WO2014095203A1 - Optimisation of heat regulation in a device comprising a fan - Google Patents

Abstract

The invention concerns a device (1) comprising: at least one component (7), at least one fan (4) for regulating the temperature of the component (7), a processor (5), and at least one temperature sensor (3), characterised in that the processor (5) is configured to control the direction of rotation of the fan (4) on the basis of the temperature of the component (7) measured by the temperature sensor (3), so as to regulate the temperature of the component (7) and the noise generated by the fan (4). The invention also concerns a method for regulating the temperature in this device.

Description

 Optimization of thermal regulation in a device comprising a fan

GENERAL TECHNICAL FIELD

 The invention relates to a device whose temperature regulation is provided by a mechanical ventilation system.

STATE OF THE ART

 The electronic devices conventionally comprise at least one fan for their temperature regulation.

 Effective temperature control is essential to maintain the performance of the device.

 Indeed, a heating of the components of the device usually leads to a degradation of the performance of the device.

 This is for example the case in electronic devices comprising a light emitting system, for displaying or projecting an image. In particular, the quality of the image displayed or projected by the light emitting system, and in particular its sharpness, depends on the good temperature regulation of the light emitting system. Too high a temperature of the components of the light emission system degrades the quality of the image produced.

 In the prior art, the temperature control of at least one component of the electronic device is managed by a processor that controls the speed of rotation of the fan as a function of the temperature of the component.

 This rotation speed has in particular one to three levels depending on the temperature of the component.

 However, with such a regulation, this type of device is very noisy. In particular, the noise generated by the device increases with heating of the device.

When the device is in high demand (for example when it displays or projects images of a higher quality), or when the device is placed in a high temperature environment, the noise generated by the device is maximum, which discourages and disturbs users.

 Some devices reduce noise by reducing the rotational speed of the fan, but this is to the detriment of device performance.

 In addition, in the case of portable devices, supposed to be mobile and usable in all circumstances (meetings, travel), the user can operate the device optimally and comfortably. PRESENTATION OF THE INVENTION

 To overcome these drawbacks, the invention proposes a device comprising at least one component, at least one fan for temperature regulation of the component, a processor, and at least one temperature sensor, characterized in that the processor is configured to control the direction of rotation of the fan as a function of the component temperature measured by the temperature sensor, so as to regulate the temperature of the component and the noise generated by the fan.

 This makes it possible to regulate the temperature of the component by minimizing the noise generated by the fan

 The invention is advantageously completed by the following features, taken alone or in any of their technically possible combination:

 - The device further comprises at least one external opening whose size is adjustable, for the passage of an air flow, the processor being configured to control the direction of rotation of the fan and the size of the external opening according to the temperature of the component;

 the processor is configured to increase the size of the external aperture with increasing the temperature of the component;

the processor is configured to control the speed of rotation of the fan according to the temperature of the component; the fan has, for a given speed of rotation: a direction of rotation generating a noise of a first amplitude,

 o another direction of rotation generating a noise of a second amplitude, greater than the first, the processor being configured to select the direction of rotation of the fan generating the noise of a second amplitude when the temperature of the component is greater than a threshold ;

 the processor is configured to select the direction of rotation of the fan generating the noise of a second amplitude when the size of an external opening of the device is maximum;

 the device comprises a light-emitting system which comprises light-emitting elements and optical elements for the projection of an image, the component whose temperature is regulated corresponding to the optical elements;

 the device being a portable image projector.

 The invention also relates to a method for regulating the temperature in a device as described above, comprising the step of controlling the direction of rotation of the fan as a function of the temperature of at least one component of the device measured by the sensor. of temperature, so as to regulate the temperature of the component by minimizing the noise generated by the fan.

 The method may also include the step that, upon increasing the temperature of the component, the processor controls the size of an external opening of the device to its maximum size, and then selects the direction of rotation of the fan. depending on the temperature of the component.

The various embodiments of the invention offer many advantages. Thus, the device makes it possible to optimize the compromise between the regulation of the temperature, synonymous with good performance of the device, and the reduction of noise for the user. For example, in the case of a device comprising a light emitting system configured for displaying or projecting images, display and projection performance is provided while reducing noise.

 The device is therefore more pleasant to use.

