be made by a light-emitting diode. However, other light sources are conceivable.

The battery pack 2 is configured to allow the introduction of one or more removable or fixed energy sources 3. The battery pack 2 represents a volume for feeding the headlamp. Depending on the configuration, the battery can be fixed or removable. The battery pack 2 can therefore be a housing for one or more batteries or the housing of the battery. In the example illustrated in Figure 1, the power source 3 is a battery, for example an alkaline battery and the battery pack 2 is shaped to place the battery or batteries in predefined positions. The headlamp also comprises a power circuit 4 which is electrically arranged between the battery pack 2 and the light emitter 1. The electrical energy from the battery pack 2 passes through the power circuit 4 before supplying the power supply. light emitter 1. The power circuit 4 is controlled by means of a management circuit 5.

The management circuit 5 receives one or more instructions from the user and controls the power circuit 4 accordingly. The instructions of the user are represented by an arrow in FIG. 1. The instructions may come for example from a press button which is actuated by the user.

By way of example, the management circuit 5 is configured to control the coupling and the electrical decoupling between the battery pack 2 and the light emitter 1. The management circuit 5 can also be configured to control a mode switch between continuous lighting and intermittent lighting. It is also possible to adjust the intensity of the luminous flux emitted. In this configuration, a large current is provided for circulating in the power circuit 4 in order to power the light source 1. On the other hand, a weak current flows in the management circuit 5. In this way, it is possible to specialize the two circuits using different technological bricks which allows the use of transistors allowing the transit of high power in the power circuit 4 and energy-saving transistors in the management circuit 5.

The management circuit 5 is advantageously formed by transistors having dimensions smaller than the power transistors. These small transistors are more sensitive to changes in temperature and they can age prematurely.

It is therefore particularly advantageous to physically dissociate the power circuit 4 and the management circuit 5 in order to keep the management circuit 5 as far away as possible from the various heat sources present inside the lamp.

As a large current can flow between the power circuit 4 and the light emitter 1, it is advantageous to place these two elements as close as possible to one another. In this way, the current travels a reduced distance which limits the losses including resistive losses. In a particularly advantageous embodiment, the power circuit 4 is made on the same substrate as the light emitters 1. As an example, these two elements are integrated on the same PCB printed circuit. The light emitter 1 represents the first source of heat inside the headlamp in calories produced. In order to protect the light emitter 1 from external aggressions, the latter is placed in a housing which defines a lighting module 6. This housing is advantageously rigid and makes it possible to prevent the light emitter 1 from receiving shocks. , but it also prevents good heat dissipation including good convection around the light emitter 1.

To limit the rise in temperature of the light emitter 1 during its operation, it is advantageous to couple the light emitter 1 to a heat sink 7 whose function is to increase the heat dissipation surface. In this way, the heat emitted by the transmitter 1 can escape more easily. The heat generated by the light emitter 1 is captured in part by its support, here the printed circuit PCB which dissipates the heat. Then, the heat recovered by the PCB is transmitted to the heat sink 7 which continues the dissipation and which transfers this heat to a less critical area.

In the lamps of the prior art, the heat radiator is disposed inside the lighting module which limits the rate of rise in temperature of the light emitter. However, in this configuration the heat generated is blocked inside the lighting module. The heat stored in the light module dissipates via the module walls. In a particular configuration of the prior art, a hole is made between the lighting module and the power module which allows a slight heat transfer by convection. Advantageously, the heat radiator 7 comprises a wall of polymer material 7a. The light emitter 1, the management circuit 5 and power 4 are preferably fixed to this wall to ensure good mechanical maintenance of the various elements of the lighting module. In order to prevent the evacuated heat from being blocked in the lighting module 6, the heat radiator 7 is configured to transfer the heat produced by conduction out of the lighting module 6. This particular configuration makes it possible to prevent the temperature in the lighting module 6 is too important. This configuration also gives good results when the heat sink 7 extends inside the power supply module 8 which contains the battery pack 2 and in particular in the compact lamps where a protective shell defines the case and more particularly when the housing is divided into at least two distinct modules: the lighting module 6 and the power supply module 8. In the example illustrated, the polymer wall 7a of the heat sink delimits the lighting module 7 and the light module. 8. Advantageously, the leaktight wall separating the lighting module 6 and the supply module is overmolded on the heat radiator 7. Unexpectedly, it has been discovered that the realization of a thermal connection by conduction between the light emitter 1 and the battery pack 2 allows a good evacuation of the heat released by the light emitter 1. Although the battery pack 2 is not the having intrinsically the lowest temperature, this part of the headlamp has a large mass, a good heat capacity and a low thermal resistance. In this configuration, the heat radiator 7 allows a rapid transfer of the heat released by the light emitter 1 towards the battery pack 2.

