FR3090819A1 - LIGHT DEVICE WITH DEHUMIDIFYING DEVICE - Google Patents

Abstract

LIGHT DEVICE WITH DEHUMIDIFICATION DEVICE The invention provides a dehumidification device (100) of a light device (102) of a motor vehicle. The dehumidification device (100) comprising a dehumidification unit (104) having a maximum capacity for absorbing moisture. The dehumidification unit (104) is adapted to selectively take a first state, in which the unit absorbs moisture, or a second state, in which the unit diffuses humidity. Furthermore, the dehumidification device (104) comprises a control unit (112) of the dehumidification unit, the latter being provided with a timer (114). The control unit is configured to control the dehumidification unit to switch to the second diffusing state after a maximum predetermined duration of the dehumidification unit in the first absorbing state. The flow of said maximum predetermined duration is indicated by the timer. Figure for the abstract: Figure 1

Description

Description

Title of the invention: LIGHT DEVICE WITH DEHUMIDIFICATION DEVICE

The invention relates to the elimination of moisture inside a light device, in particular for a motor vehicle. The invention relates to a dehumidification device with a control unit for a light device.

The humidity of the environment of a motor vehicle tends to enter its light devices. The latter generally have housings containing light sources and various electronic equipment essential for the safe use of said vehicle. Moisture entering a housing can condense on the glass of the light device so that the orientation of the light rays no longer respects the predefined pattern. As a result, the driver no longer has the lighting necessary for his safety while driving.

In addition, the humidity present in a housing can favor corrosion phenomena. These phenomena can damage certain internal electrical components, and therefore shorten the life of the light device concerned.

[0004] Thus, it is necessary to equip a light device with a dehumidification device. Document US2016363331 A1 discloses a dehumidification pump. This system aims to reduce the humidity in an enclosure of a light device for a motor vehicle. The pump has a cylindrical body with a desiccant, and opens selectively to the outside or inside of the lamp enclosure. In addition, an electrical component makes it possible to dry the desiccant in order to restore its absorption capacity. However, such a system consumes significant energy. This consumption shortens the range of the associated vehicle, and tends to increase carbon dioxide emissions in the case of a fossil fuel vehicle.

The invention aims to overcome at least one of the problems posed by the prior art. More specifically, the invention aims to reduce the electrical consumption of a dehumidification device for an enclosure.

According to a first aspect of the invention, a device for dehumidifying a light device of a motor vehicle is proposed. The dehumidification device comprises a dehumidification unit characterized by a maximum moisture absorption capacity. The unit is capable of selectively taking a first state, in which the unit absorbs moisture, or a second state, in which the unit diffuses humidity. The dehumidification device is remarkable in that it comprises a control unit for the dehumidification unit, the control unit being provided with a timer, and being configured to control the dehumidification unit to be switched to the first absorbent state after a maximum predetermined duration of the dehumidification unit in the second diffusing state, the flow of said maximum predetermined duration being indicated by the timer.

Advantageously, the dehumidification unit is arranged so that the first absorbent state is a passive state. In other words, the dehumidification unit is able to assume the first absorbent state in the absence of power supply.

Advantageously, the dehumidification unit is arranged so that the second diffusing state is an active state. In other words, the dehumidification unit is able to assume the second diffusing state when it is electrically supplied.

For example, the dehumidification unit may include a desiccant associated with a heating element configured to heat the desiccant when it is electrically powered. In the first state, the power to the heating element can be turned off to promote the absorption of moisture from the light device. In the second state, the heating element can be supplied in order to dry the desiccator, in order to favor the diffusion of humidity outside the light device. The second state also makes it possible to restore the desiccant's absorption potential, totally or partially. If necessary, the dehumidification unit may comprise flaps which open in turn towards the inside or towards the outside of the light device, depending on the state of the dehumidification unit, namely the state absorbing or respectively diffusing state.

Preferably, the maximum predetermined duration can be between 10 and 60 minutes or between 20 and 40 minutes.