 In addition, the device allows simple and optimized temperature control, while maintaining a reduced level of noise.

 The solution adapts effectively to devices including a fan, without a complete review of their architecture is necessary.

PRESENTATION OF FIGURES

 Other features, objects and advantages of the invention will emerge from the description which follows, which is purely illustrative and nonlimiting, and which should be read with reference to the appended drawings in which:

 - Figure 1 is a schematic representation of an embodiment of a device according to the invention;

 - Figure 2 is a schematic representation of another embodiment of a device according to the invention;

 - Figure 3 is a schematic representation of an embodiment of a control method according to the invention;

 - Figure 4 is a schematic representation of an exemplary embodiment of a control method according to the invention.

DETAILED DESCRIPTION

Device

FIG. 1 shows schematically an embodiment of a device 1 according to the invention. This device 1 is an electronic device whose temperature must be regulated. The device 1 comprises at least one component 7. The component 7 is for example an optical and / or electronic type component, making it possible to perform one or more functions of the device 1.

 For example, in the embodiment of Figure 2, the device 1 comprises a light emitting system 2, configured for displaying an image, and / or for projecting an image.

 This is for example a screen for displaying an image, or a projection system of an image to a projection surface such as a wall or other suitable surface.

 In the example illustrated in FIG. 2, the light emission system 2 comprises light emitting elements 11 and optical elements 12. The elements 1 1 are for example light emitting diodes (LEDs) of the three basic colors (Red, Green, Blue), and the optical elements 12 a set of micro-mirrors whose position and inclination are controlled electronically. The optical elements 12 may for example be integrated in a microchip.

 The elements 1 1 emit one or more light beams to the elements 12, which project the beams to a projection surface, for the projection of the image. This type of projector is known in the art.

 In the example of FIG. 2, the component 7 whose temperature is to be regulated is a component of the system 2, for example the optical elements 12.

 The component 7 can also be any other component whose temperature is to be regulated in order to maintain the performance of the device 1: electronic card, processor, etc.

 The device 1 further comprises at least one fan 4 for the temperature control of the component 7. If necessary, several fans 4 may be present in the device 1.

The device 1 also comprises a processor 5. It may be the main processor of the device 1, configured to manage the various electronic functions of the device 1 (interaction with the user, load management, application management, etc.), or a processor dedicated to the implementation of the temperature control method described below. Management of the temperature of the transmission system 2 is crucial to guarantee the performance of the device 1.

 This temperature may especially be measured by one or more temperature sensors 3 disposed in or near the component 7.

 The temperature of the emission system 2 depends mainly:

 the ambient temperature at which the device 1 is subjected;

 o the operating mode of device 1 (ignition phase, during operation, number of tasks performed by the device, complexity of tasks, etc.).

 In particular, in operation, the temperature of component 7 tends to increase.

 However, in general, the increase in the temperature of the component 7 degrades the performance of the device 1.

 Moreover, the increase in the speed of rotation of the fan 4, to reduce the increase in the temperature of the component 7, increases the noise generated by the device 1.

 The processor 5 is configured to control the direction of rotation of the fan 4 according to the temperature of the component 7, so as to regulate the temperature of the component by minimizing the noise generated by the fan.

 In particular, the processor makes it possible to reduce the temperature of the component 7 while minimizing the noise generated by the fan 4. The compromise between the regulation of the temperature and the reduction of the noise is thus optimized, which makes it possible to maintain the performances of the device 1 while reducing the noise generated.

 For example, in the example illustrated in FIG. 2 in which the component 7 is part of the light emission system 2, the increase in the temperature of the light emission system 2 degrades the luminous efficiency of the system 2.

Thus, the quality of the image produced, such as its sharpness or clarity, deteriorates with the increase of the temperature of the system 2 light emission. This results notably from the performance of the light emitting elements (LEDs) with the temperature.

 By controlling the direction of rotation of the fan 4 by the processor 5, the temperature of the light emission system 2 is regulated while reducing the noise generated by the fan 4.

 For a given rotation speed, the fan 4 generates a lower noise in one direction of rotation relative to the other direction of rotation.

 Indeed, according to the direction of rotation of the fan 4, the air flow is sucked or blown. The path of the air flow in the device 1 is different, which creates a different aerodynamic noise.