The heat conduction of the heat produced by the light emitter 1 in the battery pack 2 makes it possible to store a large quantity of heat. This configuration is particularly advantageous in compact lamps where the convection is bad. This configuration has further shown that the heating of the battery allows a gain in the power output at room temperature or lower temperature. In a particularly effective configuration, the thermal conduction is carried out by means of one or more metal tracks 7b and 7c which are electrically connected to the energy source 3. Moreover, the metal tracks 7b and 7c are arranged between the source of heat and battery pack 2 to facilitate heat transfer. This architecture makes it possible to increase the thermal conduction between the light emitter 1 and the battery pack 2 while using the electric tracks usually used to transmit the supply current. In the embodiment illustrated in Figure 2, the battery pack 2 is configured to receive three batteries connected in series. The metal tracks 7b and 7c are completed by two other tracks 7d and 7d. In the illustrated embodiment, tracks 7b and 7c cover most of the wall. However, it is also possible to provide similar covers between the different tracks. The elements 7 'schematically represent the contact pads with the batteries.

When the partition wall is overmolded on the thermal radiator, it is advantageous to provide a first series of studs which exit from the side of the lighting module and which are welded so as to supply the control circuit and the lamp. It is also advantageous to provide a second series of pads that leave the side of the power supply module to connect if possible directly the battery.

While the electric tracks of the prior art are located on small surfaces on the edges of the battery pack 2 to only carry current, they have a much larger surface here. This larger surface does not intervene in the transport of the current. The surplus of material allows a better thermal conduction. The overweight is of the order of a few grams, for example 1 or 2 grams, which also allows to integrate this feature in addition without penalizing the user. In a particular embodiment, the metal elements thermally connecting the light source 1 with the battery pack 2 do not realize the thermal connection with the management circuit 5. A thermal barrier is formed for example by means of a volume of gas and / or by means of a plastic film which has a greater thermal resistivity. This feature makes it possible to limit the rise in temperature of the management circuit 5. The thermal barrier will prevent the heat from arriving or it will diffuse the heat to limit the temperature increase of the circuit 5. In another embodiment which can be combined with the previous embodiments, the battery pack 2 is formed by a metal frame on which is molded a layer of polymeric material. The metal frame makes it possible to increase the thermal mass of the battery pack 2. This configuration makes it possible to force the transfer of heat from the light emitter 1 to the battery pack 2 by the metal tracks and to have in addition a diffusing plate heat that reduces the appearance of parasitic hot spots. The polymeric material commonly used in headlamps is enhanced by metal tracks that facilitate heat transfer. There is always an increase in the general temperature of the lamp during its operation, but the electronic circuits sensitive to a rise in temperature have their operating temperature decreased in comparison with a lamp according to the prior art. As a corollary, for a fixed increase in the temperature of the electronic components, it is possible to pass more current in the light emitter 1 and thus to have a greater luminous flux. It is then possible to provide a lighting module 6 hermetic and / or sealed to better protect the light emitter 1 without affecting a good heat transfer. It is also possible to provide that the supply module 8 can be sealed and / or sealed. The separation between these two modules can be achieved by a wall containing metal tracks of the radiator. As the management of heat flows is better controlled, there is less risk of failure in electrical devices sensitive to temperature increases.

Claims (4)

REVENDICATIONS1. Headlamp comprising: a light emitter (1), a battery pack (2) for receiving a power source, the battery pack (2) being electrically coupled to the light emitter (1), a power circuit (4) arranged between the light emitter (1) and the battery pack (2) and intended to supply the light emitter (1), a management circuit (5) receiving at least one user input and controlling the circuit power (4). a heat radiator (7) configured to transfer heat between the light emitter (1) and the battery pack (2) by thermal conduction, the heat sink (7) having at least one metal track for supplying the battery pack (2) for power supply of the power circuit (4). 2. Lamp according to claim 1, wherein the thermal radiator (7) is formed by a plurality of metal tracks (7b, 7c) for supplying the battery pack (2) for powering the power circuit (4), the tracks metallic (7b, 7c) at least partially covering the bottom of the battery pack (2). 3. Lamp according to one of claims 1 and 2, wherein the light emitter (1) is formed on an integrated circuit mounted on a first side of a wall of polymer material and the bottom of the battery pack (2). is defined by the second opposite face of the wall of polymer material. 4. Lamp according to claim 3, wherein the heat sink (7) comprises a metal plate partially coated with a thermoplastic material.