Device and method for cooling and lubricating tools in machining processes

The invention claimed is: 1. A device for cooling and lubricating a tool during a chip removal machining process, wherein it comprises: a first subsystem for cryogenic cooling that comprises: a first entry configured to introduce CO 2 in liquid state in a first conduit of the device; a first exit configured to supply CO 2 in liquid state from a second conduit of the device; a third conduit located between said first conduit and second conduit; and means for preventing the formation of dry ice in said first, second and third conduits, wherein said means for preventing the formation of dry ice in said first, second and third conduits are implemented by means of means for pressurizing said conduits above the triple point of the CO 2 before injecting the CO 2 in liquid state through the exit; wherein said means for pressurizing said first, second and third conduits above the triple point of the CO 2 comprises a second entry configured to introduce CO 2 in gaseous state in a fourth conduit of the device; a fifth conduit placed after said fourth conduit; a first solenoid valve configured to control the passage of CO 2 in liquid state between the first conduit and the third conduit; a second solenoid valve configured to control the passage of CO 2 in gaseous state between the fifth conduit and a sixth conduit; a first no-return valve disposed to communicate said first conduit and third conduit, so that when said first solenoid valve is closed, passage of CO 2 in gaseous state is allowed from the third conduit towards the first conduit before introducing the CO 2 in liquid state through the first entry; and a second no-return valve disposed to communicate said third and sixth conduit, so that when said second solenoid valve is open, circulation of the CO 2 in gaseous state is allowed from the sixth conduit towards the first solenoid valve but not the other way around, impeding the advance of CO 2 in liquid state towards the second solenoid valve; a second subsystem for lubrication that comprises means for supplying micro-particles of a cutting oil in liquid state; said first subsystem and second subsystem being independent from each other and said first subsystem and second subsystem being configured to operate both simultaneously or either one alone. 2. The device of claim 1 , wherein said means for pressurizing said first, second and third conduits above the triple point of the CO 2 also comprise a first shut-off valve placed on the first conduit and a second shut-off valve placed on the fourth conduit, configured to depressurize the first subsystem if necessary. 3. The device of claim 1 , wherein said means for pressurizing said first, second and third conduits above the triple point of the CO 2 also comprise a first pressure regulator for CO 2 in liquid state and a second pressure regulator for CO 2 in gaseous state, said first pressure regulator being placed between the third and second conduits; and said second pressure regulator being placed between said fourth and fifth conduits. 4. The device according to claim 1 , wherein said means for supplying micro-particles of a cutting oil in liquid state, comprise: a third entry configured to introduce pressurized air into a seventh conduit of the device; a device configured to supply cutting oil in liquid state through an eighth conduit; a third solenoid valve configured to control the passage of pressurized air to the seventh conduit; a fourth solenoid valve to control the passage of cutting oil to the eighth conduit; a coupling designed to join said seventh and eighth conduits in a single conduit; and a nozzle placed at the end of the exit of said conduit, said nozzle being configured to pulverize the cutting oil by the Venturi effect so it can be injected. 5. The device of claim 4 , wherein said coupling is a T-shaped coupling where said seventh and eighth conduits are joined axially to said conduit. 6. The device of claim 5 , wherein said conduit is a hose with two coaxial channels: an internal conduit configured so the cutting oil can flow in liquid state, said internal conduit being surrounded by an outer wall, configured so the pressurized air can flow between the internal conduit and the outer wall. 7. The device of claim 4 , wherein said means for supplying micro-particles of a cutting oil in liquid state, comprise a third pressure regulator located between a ninth conduit placed at the exit of said third entry and a tenth conduit placed at the entry of said third solenoid valve. 8. The device according to claim 1 , further comprising control means configured to control both the first subsystem and the second subsystem. 9. The device according to claim 1 , comprising a plurality of magnetic legs configured to couple to a machine-tool. 10. A method of operating a device for cooling and lubricating a tool during a chip removal machining process, comprising said device a first subsystem for cryogenic cooling, comprising: a first entry configured to introduce CO 2 in liquid state in a first conduit of the device; a first exit configured to supply CO 2 in liquid state from a second conduit of the device; a third conduit located between said first and second conduit; and means for preventing the formation of dry ice in said first, second and third conduits; and a second subsystem for lubrication, comprising means for supplying micro-particles of a cutting oil in liquid state; wherein said means for preventing the formation of dry ice comprise means for pressurizing said first, second and third conduits above the triple point of the CO 2 , wherein said means for pressurizing said conduits comprising: a second entry configured to introduce CO 2 in gaseous state in a fourth conduit of the device; a fifth conduit located after said fourth conduit; a first solenoid valve configured to control the passage of CO 2 in liquid state between the first conduit and the third conduit; a second solenoid valve configured to control the passage of CO 2 in gaseous state between the fifth conduit and a sixth conduit; a first no-return valve placed to communicate said first conduit and third conduit; and a second no-return valve placed to communicate said third conduit and sixth conduit; and wherein said means for supplying micro-particles of a cutting oil in liquid state comprise: a third entry configured to introduce pressurizing air into a seventh conduit of the device; a tank configured to supply cutting oil in liquid state through an eighth conduit; a third solenoid valve configured to control the passage of pressurized air in the seventh conduit; a fourth solenoid valve for controlling the passage of cutting oil in the eighth conduit; a coupling designed to join said seventh conduit and eighth conduit in a single ninth conduit, and a nozzle placed at the output end of said ninth conduit, said nozzle being configured to pulverize the cutting oil by the Venturi effect so it can be injected, the method comprising the following stages for the injection of CO 2 in liquid state through the coupling: opening the second solenoid valve to control the passage of CO 2 in gaseous state between the fifth conduit and the sixth conduit; pressurizing the first, second and third conduits above the triple point of the CO 2 ; opening the first solenoid valve that controls the passage of CO 2 in liquid state between the first conduit and the third conduit; injecting CO 2 in liquid state through the first exit. 11. The method of claim 10 , which comprises the following stages to interrupt the injection of CO 2 in liquid state through the first exit: closing the first solenoid valve that controls the passage of CO 2 in liquid state; sweeping at least the second and