FR2998387A1 - Protection device for protecting e.g. hard disk against heat, has cooling unit whose circulation unit circulates cooling liquid from exterior toward interior of envelope and vice versa and includes heat sink external to envelope - Google Patents

Abstract

The device (1) has a watertight and hermetically closed envelope comprising an external shell (3) made of heat resistant material. A cooling unit (4) cools computer equipment (2) confined within the envelope. The cooling unit has a circulation unit (5) for circulating cooling liquid from exterior toward interior of the envelope and vice versa. The circulation unit has a heat sink (6) external to the envelope. The circulation unit has an input channel (7) and an output channel (8) reciprocally traversing an input and an output arranged in a wall (9) of the envelope.

Description

The present invention is in the computer field, in particular computer hardware. The invention particularly relates to a device for protecting a computer against heat, fire and water. Such a device will find a preferential application, but in no way limiting, in the protection of storage equipment and the safeguarding of digital data. In addition, the invention is preferentially dedicated to the protection of hard disks. In known manner, a computer hardware does not provide sufficient protection against fire-related, such as fire, or water-related, such as flooding. It is then necessary, in order to offer them protection, to lock them in enclosures provided for this purpose. In particular, such enclosures are often hermetically sealed, to prevent heat transfer from the outside to the inside in the event of a fire, and sealed, to prevent any infiltration of water. A major problem lies in the heat dissipation of the computer hardware. Indeed, during operation, for the equipment enclosed in a protective enclosure, it is necessary to dissipate the calories it produces, so as not to damage the equipment therein. In particular, in the case of hard disks, their operation is provided by an air layer ensuring a floating reading heads above the storage media trays. Therefore, an increase in temperature above 50 degrees Celsius causes expansion of said trays, as well as the air layer which provides said floatation, up to causing contact of the heads with the surface of the trays. This contact inevitably leads to a deterioration of the surface, as well as the read heads themselves. Therefore, it is essential, to ensure the proper functioning of the equipment, while ensuring its protection, to dissipate the calories produced inside the enclosure. A first known solution is described in document EP 1 815 727, concerning a box for protection against fire and / or water. This box comprises outer walls covered or made of a material having thermal characteristics of flame protection, but also limiting the heat transfer from the outside to the inside. Such a box comprises openings or vents, allowing air to flow from the inside to the outside, and vice versa. In particular, these vents provide circulation of a flow of air in a natural way, under the effect of heating and expansion of the enclosed gases. The overpressure, even minimal, which is created induces a flow of air from the inside to the outside of the enclosure. This document also plans to force this circulation through fans. Against the infiltration of water, the vents may have a longitudinal siphon shape, or even several successive siphons. In addition, the hard drives are enclosed in a waterproof pocket. The latter comprises walls made of a metallic material directly in contact with the outer walls of the hard disks that it encloses, thus making it possible to diffuse the heat thus produced by conduction. The air inside the box then heats up and produces the circulation effect described above. Another known solution is described in document EP 1 475 803. It consists of a computer system for backing up digital data protected against water and fire by means of a sealed housing inside which said enclosure is enclosed. computer hardware to protect, including a hard drive. Said enclosure is provided flame retardant, through several outer layers of different types of materials.

In addition, the heat dissipation of the calories produced by the hard disks is effected by means of a radiator, attached, on the one hand, against the walls of the hard disks and, on the other hand, against an inner wall of the disk. 'pregnant. The latter is provided metal, so as to ensure, once again, a diffusion of heat by conduction.

Such devices are not entirely satisfactory, because the heat dissipation is carried out ultimately by diffusion of calories directly to the outside of the enclosure. Therefore, in the case of high temperatures, especially during a fire, when the outside temperature becomes greater than the internal temperature relative to said enclosure, no thermal diffusion is no longer performed. Conversely, the operation of known protection devices can generate a thermal bridge from the outside to the inside, potentially damaging the computer hardware that is supposed to be protected. The present invention aims to overcome the drawbacks of the state of the art, by proposing a protection device against heat, fire and water, computer equipment, ensuring the heat dissipation of said equipment during operation that it encloses without creating a thermal bridge from outside to inside. To do this, it has been imagined to use cooling by circulation of a coolant from the outside to the inside of the enclosure, and vice versa. In short, the invention provides for creating a sealed chamber for circulating the liquid inside the already sealed enclosure enclosing the material to be protected. This feature therefore allows to preserve the protective properties against water and heat. Therefore, it is possible to consider an integral outer shell of protection against heat and fire. In addition, it should be noted that the use of a liquid circulating inside the enclosure goes directly against the idea of protecting the material locked in water. Thus, the device according to the invention comprises, on the one hand, a tight and hermetically sealed envelope consisting of an outer shell of material having thermal resistance characteristics and, on the other hand, means for cooling said material. computer encased within said casing, characterized in that said cooling means consist of means for circulating a cooling liquid from the outside to the inside of said casing, and vice versa, said setting means in circulation comprising at least one heat sink outside said envelope. In addition, according to other additional nonlimiting features, said circulation means may comprise at least one input channel and at least one output channel crossing reciprocally an input and an output formed through at least one input channel. wall of said casing, said inlet and outlet being provided with sealing seals, sealed and thermal. According to a particular embodiment, said cooling means may comprise a box shaped and dimensioned so as to receive internally said computer equipment, said box comprising hollow walls internally providing a circulation space of said coolant, said box being connected in a manner sealed to said input and output channels.