The maximum predetermined duration can preferably be substantially equal to 30 minutes.

The control unit may preferably include a memory element for storing therein a command history of the control unit.

Preferably, the control unit is configured to store each command in the memory element. Preferably, the control unit can include a microcontroller element programmed to perform the functions of the control unit.

The command history may preferably include a time indication of the last command to switch from the diffusing state to the absorbing state.

Preferably, the control unit can be configured to control the dehumidification unit to switch to the second diffusing state after expiration of a predetermined duration, in particular between 3 and 7 hours, counted from said time indication of the last command to switch from the diffusing state to the absorbing state.

The control unit can preferably be configured to estimate the moisture absorption capacity of the dehumidification unit at a given time based on the data from said history, and to control the dehumidification unit based on said estimate.

Preferably, the device can comprise a unit for receiving data relating to the state of components internal and / or external to the dehumidification device, and the control unit can preferably be configured to control the unit. dehumidification based on at least some of this data.

Said data received by the reception unit may preferably include an indication of the level of charge of a battery of the motor vehicle and / or an indication of switching on of the ignition.

Preferably, the control unit can be configured to control the dehumidification unit to switch to the second diffusing state if said data indicate a battery charge greater than a threshold value and switching on of the motor vehicle.

The threshold value can preferably correspond to 80% or 90% of the maximum charge of said battery.

The data received by the receiving unit may preferably include an indication of the moisture absorption capacity of the dehumidification unit.

Preferably, the control unit can be configured to control the dehumidification unit to switch to the first absorbent state if said data indicates a moisture absorption capacity greater than a threshold capacity.

The threshold capacity may preferably correspond to a percentage, in particular 50%, of the maximum moisture absorption capacity of the dehumidification unit.

Preferably, the dehumidification unit can comprise a humidity sensor operatively connected to the memory element, to generate said indication of the moisture absorption capacity.

According to another aspect of the invention, a light device for a motor vehicle comprising a dehumidification device is proposed. The device is remarkable in that the dehumidification device conforms to one aspect of the invention.

Using the measures proposed by the present invention, it becomes possible to propose a low energy dehumidification system. To do this, the invention takes into account certain relevant durations.

The invention reduces the time during which the dehumidification unit consumes energy, that is to say the energy coming from the vehicle battery. For example, the energy supplied may correspond to an energy necessary for total regeneration from a saturated state. This supply of energy can be translated into a supply period.

According to certain considerations, the power supply can be optimized as a function of the capacities of the dehumidification unit. These capacities can be estimated in the light of a history, an absorption capacity, a humidity measurement, and a dew point.

Other characteristics and advantages of the present invention will be better understood on the basis of the description of the examples and of the drawings among which:

[Fig.l] shows a dehumidification device according to a first embodiment of the invention;

[Fig.2] shows a dehumidification device according to a second embodiment of the invention;

[Fig.3] shows a dehumidification device according to a third embodiment of the invention;

[Fig.4] shows a dehumidification device according to a fourth embodiment of the invention. :

Unless specifically indicated to the contrary, technical characteristics described in detail for a given embodiment can be combined with the technical characteristics described in the context of other embodiments described by way of examples and without limitation. Similar reference numbers will be used to describe similar concepts across different embodiments of the invention. For example, the references 100, 200, 300 and 400 designate four embodiments of a dehumidification device according to the invention.

The illustration in [fig.l] shows a diagram of the operation of a dehumidification device 100 according to a first embodiment of the invention.

The dehumidification device 100 can be associated with a light device 102 for a motor vehicle. The light device 102 may include a projector and / or a signaling module.

The dehumidification device 100 may include a dehumidification unit 104, for example in communication with the internal enclosure 106 of the light device 102. The dehumidification unit 104 may include a maximum capacity for absorbing moisture. This capacity can be imparted by a desiccant 108. In a known manner, such a material has the chemical property of being able to absorb moisture, then of releasing this moisture into the atmosphere when the desiccant 108 is reheated. Desiccant 108 may include nanoporous material, silica gel, drierite, magnesium chloride, or any other equivalent material.