 Likewise, since the path of the air flow varies according to the direction of rotation of the fan, the temperature regulation of the component 7 varies according to this direction of rotation. In particular, the influence of the direction of rotation of the fan 4 on the temperature regulation depends in particular on the relative position of the fan 4 with respect to the component 7.

 In general, the direction of rotation inducing the maximum noise is that which also makes it possible to reduce the temperature of the component 7 the best.

 As stated above, the fan 4 has, for a given speed of rotation, a direction of rotation generating a noise of a first amplitude, and another direction of rotation generating a noise of a second amplitude, greater than the first.

 According to a possible aspect of the control implemented by the processor 5, the latter is configured to select the direction of rotation of the fan 4 generating the noise of a second amplitude when the temperature of the component 7 is greater than a threshold.

 Below this threshold, the processor 5 retains the direction of rotation generating a lower noise of first amplitude.

 In addition to the fan 4, the device 1 may comprise at least one external opening 10 whose size is adjustable. It can also be a plurality of external openings.

In one example, the processor 5 controls a motor 14 that controls the size of the outer aperture 10 (or the plurality of apertures 10). These external openings comprise, for example, a sliding element in front of a recess, the translation of which determines the size of the openings.

 These external openings allow the circulation of a flow of air to and from the outside of the device 1.

 The outer openings 10 may be arranged on an edge of the device 1, or on the entire edge of the device 1.

 According to one embodiment, the processor 5 is configured to control the direction of rotation of the fan 4 and the size of the external openings as a function of the temperature of the component 7.

 This double control makes it possible to manage more finely the compromise existing between the temperature of the component 7 and the noise generated by the fan 4, since another regulation parameter is available (size of the openings 10).

 In a particular example, the processor 5 controls, besides the size of the openings 10, the profile of the external openings 10, thanks to the motor 14.

 Different controls can be implemented in the device 1 for the regulation of the temperature. These controls can be combined, partially used, or not used.

 In one aspect, the processor 5 is configured to increase the size of the outer openings as the temperature of the component 7 increases.

 As can be understood, increasing the size of the external openings makes it possible to reduce the temperature of the component 7 by circulating a flow of air in the device 1.

 In another aspect, the processor 5 is configured to control both the direction of rotation of the fan 4 and its rotational speed, depending on the temperature of the component 7.

In yet another aspect, the processor 5 is configured to select the direction of rotation of the fan 4 generating the noise of a second amplitude (maximum noise) when the size of the outer openings is maximum. This means that the processor 5, during the temperature control of the component 7, controls in the first place increasing the size of the outer openings. Once this maximum size is reached, the processor 5 controls the direction of rotation of the fan 4, and, if necessary, the speed of rotation of the fan 4.

 The device 1, which integrates the component 7, may for example be a portable image projector. In this case, it comprises a system 2 for light emission.

 This type of projector is transported by the user, like a USB key, and allows it to project images in various circumstances.

 It may also be other portable devices requiring temperature control and reduction of operating noise.

 Without limitation, it may also be a USB key, a camera, a camera, a computer, a projector, or a mobile phone, comprising one or more components whose temperature must be regulated.

Examples of regulation

 In FIG. 3, a method of temperature regulation in the device 1 described above comprises, in particular, the step E2 of controlling the direction of rotation of the fan 4 as a function of the temperature of at least one component 7 of the device 1, so to regulate the temperature of the component 7 by minimizing the noise generated by the fan 4. The temperature of the component 7 is measured by the above-mentioned temperature sensor 3, and transmitted to the processor 5 (step E1).

 According to a particular aspect of the method, if the device 1 comprises at least one external opening 10, the processor 5 controls the size of the external opening 10 up to its maximum size, then selects the direction of rotation of the fan 4 as a function of the temperature of the component 7.

 A particular and nonlimiting example of control is described below, with reference to FIG. 4.

When the device 1 is switched on, the measured temperature T ₂ (step

E3) by the sensor 3 for the component 7 is weak. The processor 5 selects the direction of rotation of the fan 4 according to the direction of rotation generating a noise of first amplitude (low noise). Processor 5 keeps the external openings closed (step E4).

When the temperature T ₂ of a component 7 (such as, for example, the optical elements 12 of the light emission system 2) exceeds a threshold Te, the processor 5 begins to increase the size of the external openings, in order to reduce the temperature component 7 (step E5).