According to another embodiment, said box may comprise metal walls provided with fixing means in contact with said computer equipment. Advantageously, said channels may consist of sheaths of plastic material.

Other characteristics and advantages of the invention will emerge from the following detailed description of non-limiting embodiments of the invention, with reference to the appended figures, in which: FIG. 1 represents a schematic view of the principle of operation of the device according to the invention; and FIG. 2 represents a simplified cutaway perspective view of a preferred embodiment of said protection device. The present invention relates to a device 1 for protecting a computer hardware 2. In particular, said device 1 is provided to ensure the protection of said equipment 2 against heat, fire and water. It should be noted that said computer hardware 2 may be digital data storage equipment, such as at least one hard disk or a ROM or RAM type memory reader, or else a tape drive. Said computer hardware may also include connectors and other electronic elements ensuring the operation of said hardware 2, as well as related electronic components, including a network card or a motherboard. According to the embodiment shown in FIG. 2, said computer hardware 2 consists of three hard disks 20. Firstly, said device 1 comprises a sealed and hermetically sealed envelope consisting of an outer shell 3. The latter comprises one or more walls 20 connected to each other, so as to provide an interior volume completely separate and distinct from the outside atmosphere. According to the preferred embodiment, as visible in Figure 2, said shell 3 has a rectangular parallelepiped shape. In particular, such a volume can be closed at at least one face of said envelope, permanently or removably. In the case of a permanent closure, the face is sealed after said material 2 has been placed and connected inside the enclosure. Such sealing can be achieved with a suitable thermal paste, but also by gluing, welding or heat sealing. In the case of a removable closure, said face is fixed by screwing, with an intermediate seal ensuring tightness. In addition, such a shell 3 is made of a material 35 having thermal resistance characteristics. More specifically, said shell 3 has a surrounding layer 30 surrounding it all around its periphery, said layer 30 consisting of one or more materials having the required characteristics. In the case of a removable opening of the shell 3, said layer 30 can be made after closing, so as to ensure perfect continuity in the entirety of the outside of said shell 3. According to different modes of realization, said materials may be made of a flame-resistant material, increasing the burning time of said layer 30 before the fire comes to burn in contact with said shell 3, and / or a refractory material, providing a wall of thermal reflection against convection when the device 1 is subjected to high external temperatures, above 30 ° C, and / or a material having expansion characteristics under the effect of heat, such as vermiculite. It should be noted that any type of material offering thermal resistance characteristics to heat and / or fire can be used. Furthermore, said device 1 comprises means 4 for cooling said computer hardware 2 enclosed within said envelope. Advantageously, said cooling means 4 consist of means 5 for circulating a cooling liquid from the outside towards the inside of said envelope, and vice versa. In sum, the means 5 form a circuit passing through said shell 3 and ensuring a circulation of a coolant between the outside and the inside. In addition, said means 5 comprise pumping means 50, in particular at least one pump, ensuring the circulation. Preferably, the circulation of said liquid is effected in a closed manner. It will be noted that said cooling liquid may be water, but also a mixture of liquid, in particular glycol. In addition, said circulation means 5 comprise at least one heat sink 6 outside said envelope. In particular, such a dissipator 6 is in contact with the circuit inside which circulates said liquid, so as to dissipate the calories.

As such, said dissipator 6 may be in the form of a radiator, with or without ventilation. Thus, during the circulation of said liquid, when it arrives inside the envelope, it heats and recovers the calories produced by said computer hardware 2 in operation, then during its passage to the outside, it cools, in particular via the dissipator 6, to transmit the calories previously stored, then goes back inside the enclosure, and so on. In particular, said circulation means 5 may comprise at least one inlet channel 7 and at least one outlet channel 8, crossing reciprocally an inlet 70 and an outlet 80 formed through at least one wall 9 of said envelope. According to a preferred embodiment, said channels 7, 8 consist of sheaths of plastic material. Indeed, in case of fire, the duct portions located outside the envelope will melt, releasing the liquid outside and avoiding any flow inside the envelope.