The dehumidification unit 104 may be able to selectively take a first state, in which said desiccant 108 absorbs moisture from the internal enclosure 106, or a second state, in which the dehumidification unit 104 diffuses moisture out of the light device 102. For this purpose, the dehumidification unit 104 may include an internal cavity receiving the desiccant 108, and flaps (not shown) opening in turn towards the internal enclosure 106 or towards the outside of the light device 102. The internal cavity can be placed between said flaps.

The dehumidification unit 104 may include a heating element 110, for example an electrical resistance. The heating element 110 can be configured to heat the desiccant 108, and therefore to dry it. In the first state, the supply of the heating element 110 can be cut in order to favor the absorption of moisture from the internal enclosure 106, while in the second state the heating element 110 can be supplied in 'dry the desiccant 108 and restore its absorption potential, totally or partially. The dehumidification unit 104, and in particular the heating element 110, can be supplied by storage means, or means for accumulating energy, such as an electric battery 116 of the vehicle.

The power supply to the dehumidification unit 104, and therefore the heating element 110, can be conditioned by the state of the engine S_engine. The engine in question may be the primary engine of the vehicle. It can be an internal combustion engine, powered in particular by fuel. In addition or as a replacement, the motor includes an electric motor.

When said engine is stopped, the power to the dehumidification unit 104, and therefore the heating element 110, is cut. This can be respected regardless of the state of the dehumidification unit 104. When the engine is in an operating state, the heating element 110 can be supplied by the storage means. Optionally, the heating element 110 is supplied by the storage means 116 each time the engine starts. An alternator (not shown) can be coupled to the engine to produce energy recharging the battery 116.

In the example described, when the engine starts, the dehumidification unit 100 is in the second diffusing state. The dehumidification device 100 can comprise a control unit 112, for example with a timer 114. The control unit 112 can be configured to control the switching of the dehumidification unit 104 to the first absorbent state after a maximum predetermined duration of the dehumidification unit 104 in the second diffusing state. The flow of said maximum predetermined duration can be indicated by the timer 114.

Thus, the period during which the dehumidification unit 104 remains in the second state is limited in time, as a result of which the period during which the heating element 110 is supplied with primary energy is shortened. Consequently, energy consumption is under control, and the vehicle thus equipped sees its energy needs decrease.

For example, the maximum predetermined duration is between 10 and 60 minutes or between 20 and 40 minutes. Optionally, the maximum predetermined duration is around 30 minutes. This duration of 30 minutes is an optimal compromise between the restitution of the absorption potential of the desiccant 108, and the energy necessary for this restitution.

The illustration in [fig.2] shows a diagram of the operation of a dehumidification device 200 according to a second embodiment of the invention. The dehumidification device 200 according to the second embodiment can be substantially similar or identical to the first embodiment. The second embodiment uses the numbering of the first embodiment for similar or identical elements, the numbering being however incremented by 100. Numbers specific to this embodiment are added.

The second embodiment may differ from the first embodiment in that the electrical supply to the dehumidification unit 204, and therefore the heating element 210, can be conditioned by switching on the vehicle for which one can define a corresponding S_key indication. The ignition can be caused by a user activating the vehicle using an ignition key. Thus, the user can exit the vehicle from a stopped state and / or from a standby state. Thus, the dehumidification unit 204, and therefore the heating element 210, can be supplied before the vehicle engine starts. Therefore the action of the dehumidification unit 204 can start earlier, which potentially improves vehicle safety.

In the absence of ignition, S_key, in particular in standby, the supply of the dehumidification unit 204, and therefore the heating element 210, is cut; whatever the state of the dehumidification unit 204. In the event of ignition, the corresponding indication S_key is positive and the heating element 210 can be supplied by the storage means, respectively by the battery 216.

The control unit 212 can communicate with a memory element 218. The memory element 218 can be adapted in order to record there a command history of the control unit 212. The command history can include a time indication of the last command to switch from the diffusing state to the absorbing state, that is to say a time indication of the most recent change between the first state and second state. For example, the time indication is a duration.