 This makes it possible to maintain the performance of the device 1, such as the luminous efficiency of the image projected by the system 2, despite the increase in temperature, while minimizing the noise of the fan 4. As noted above, the increase in the temperature degrades the quality of the image in the case of a system 2 of light emission.

When the temperature T ₂ of a component 7 (such as for example the optical elements 12 of the light emission system 2) exceeds a threshold T _p , with Τ _β > Τ _θ , and the size of the external openings 10 is maximum , the processor 5 selects the direction of rotation of the fan 4 generating a noise of a second amplitude (maximum noise, step E6).

This direction of rotation of the fan 4 makes it possible to further cool the component 7. Although this direction of rotation of the fan 4 is noisier, this makes it possible to preserve the performance of the device 1, such as, for example, the quality of the displayed image. or projected by the system 2, since the temperature T ₂ of the component 7 is high.

 In this example, the rotational speed of the fan 4 has been assumed to be constant. However, this can also be controlled by the processor 5, and vary in case of temperature increase.

 Likewise, a simultaneous control of the size of the external openings and the direction of rotation of the fan 4 (and / or its speed of rotation) can be implemented. In particular, it is not necessary for the openings 10 to have reached their maximum size in order to modify the direction of rotation of the fan 4.

Similarly, the control implemented in the device 1 may depend on several temperature thresholds for the component 7, but also depend on several measured temperatures. In the example above, only the temperature of the component 7 has been taken into account (as for example the optical elements 12), insofar as it is the most representative temperature.

 However, the temperature of other components 7 of the optical system 2 can be taken into account in the control of the fan 4 and the openings 10. In the example of FIG. 2, the temperature of the light emitting elements 11 can The invention also makes it possible to optimally manage the compromise between the performances of the device and the noise generated by the device. It applies in particular, but not exclusively, to devices configured to project or display an image.

Claims

1. Device (1) comprising:  at least one component (7),  at least one fan (4) for controlling the temperature of the component (7),  a processor (5), and  at least one temperature sensor (3), characterized in that the processor (5) is configured to control the direction of rotation of the fan (4) as a function of the temperature of the component (7) measured by the temperature sensor (3) so as to regulate the temperature of the component (7) and the noise generated by the fan (4). 2. Device (1) according to claim 1, further comprising at least one opening (10) external whose size is adjustable, for the passage of a flow of air, the processor (5) being configured to control the direction of rotation of the fan (4) and the size of the external opening (10) as a function of the temperature of the component (7). 3. Device (1) according to claim 2, wherein the processor (5) is configured to increase the size of the outer opening (10) with increasing the temperature of the component (7). 4. Device according to one of claims 1 to 3, wherein the processor (5) is configured to control the rotational speed of the fan (4) according to the temperature of the component (7). 5. Device (1) according to one of claims 1 to 4, wherein the fan (4) has, for a given speed of rotation:  a direction of rotation generating a noise of a first amplitude, another direction of rotation generating a noise of a second amplitude, greater than the first, the processor (5) being configured to select the direction of rotation of the fan (4) generating the noise of a second amplitude when the temperature of the component (7) is greater than a threshold. Device according to claim 5, wherein the processor (5) is configured to select the direction of rotation of the fan (4) generating the noise of a second amplitude when the size of an external opening (10) of the device ( 1) is maximum. 7. Device (1) according to one of claims 1 to 6, comprising a system (2) for light emission which comprises elements (1 1) for light emission and optical elements (12) for projection an image, the component (7) whose temperature is regulated corresponding to the elements (12) optical. 8. Device according to one of claims 1 to 7, said device (1) being a portable image projector. 9. A method of controlling the temperature in a device (1) according to one of claims 1 to 8, comprising the step of controlling the direction of rotation of the fan (4) as a function of the temperature of at least one component (7) of the device (1) measured by the temperature sensor (3), so as to regulate the temperature of the component (7) by minimizing the noise generated by the fan (4). The method of claim 9, wherein, upon increasing the temperature of the component (7), the processor (5) controls the size of an external opening (10) of the device (1) to its maximum size, then selects the direction of rotation of the fan (4) according to the temperature of the component (7).