Oxy-acetylene work apparatus and method for determining the operating time of said apparatus

The invention claimed is: 1. An oxyacetylene type work apparatus comprising: a first container containing acetylene; a first pressure gauge configured to measure the pressure in the first container, said first pressure gauge comprising a first dial and a first pressure indicator, said first pressure indicator being rotatable relative to said first dial; a first two-dimensional marking disposed on the first dial, said first pressure indicator configured to adopt a plurality of angular positions relative to said first marking according to the value of the pressure in the first container; a second container containing oxygen; a second pressure gauge configured to measure the pressure in the second container, said second pressure gauge comprising a second dial and a second pressure indicator, said second pressure indicator being rotatable relative to said second dial; a second two-dimensional marking disposed on the second dial, said second pressure indicator configured to adopt a plurality of angular positions relative to said second marking according to the value of the pressure in the second container; an image capturing device configured to produce images of the first pressure gauge and of the second pressure gauge; an electronic logic circuit configured to process said images of the first and second pressure gauges thereby determining the respective angular positions of the first and second pressure indicators relative to the first and second two-dimensional markings and to deduce from said angular positions the pressure values measured by the first and second pressure gauges, respectively, a sensor configured to measure the temperature of the first acetylene container, wherein the electronic logic circuit is configured to: determine the residual amount of acetylene in the first container, in accordance with a predetermined initial amount of acetylene in the first container, the value of the temperature of the first container measured by the sensor and the value of the pressure measured by the first pressure gauge; and determine the residual amount of oxygen in the second container, in accordance with a predetermined initial amount of oxygen in the second container and the value of the pressure measured by the second pressure gauge. 2. The apparatus as claimed in claim 1 , wherein the temperature sensor is configured to measure the temperature through contact with the first container. 3. The apparatus as claimed in claim 1 , wherein the temperature sensor is configured to remotely transmit temperature values of the first container. 4. The apparatus as claimed in claim 1 , wherein the temperature sensor is affixed on the outer surface of the first container. 5. The apparatus as claimed in claim 1 , wherein the temperature sensor is of the liquid crystal thermometer type. 6. The apparatus as claimed in claim 1 , wherein the temperature sensor is of the infrared thermometer type. 7. The apparatus as claimed in claim 1 , wherein said predetermined initial amount of acetylene is encoded in the first two-dimensional marking, the electronic logic circuit being configured to process the image of the first pressure gauge so as to decode said predetermined initial amount of acetylene. 8. The apparatus as claimed in claim 1 , wherein said predetermined initial amount of oxygen is encoded in the second two-dimensional marking, the electronic logic circuit being configured to process the image of the second pressure gauge so as to decode said predetermined initial amount of oxygen. 9. The apparatus as claimed in claim 1 , wherein said predetermined initial amount of acetylene and/or said predetermined initial amount of oxygen are stored in the electronic logic circuit. 10. The apparatus as claimed in claim 1 , further comprising a blowpipe comprising a first supply line in fluid communication with the first container containing acetylene, a second supply line in fluid communication with the second container containing oxygen and a nozzle in fluid communication with said first and second passages, said nozzle being configured so as to distribute a predetermined flow of an oxygen-acetylene mixture when the blowpipe is supplied, via the first supply line, with a first determined acetylene pressure and when the blowpipe is supplied, via the second supply line, with a second determined oxygen pressure. 11. The apparatus as claimed in claim 1 , wherein the electronic logic circuit is configured to determine a first duration of acetylene autonomy, in accordance with the predetermined flow of oxygen-acetylene mixture, said first acetylene pressure and the residual amount of acetylene in the first container, and to determine a second duration of oxygen autonomy, in accordance with the predetermined flow of oxygen-acetylene mixture, said second oxygen pressure and the residual amount of oxygen in the second container. 12. The apparatus as claimed in claim 1 , wherein the temperature sensor is configured to measure the temperature of the outer surface of the first container. 13. The apparatus as claimed in claim 12 , wherein the electronic logic circuit is configured to compare the first duration of acetylene autonomy and the second duration of oxygen autonomy and to determine the shortest of said first and second durations as being the autonomy of the apparatus in terms of time. 14. A method for determining the autonomy of an apparatus as claimed in claim 1 , said method comprising the following steps: a) producing an image of the first pressure gauge and processing said image so as to determine the angular position of the first pressure indicator relative to the first two-dimensional marking; b) deducing from the angular position of the first pressure indicator the value of the pressure measured by the first pressure gauge; c) producing an image of the second pressure gauge and processing said image so as to determine the angular position of the second pressure indicator relative to the second two-dimensional marking; d) deducing from the angular position of the second pressure indicator the value of the pressure measured by the second pressure gauge; e) measuring the temperature of the first container; f) determining a predetermined initial amount of acetylene; g) determining a predetermined initial amount of oxygen; h) processing the data obtained in steps b), e) and f) so as to determine the residual amount of acetylene in the first container; and i) processing the data obtained in steps d) and g) so as to determine the residual amount of oxygen in the second container. 15. The method as claimed in claim 14 , wherein, during step b), the image of the first pressure gauge is processed so as to decode a predetermined initial amount of acetylene encoded in the first two-dimensional marking and/or, during step g), the image of the second pressure gauge is processed so as to decode a predetermined initial amount of oxygen encoded in the second two-dimensional marking. 16. The method as claimed in claim 14 , further comprising a step of storing the following data inside the electronic logic circuit: a flow rate of the oxygen-acetylene mixture distributed by the nozzle of a blowpipe; a value of the first blowpipe acetylene supply pressure; and a value of the second blowpipe oxygen supply pressure, the electronic logic circuit being configured to determine a first duration of acetylene autonomy, in accordance with the predetermined flow rates of the oxygen-acetylene mixture, the first acetylene pressure and the residual amount of acetylene in the first container, and to determine a second duration of ox