The control unit 212 can be configured to control the dehumidification unit 204 in order to switch to the second diffusing state after the expiration of a predetermined duration. The predetermined duration can be between 3 and 7 hours, counted from said time indication of the last command to switch from the diffusing state to the absorbing state. Thus, the time during which the dehumidification unit 204 remains in the first state is limited in time, and remains less than the predetermined duration. This characteristic also makes it possible to define a minimum time during which the dehumidification unit 204 remains in the first state, which guarantees a certain level of moisture absorption. The predetermined duration can be measured by the timer 214 by including the time during which the vehicle remains on standby, that is to say unused by the driver.

The control unit 212 can be configured to estimate the moisture absorption capacity of the dehumidification unit 204 at a given time based on the data from said history, and to control the unit dehumidification 204 according to said estimate. For example, if the dehumidification unit 204 has not undergone total regeneration during the last 6 hours, the control unit 212 may consider that the dehumidification unit 204 does not have sufficient absorption capacity . Therefore, a change from the first state to the second state becomes necessary.

Similarly, if the history shows that a change from the first state to the second state has taken place in the last 6 hours, the control unit 212 may consider that the absorption capacity is sufficient, and that a switch from the second state to the first state is possible. By these control laws, energy consumption can be rationalized while promoting an adequate absorption capacity. Other parameters, in particular the temperature and humidity of the environment, can be taken into account in order to optimize the operation of the dehumidification device 200.

The switching from the second state to the first state can be conditioned by an indication relating to the storage means, respectively to the battery 216. For example, said indication can be an indication of the level of charge U_in of the battery 216 relative to at nominal load level. The charge level U_in can correspond to at least 90% of the maximum level. Therefore, the heating element 210 can be supplied with primary energy, in particular for a maximum duration. Said maximum duration may be equal to 30 minutes.

The dehumidification device 200 can include a unit 220 for receiving data relating to the state of components internal and / or external to the dehumidification device 200. The control unit 212 can be configured so as to control the dehumidification unit 204 as a function of at least part of the data received by the reception unit 220.

The data received by the reception unit 220 can include the indication of the charge level U_in of the battery 216 of the motor vehicle. In addition or as an alternative, the data received by the reception unit 220 may include the indication of contact ignition S_key. The control unit 212 can be adapted so that the dehumidification unit 204 switches to the second diffusing state if said data received by the reception unit 220 indicates a battery charge greater than a threshold value and a setting contact with the motor vehicle. The threshold value can correspond to: 80%, or 90%, of the maximum charge of said battery.

The second embodiment is based on the history of the dehumidification unit 204, and considers the durations in the first and in the second state. By knowing the regeneration and saturation times of the dehumidification unit 204, the history makes it possible to estimate the dehumidifying effect that the dehumidification unit 204 can bring at a given time. This knowledge then allows feeding wisely.

The illustration in [fig.3] shows a diagram of the operation of a dehumidification device 300 according to a third embodiment of the invention. The dehumidification device 300 according to the third embodiment can be substantially similar or identical to the second embodiment. The third embodiment uses the same numbering as for the second embodiment for similar or identical elements, the numbering however being incremented by 100. Numbers specific to this embodiment are added.

The third embodiment may differ from the second embodiment in that the supply of the dehumidification unit 304, in particular therefore the heating element 310, depends on a characteristic of the dehumidification unit 304.

The dehumidification device 300 can comprise a unit 320 for receiving data relating to the state of components internal and / or external to the dehumidification device 300. Furthermore, the control unit 312 can be configured in order to control the dehumidification unit 304 as a function of at least part of the data received.

