Flow detection device, cooling arrangement for an electronic device, and rack hosting a plurality of electronic devices

What is claimed is: 1. A flow detection device, comprising: a fluidic input port; a fluidic output port; a channel connected to the fluidic input port and to the fluidic output port; a float located within the channel, a specific weight of the float being greater than a specific weight of a fluid injected in the flow detection device via the fluidic input port, wherein respective locations of the fluidic input port, of the channel and of the fluidic output port on the flow detection device cause the float to rise within the channel when a sufficient flow of the fluid is injected in the flow detection device; a conduit connecting the channel to the fluidic output port, the conduit extending from under a position of the float when the float is raised within the channel, the fluidic output port being at least as high as the position of the float when the float is raised within the channel; a gas extraction passage connecting the channel to the fluidic output port, an entry of the gas extraction passage being located at or above a highest possible position of the float when the float rises within the channel, an exit of the gas extraction passage proximate to the fluidic output port being at least as high as the entry of the gas extraction passage; and a sensor adapted to detect the position of the float within the channel. 2. The flow detection device of claim 1 , wherein the float has a diameter smaller than a diameter of the channel and greater than diameters of the fluidic input port and of the fluidic output port. 3. The flow detection device of claim 1 , wherein the channel extends substantially vertically, the fluidic input port being connected to a lower end of the channel, the fluidic output port being connected to an upper end of the channel. 4. The flow detection device of claim 3 , wherein the sensor is adapted to measure the flow of the fluid as a function of the position of the float along a length of the channel. 5. The flow detection device of claim 1 , wherein the sensor comprises: a transparent or translucent window located in an upper area of the channel; a light source emitting light through the transparent or translucent window; and a light detector configured to detect, through the transparent or translucent window, light from the light source reflected by the float when the float is in an elevated position within the channel. 6. The flow detection device of claim 1 , wherein the sensor comprises a magnetic detector configured to detect a magnetic field of the float when the float is in an elevated position within the channel. 7. The flow detection device of claim 6 , wherein the float comprises a magnetic material, and wherein the flow detection device comprises a magnet that magnetizes the magnetic material of the float. 8. The flow detection device of claim 7 , wherein the magnet is located above the float. 9. A cooling arrangement for an electronic device, comprising: a cooling circuit, comprising: a fluidic input line adapted for receiving a cooling fluid from a cooling fluid source, a fluidic output line adapted for returning the cooling fluid toward a drain, a cooling device mountable to the electronic device, the cooling device being adapted to receive the cooling fluid from the fluidic input line and to transfer heat from the electronic device to the cooling fluid before returning the cooling fluid via the fluidic output line, and the flow detection device of claim 1 , the fluidic input port receiving the cooling fluid from one of the fluidic input line and the fluidic output line, the fluidic output port returning the cooling fluid to the one of the fluidic input line and the fluidic output line; and a processor communicating with the flow detection device and configured to determine a status of the flow of the cooling fluid in the flow detection device based on a signal from the sensor. 10. The cooling arrangement of claim 9 , wherein the processor is further configured to cause a shutdown of the electronic device when the status of the flow of the cooling fluid in the flow detection device indicates a lack of cooling flow. 11. A rack comprising a plurality of stages, wherein each stage comprises an electronic device being cooled by a cooling arrangement as defined in claim 9 , each stage being adapted for receiving a component communicatively coupled to the electronic device, the fluidic input and output lines extending on the component when the component is received in the rack. 12. The rack of claim 11 , wherein the flow detection device and the processor communicating with the flow detection device are located on the component. 13. The rack of claim 11 , further comprising a main processor communicatively coupled to the processor of each cooling arrangement and receiving therefrom the status of the flow of the cooling fluid of each cooling arrangement. 14. The rack of claim 13 , wherein the main processor is configured to cause a transfer of operations running on a given electronic device coupled to a given component in which the status of the flow of the cooling fluid indicates a lack of cooling flow to another electronic device. 15. The rack of claim 14 , wherein the main processor is further configured to cause a start of a given electronic device connected to a given component when the status of the flow of the cooling fluid for the given component indicates a proper cooling flow. 16. The flow detection device of claim 1 , wherein the exit of the gas extraction passage proximate to the fluidic output port is higher than the entry of the gas extraction passage. 17. The flow detection device of claim 1 , wherein the float is a sphere. 18. The flow detection device of claim 1 , further comprising a grid between the channel and the fluidic output port, wherein the grid prevents the float from entering the fluidic output port.