In addition, this plastic material makes it possible to limit the thermal bridges between the inside and the outside of the envelope, because of the low thermal conductivity of this material, compared with an armored sheath, surrounded by metal and capable of withstanding very high temperatures and which would be preferred in this context. It will be noted that the junction between the channels 7, 8 and the inlet ports 70, 80 is provided so as to ensure the protection characteristics of the device 1. In particular, said inlet 70 and outlet 80 may be provided with sealing joints. hermetic, waterproof and thermal. According to a preferred embodiment, said seals may consist of an expansive material under the effect of heat, so as to expand sufficiently to completely obstruct said orifices. According to another additional feature, said cooling means 4 comprise a box 40 shaped and dimensioned so as to internally receive said computer hardware 2. According to the embodiment shown in FIG. 2, said box 40 has a rectangular parallelepipedal shape. In addition, said computer hardware 2 is in the form of three hard disks, said box 40 comprises at least one open face, so as to introduce the disks inside. In addition, it internally comprises means for holding said disks, in particular in the form of slides formed in the lateral inner faces, inside which said disks can be inserted and extracted by sliding. Therefore, it will be noted that some of the walls of said disks, in particular the side walls, are directly in contact with the casing 40, ensuring thermal transmission directly by conduction. As such, said box 40 may comprise metal walls provided with fastening means in contact with said computer hardware 2. This metal material thus increases the heat conduction and the transmission of calories from said material 2 to the coolant. To do this, said box 40 may comprise hollow walls 41 internally providing a circulation space of said coolant. In addition, said box 40 is sealingly connected to said inlet and outlet channels 8 and 8. Thus, the liquid comes into contact with the walls which are themselves in contact with the computer equipment 2, increasing the recovery of the calories produced. . Thus, the interior of the casing 40 forms a hermetic and sealed space for circulating the liquid within the enclosure already sealed and sealed, free from any contact of the interior volume of the casing with the external atmosphere. . In a subsidiary manner, as can be seen in the figures, said device 1 may comprise wired connection means to the outside of said computer hardware 2 electrically and to a computer network. In short, an electrical wiring 10 and a network cabling 11 are connected to said computer hardware, in order to mutually provide its power supply and its connection to an external network (or directly to a terminal, in particular a computer).

As can be seen in FIG. 2, these cabling 10, 11 may be subdivided into two inner and outer portions 101 and 101 to said envelope, the connection between the two portions being operated via a connector 102 passing through a wall of the shell. 3.

In addition, this connector 102 can receive sealed and hermetic junction means, and an expansive material which, under the effect of a high temperature, melts or expands to close the hole in which it is fixed in the wall of said shell 3.

During operation, the computer hardware 2 enclosed in the device 1 operates, electrically powered by the wiring 10 and connected to the network by the wiring 11. The heat produced is dissipated by the circulation of the fluid between the interior and the interior. outside, under the action of the pumping means 50. In this respect, it will be noted that the circulation can be carried out continuously or according to programmed time intervals. In particular, the triggering of the flow of the fluid can be effected by means of temperature detection sensors, located inside the envelope. As soon as a threshold temperature is reached, then the fluid is circulated until the temperature drops below this threshold value. In addition, these sensors make it possible internally to cut off the supply of said equipment in the event of exceeding a critical temperature.

In the event of even partial immersion of the device 1, the sealing of the casing and the cooling circuit, ensure the intact preservation of the material 2 which is enclosed therein. In case of fire, all external elements are destroyed, in particular the part of the circulation means 5 and the dissipator 6 located outside, as well as the channels 7, 8. From then on, the circulation of liquid is interrupted. In addition, the melting of the plastic material of the channels 7.8 ensures the outward flow of said liquid.

In addition, the expansive joints completely obstruct the already sealed orifices through which said channels 7, 8 and to which the cables 10, 11 are connected, rendering the outer shell 3 completely integral and providing resistance against flames and fire.

Thus, by resorting to a circulation of fluid, rather to ventilation or dissipation by conduction, the invention makes it possible to completely seal the device 1 of protection according to the invention with water and heat.

Claims (5)

REVENDICATIONS1. Device (1) for protecting a computer equipment (2) against heat, fire and water, comprising, on the one hand, a sealed and hermetically sealed envelope consisting of an outer shell ( 3) of 5 material having thermal resistance characteristics and, on the other hand, means (4) for cooling said computer equipment (3) enclosed within said casing, characterized in that said cooling means (4) consist of means (5) for circulating a coolant from the outside to the inside of said casing, and vice versa, said circulating means (5) comprising at least one heat sink (6). outside said envelope. 2. Device enclosure (1) according to claim 1, characterized in that said means for circulating (5) comprise at least one inlet channel (7) and at least one outlet channel (8) reciprocally crossing an inlet and an outlet formed through at least one wall (9) of said casing, said inlet and outlet being provided with hermetic, sealed and thermal sealing joints. 3. enclosure device (1) according to claim 2, characterized in that said cooling means (4) comprises a box (40) shaped and dimensioned so as to receive internally said computer hardware (2), said box (40) comprising hollow walls (41) internally providing a circulation space of said coolant, said box (40) being sealingly connected to said inlet (7) and outlet (8) channels. 4. enclosure device (1) according to claim 3, characterized in that said box (40) comprises metal walls provided with fixing means in contact with said computer equipment (2). 5. enclosure device (1) according to claim 2, characterized in that said channels (7,8) consist of sheaths of plastic material.