The data received by the reception unit 320; data according to which the control unit 312 controls the dehumidification unit 304; may include an indication of the moisture absorption capacity CAH of the dehumidification unit 304. Said indication of the moisture absorption capacity CAH may be equal to 0% when the dehumidification unit 304 is fully regenerated , that is, it released all the moisture it contained. The indication of the moisture absorption capacity CAH can be equal to 100% when the dehumidification unit 304 is saturated with water, which corresponds to the maximum storage that the dehumidification unit 304 can achieve.

The control unit 312 can be configured to control the dehumidification unit 304 so as to switch to the first absorbent state if said data indicate a moisture absorption capacity CAH below a threshold capacity. The threshold capacity may correspond to a percentage, in particular 50%, of the maximum moisture absorption capacity of the dehumidification unit 304.

The indication of the moisture absorption capacity CAH can be calculated using at least one model. The model in question can be based on the history of switching between the first state and the second state, this history being recorded in particular on memory element 318.

Advantageously, the dehumidification unit 304, and therefore the heating element 310, are supplied until the absorption capacity of the dehumidification unit 304 becomes maximum; that is, to the point of total regeneration. For this function, the dehumidification unit 304 is in the first state.

This regeneration can depend on the storage means, and in particular on the charge of the battery 316.

The data received by the reception unit 320 can include an indication of the charge level U_in of the battery 316 of the motor vehicle. The control unit 312 can be configured to control the dehumidification unit 304 to switch to the second diffusing state if said data indicate a battery charge U_in greater than a threshold value and a switching on of the motor vehicle. This threshold value can correspond to: 80%, or 90%, of the maximum charge of said battery.

The third embodiment follows an approach based on the capacity of the dehumidification unit 304. When the capacity of the latter falls below a threshold value, the supply is triggered. Thus, the third embodiment focuses on the likely action that the dehumidification unit 304 can produce.

The illustration in [fig.4] shows a diagram of the operation of a dehumidification device 400 according to a fourth embodiment of the invention. The dehumidification device 400 according to the fourth embodiment can be substantially similar or identical to the third embodiment. The fourth embodiment uses the same numbering as for the third embodiment for similar or identical elements, the numbering being however incremented by 100. Numbers specific to this embodiment are added.

The fourth embodiment can essentially differ from the third embodiment in that the dehumidification unit 404 can comprise a humidity sensor 422 operatively connected to the memory element 418. This can make it possible to generate the indication of the moisture absorption capacity CAH specific to the dehumidification unit 404. The humidity sensor 422 can be placed inside the internal enclosure 406 of the light device 402 so as to measure the degree thereof internal humidity.

The fourth embodiment can estimate a risk of condensation inside the light device 402. For example, the risk of condensation can be classified as critical when the dew point is greater than 5 ° C, and that in addition, the indication of the moisture absorption capacity CAH is less than 50%. In particular, the dew point can be estimated using the humidity sensor 422.

In the event of a critical risk, the dehumidification unit 404, and therefore the heating element 410, can be supplied by the storage means, respectively the battery 416. The dehumidification unit 404 can then switch from the first state in the second state.

Power can be supplied provided that the battery is charged to at least: 80%, or 90%. The supply can be maintained until the critical risk becomes an acceptable risk, for example when the dew point is below 5 ° C. In the present embodiment, the dew point can be calculated on the basis of models derived from data specific to the corresponding vehicle.

The precision is then improved by taking into account the humidity in the light device 402. Thus, the fourth embodiment limits the energy-consuming phase to that during which the risk of dew is highest. More specifically, power is provided when the capacity of the dehumidification unit does not allow the effects of an essentially high rose point to be corrected.

The different embodiments can be combined with each other. For example, the invention considers the combination of the first, the second, the third and the fourth embodiment.

The scope of protection is determined by the claims.

Claims (1)

Claims [Claim 1] Dehumidification device (100; 200; 300; 400) of a light device (102; 402) of a motor vehicle, the dehumidification device (100; 200; 300; 400) comprising a dehumidification unit (104; 204 ; 304; 404) characterized by a maximum moisture absorption capacity, the unit being able to selectively assume a first state, in which the unit (104; 204; 304; 404) absorbs moisture , or a second state, in which the unit (104; 204; 304; 404) diffuses humidity, characterized in that the device (100; 200; 300; 400) comprises a control unit (112; 212 ; 312; 412) of the dehumidification unit (104; 204; 304; 404), the control unit (112; 212; 312; 412) being provided with a timer (114; 214), and being configured for controlling the dehumidification unit (104; 204; 304; 404) to switch to the first absorbent state after a maximum predetermined duration of the dehumidification unit (104; 204 ; 304; 404) in the second diffusing state, the flow of said maximum predetermined duration being indicated by the timer (114; 214). [Claim 2] Device (100; 200; 300; 400) according to claim 1, characterized in that the maximum predetermined duration is between 10 and 60 minutes or between 20 and 40 minutes. [Claim 3] Device (100; 200; 300; 400) according to claim 2, characterized in that the maximum predetermined duration is substantially equal to 30 minutes. [Claim 4] Device (200; 300; 400) according to one of claims 1 to 3, characterized in that the control unit (212; 312; 412) comprises a memory element (218; 318; 418) for storing a history of the control unit controls (212; 312; 412). [Claim 5] Device (100; 200; 300; 400) according to claim 4, characterized in that the command history includes a time indication of the last command to switch from the diffusing state to the absorbing state. [Claim 6] Device (200) according to claim 5, characterized in that the control unit (212; 312; 412) is configured to control the dehumidification unit (204) to switch to the second diffusing state after a period of time has elapsed predetermined, in particular between 3 and 7 hours, counted from said time indication of the last command to switch from the diffusing state to the absorbing state. [Claim 7] Device (200; 300; 400) according to one of Claims 4 to 6, characterized in that the control unit (212; 312; 412) is configured to estimate the moisture absorption capacity of the dehumidification unit (204; 304; 404) at a given time based on the data from said history, and to control the dehumidification unit (204; 304; 404) according to said estimate. [Claim 8] Device (200; 300; 400) according to one of claims 1 to 7, characterized in that the device comprises a receiving unit (220; 320; 420) of data relating to the state of components internal and / or external to the device dehumidification, and in that the control unit (212; 312; 412) is configured to control the dehumidification unit (204; 304; 404) according to at least some of this data. [Claim 9] Device (200; 300; 400) according to claim 8, characterized in that the said data received by the reception unit (220; 320; 420) include an indication of the level of charge of a battery (216; 316; 416) of the motor vehicle and / or an indication of ignition S_key. [Claim 10] Device (200; 300; 400) according to claim 9, characterized in that the control unit (212; 312; 412) is configured to control the dehumidification unit (204; 304; 404) to be switched to the second diffusing state if the said data indicate a battery charge greater than a threshold value and ignition of the motor vehicle. [Claim 11] Device (200; 300; 400) according to claim 10, characterized in that the threshold value corresponds to 80% or 90% of the maximum charge of said battery (216; 316; 416). [Claim 12] Device (100; 200; 300; 400) according to one of Claims 8 to 11, characterized in that the data received by the reception unit (220; 320; 420) includes an indication of the moisture absorption capacity CAH of the dehumidification unit (104; 204; 304; 404). [Claim 13] Device (200; 300; 400) according to claim 12, characterized in that the control unit (212; 312; 412) is configured to control the dehumidification unit (204; 304; 404) to be switched to the first absorbent state if said data indicates a capacity for absorbing humidity CAH greater than a threshold capacity. [Claim 14] Device (100; 200; 300; 400) according to claim 13, characterized in that the threshold capacity corresponds to a percentage, in particular 50%, of the maximum moisture absorption capacity of the dehumidification unit (204; 304; 404). [Claim 15] Device (400) according to one of claims 12 to 14, characterized in that the dehumidification unit (404) comprises a humidity sensor (422) operatively connected to the memory element (418), for generating said indication of the moisture absorption capacity CAH. [Claim 16] Light device for a motor vehicle comprising a dehumidification device, characterized in that the dehumidification device conforms to one of claims 1 to 15.